G12 | Macro Paper Warehouse

A Preferred-Habitat Model of Term Premia, Exchange Rates, and Monetary Policy Spillovers

Mon, 01 Jan 0001 00:00:00 +0000

Layer 1 — Core Argument

The paper develops a two-country preferred-habitat model in which currency and bond markets are populated by different investor clienteles — currency traders with price-elastic demand for foreign assets, and bond investors whose preferences are habitat-specific by country and maturity — with segmentation partly overcome by global arbitrageurs who have limited capital and bear mean-variance risk. Risk premia in the model are time-varying, connected across markets, and consistent with the empirical violations of Uncovered Interest Parity (UIP) and the Expectations Hypothesis (EH): in particular, currency carry trade (CCT) and bond carry trade (BCT) strategies earn abnormally high expected returns in ways that co-vary across the two markets in a manner the standard frictionless model cannot generate. Through these time-varying, connected risk premia, large-scale bond purchases (QE) lower domestic bond yields, lower foreign bond yields, and depreciate the purchasing country’s currency; short-rate cuts also lower foreign yields, but with smaller effects than bond purchases. A key structural finding, quantified in the estimated model calibrated to US and Eurozone data, is that currency returns are nearly uncorrelated with long-maturity bond returns — an exchange-rate disconnect — yet the currency market is instrumental in transmitting bond demand shocks across countries, because arbitrageurs hedge their cross-currency positions in bond markets and vice versa. Sterilized foreign-exchange interventions have strong effects on the exchange rate but weak effects on bond yields, while QE/QT has weak effects on the exchange rate but sizeable effects on foreign bond yields — a sharp asymmetry that follows directly from the disconnect.

Layer 2 — Q&A

Q1. Why do UIP and EH fail in the standard model, and what changes in this model?

In the standard model with perfect capital mobility, risk premia are constant, so the yield curve depends only on expectations of the domestic short rate and the exchange rate absorbs short-rate differentials exactly. In this model, arbitrageurs bear the residual risk when currency traders and bond clienteles are unwilling to absorb excess supply or demand at prevailing prices. Because arbitrageurs have limited capital (captured by a risk-aversion parameter a ≥ 0 that can also represent capital or Value-at-Risk constraints in reduced form), they demand compensation — time-varying risk premia — for holding currency and maturity risk. When a = 0, arbitrageurs are risk-neutral, UIP and EH both hold, and the model collapses to the standard frictionless benchmark.

Q2. What are the three types of agents and what does each do?

Currency traders hold foreign assets and have a demand that is downward-sloping (price-elastic, with slope coefficient αe ≥ 0) in the log exchange rate; their demand also shifts with a stochastic currency demand factor γt. They can be interpreted as households engaged in expenditure switching or central banks managing reserve levels. Bond investors form clienteles, each with a preferred-habitat demand for bonds of a specific country and maturity that is downward-sloping in the log bond price (slope αj(τ)) and shifts with a country-specific bond demand factor βjt; examples are pension funds and insurance companies whose liabilities are long-dated and denominated in their home currency. Global arbitrageurs trade the currency and all bonds of both countries, maximizing mean-variance utility over instantaneous wealth changes; they bridge the segmented markets and their positions pin down equilibrium risk premia.

Q3. What is the equilibrium structure and which factors drive prices?

The equilibrium exchange rate and bond prices are log-affine functions of five stochastic factors: the home short rate iHt, the foreign short rate iFt, the currency demand factor γt, and the two bond demand factors βHt and βFt. These factors follow a mean-reverting (Ornstein-Uhlenbeck) system. The equilibrium is characterized by a scalar nonlinear system (25 equations in the general case) whose solution pins down the loadings of prices on each factor. This affine structure means each asset’s risk premium is the product of the arbitrageur’s risk-aversion coefficient, the factor covariance matrix, and arbitrageur net positions, which are themselves determined by market-clearing.

Q4. How does a conventional short-rate cut transmit domestically and internationally in the model?

Following a home short-rate cut, arbitrageurs find it attractive to enter the CCT — borrow home currency, invest in foreign currency. If currency traders’ demand is price-elastic (αe > 0), arbitrageurs’ equilibrium foreign-currency holdings rise, and the expected return on the CCT rises too (arbitrageurs must be compensated for the increased risk). This attenuation effect means the foreign currency appreciates less than implied by UIP: the exchange rate response is dampened. Simultaneously, arbitrageurs enter the home BCT (borrow at the home short rate, invest in long home bonds); if home bond investors’ demand is price-elastic (αH(τ) > 0), arbitrageurs’ long-bond holdings rise and the BCT’s expected return rises, attenuating the transmission to domestic long-maturity yields (which fall less than EH would imply). A propagation effect to foreign bond yields arises through arbitrageur hedging: by taking long positions in foreign currency (CCT), arbitrageurs become exposed to the risk that the foreign short rate drops and the foreign currency depreciates; long-maturity foreign bonds provide a natural hedge (their price rises when the foreign short rate drops), so arbitrageurs increase foreign bond demand, depressing foreign yields. This international transmission of conventional policy is absent from the standard model.

Q5. How does unconventional policy (QE/QT) transmit domestically and to the exchange rate and foreign yields?

Following QE purchases of home bonds, their prices rise; arbitrageurs accommodate by holding fewer home bonds, which reduces their exposure to home short-rate risk. With less home-rate risk, arbitrageurs become more willing to hold foreign currency (which depreciates when the home short rate rises, offering a natural hedge against the home rate risk they have shed). The increased foreign-currency position in turn makes arbitrageurs more willing to hold foreign bonds (which hedge the foreign-currency position against foreign rate changes). The net result in the model is: QE lowers domestic bond yields, lowers foreign bond yields, and depreciates the home currency. The quantitative finding from the estimated model is that QE/QT effects on foreign bond yields are sizeable and stronger than those of conventional short-rate policy.

Q6. What explains the exchange-rate disconnect, and how can the currency market still transmit bond demand shocks?

In the estimated model, variance decompositions reveal that long-maturity bond yields in each country are driven primarily by bond demand factors (βHt and βFt), while the exchange rate is driven primarily by the currency demand factor (γt); short rates account for a small fraction of movements in both, and each factor type accounts for negligible variation in the other asset class’s price. The disconnect between bond yields and the exchange rate arises because bond demand shocks in the two countries move the exchange rate in opposite directions — a home bond demand shock that lowers home yields also raises the exchange rate via arbitrageur hedging, while a foreign bond demand shock moves the exchange rate in the opposite direction. These offsetting effects make the exchange rate nearly uncorrelated with long-maturity bond yields. However, bond demand shocks in one country are transmitted to bond yields in the other country through the currency market: arbitrageurs hedge their bond positions using the currency, so a shock to home bond demand moves arbitrageurs’ currency positions, which in turn affects their willingness to hold foreign bonds. Cross-country bond yield comovement is therefore positive and sizeable, despite the exchange-rate disconnect.

Q7. What are the model’s implications for foreign exchange intervention?

A sterilized purchase of foreign currency by the home or foreign central bank — which shifts the currency demand factor — has strong effects on the exchange rate but weak effects on bond yields. This follows directly from the variance decomposition: the exchange rate loads heavily on the currency demand factor and bond yields load lightly on it. The asymmetry mirrors the QE result in reverse: QE shifts bond demand factors, which load heavily onto bond yields and lightly onto the exchange rate; FX intervention shifts the currency demand factor, which loads heavily onto the exchange rate and lightly onto bond yields. The model thus delivers a sharp policy instrument separation between QE/QT (primarily a bond yield tool) and FX intervention (primarily an exchange-rate tool), with each having spillovers in the other dimension that are quantitatively weaker.

Q8. How is the relationship between currency risk premia and bond risk premia captured, and what empirical regularities does the model match?

The model’s risk premia are linked through the shared arbitrageur portfolio: the price of each risk factor is proportional to the covariance between that factor and the arbitrageur’s overall portfolio return, so a shock that changes arbitrageurs’ currency positions also changes the compensation required for bond positions, and vice versa. The estimated model is reported to match closely the violations of UIP (CCT profitability) and EH (BCT profitability) documented in the literature, and the ways in which these violations are connected — including findings that yield-curve slope differentials predict CCT profitability, and that CCT profitability declines when carried out with long-maturity rather than short-maturity bonds. These matches are described as consistent with the empirical regularities, not structural identification of the underlying causes.

Q9. What is the role of segmented versus global arbitrage, and why does the distinction matter?

The paper considers both cases. Under segmented arbitrage, separate arbitrageur pools operate in the currency market (risk aversion ae), home bond market (aH), and foreign bond market (aF); first-order conditions for each pool reflect only their own portfolio risk, so the prices of risk factors differ across markets. Under global arbitrage, a single pool of arbitrageurs trades all assets, and their shared portfolio means the price of each risk factor is the same across currency and bond markets — this is the mechanism through which bond demand shocks in one country propagate through the currency market to bond yields in the other. Global arbitrage is the primary specification; segmented arbitrage serves as a benchmark to isolate the hedging-based transmission channel that requires global positions.

Q10. How does the model relate to and extend predecessor frameworks?

The model extends Vayanos and Vila (2021) — a closed-economy preferred-habitat yield curve model — to two countries by adding a currency market and a second country’s bond market, with arbitrageurs who are global rather than country-specific. In the currency dimension, the attenuation of UIP deviations parallels Gabaix and Maggiori (2015), which models exchange-rate dynamics with financially constrained intermediaries but without a yield curve. The two-country structure allows the paper to simultaneously study term premia (EH violations), exchange rate dynamics (UIP violations), and their connection, and to quantify the effects of QE, conventional monetary policy, and FX intervention within a single internally consistent framework estimated on US-Eurozone data.

Key Concepts

Preferred-habitat demand: A bond investor’s demand for bonds of a specific country and maturity that does not arise from portfolio optimization over the full menu of available assets, but rather from institutional constraints or liability-matching motives (e.g., pension funds matching long-dated domestic liabilities). In the model, preferred-habitat demand is price-elastic with slope αj(τ) and shifts with a country-specific bond demand factor βjt; the elastic component means that as bond prices rise, clientele demand falls, so arbitrageurs must absorb the residual supply and require a risk premium to do so.

Global arbitrageur: An investor who trades the currency and bonds of both countries simultaneously, bridging the segmented currency and bond markets. In the model, global arbitrageurs maximize mean-variance utility over instantaneous wealth changes; their shared portfolio across all asset classes is the mechanism through which shocks in one market create hedging-driven demand in other markets, generating the cross-market linkages in risk premia and monetary policy transmission.

Currency carry trade (CCT): A strategy that borrows at the home short rate and invests at the foreign short rate, profiting when the foreign currency does not depreciate enough to offset the interest rate differential. Under UIP, the CCT earns zero expected return; the model generates a positive expected CCT return — a currency risk premium — when arbitrageurs are risk-averse and currency traders’ demand is price-elastic. In the paper’s notation, the CCT return is det/et + (iFt − iHt)dt.

Bond carry trade (BCT): A strategy that borrows at the short rate and invests in long-maturity bonds of the same country, profiting when long yields fall or when expected short rates are below current long yields. Under EH, the BCT earns zero expected return; the model generates a positive expected BCT return — a term premium — when arbitrageurs are risk-averse and bond clientele demand is price-elastic.

Exchange-rate disconnect: The empirical and model finding that movements in the exchange rate are nearly uncorrelated with movements in long-maturity bond yields, even though both are endogenously determined in the same model. The disconnect arises in the estimated model because long bond yields are driven primarily by bond demand factors, while the exchange rate is driven primarily by the currency demand factor, and the two sets of factors move the exchange rate in offsetting directions so that their net effect on bond yield-exchange rate covariance is approximately zero.

Attenuation effect: The dampening of monetary policy transmission to asset prices caused by the need to compensate risk-averse arbitrageurs for the increased risk they bear when accommodating the policy-induced excess demand. In the currency market, a home short-rate cut causes the CCT’s expected return to rise (arbitrageurs must be paid more to hold foreign currency), which means the foreign currency appreciates less than UIP predicts. In the bond market, a short-rate cut causes the BCT’s expected return to rise (term premia increase), so long yields fall less than EH predicts.

Propagation effect: The international transmission of a domestic monetary policy shock to foreign asset prices through arbitrageur hedging. A home short-rate cut causes arbitrageurs to increase their foreign-currency position (CCT); this exposes them to the risk of foreign short-rate declines (which depreciate the foreign currency), and long-maturity foreign bonds hedge this risk; so arbitrageurs increase foreign bond demand, depressing foreign yields. This channel is absent from the standard model where risk premia are constant.

Log-affine equilibrium: The conjectured and verified form of the equilibrium in which the log exchange rate and log bond prices are affine (linear plus constant) functions of the five state factors (iHt, iFt, γt, βHt, βFt). This structure allows the model to be solved as a system of ordinary differential equations and scalar equations, and enables closed-form or numerically tractable characterization of risk premia, variance decompositions, and policy effects.

Bond demand factor (βjt): A stochastic variable that shifts the intercept of bond clientele demand in country j, independent of maturity τ. A positive shock to βjt increases desired bond holdings of country-j clienteles at any given price, forcing arbitrageurs to shed country-j bonds, which lowers bond yields. The factor follows a mean-reverting process and in the estimated model is found to be the primary driver of long-maturity yields in both countries.

Currency demand factor (γt): A stochastic variable that shifts the intercept of currency traders’ demand for foreign assets, independent of the exchange rate level. A positive shock to γt increases desired foreign asset holdings of currency traders, so arbitrageurs reduce their foreign-currency position, which affects their bond positions through hedging. In the estimated model, γt is the primary driver of exchange-rate movements.

Summary based on LSE Research Online accepted version (accepted manuscript). AI-assisted, human review pending.

Aggregate demand externality and self-fulfilling default cycles

Mon, 01 Jan 0001 00:00:00 +0000

Layer 1 — Overview

Research Question. Why do corporate defaults cluster in recurring episodes rather than occurring smoothly? The paper asks whether observable fundamental factors — firm characteristics and macroeconomic variables — are sufficient to account for the clustered default patterns documented in the data, and, if not, what theoretical mechanism can explain them.

Empirical Motivation. Using Moody’s historical default rate data, the authors document that the long-run average corporate bond default rate during 1866–2008 was approximately 1.50%, yet defaults were highly episodic: the worst three-year period during the Great Depression totaled 12.88%, and the three-year period 1873–1875 after the railroad boom reached 35.80%. A Markov switching regression on post-war default rate data (1951–2017) strongly rejects a linear no-switch model in favor of a two-regime model across all information criteria (AIC, HQ, SC, and log-likelihood). The estimated high-default regime has a mean default rate of 1.93% (unconditional mean µ/(1−ρ)) — roughly eight times the 0.23% mean of the low-default regime — and a standard deviation nearly six times larger. The high-default regime persists on average 5.81 years (transition probability of staying ≈ 0.83), while the low-default regime lasts approximately 7.52 years (staying probability ≈ 0.87).

Model. The authors build a continuous-time general equilibrium model with Dixit-Stiglitz monopolistic competition (CES aggregation with elasticity σ) and an endogenous entry/exit/default mechanism. Households are risk-neutral and also act as entrepreneurs. At each instant, δµ new project blueprints are invented; entrepreneurs borrow to invest, then face an idiosyncratic liquidity shock z drawn from a Pareto distribution G(z). Entrepreneurs continue if z ≤ Z*, a cutoff determined by the continuation value of the firm, and default otherwise. Continuing firms become monopolists for a new variety until that variety becomes obsolete at a Poisson rate δ. Each operating firm must borrow working capital constrained by its firm value Vt (collateral constraint wtnjt ≤ θVjt). The entire equilibrium reduces to a two-dimensional dynamical system in (Mt, Vt), where Mt is the number of operating firms (state variable) and Vt is the firm value (control variable).

Key Mechanism — Demand Externality and Positive Feedback. Under CES aggregation, each firm’s gross revenue is y_jt^(1–1/σ) · Y_t^(1/σ), making individual firm revenue increasing in aggregate output Yt. A decline in Yt lowers firm profits and firm value Vt, which raises the default threshold Z* and increases the fraction of projects that are abandoned. Fewer operating firms further depress Yt, closing a positive feedback loop. This static strategic complementarity (through CES) is combined with dynamic strategic complementarity through the borrowing constraint: higher expected future firm value relaxes current working capital constraints, raising current production.

Multiple Equilibria and Global Dynamics. The two-locus phase diagram (˙Mt = 0 and ˙Vt = 0) yields multiple intersections — and hence multiple steady states — when productivity A lies in an intermediate range (A < A < Ā). When A > Ā, a single good saddle-point equilibrium exists. When A < A, no equilibrium can be sustained. In the intermediate range, a good steady state (low default rate, high firm value) coexists with a bad steady state (high default rate, low firm value). The good steady state is always a saddle; the bad steady state is a sink (locally indeterminate, κ < κ_Hopf) or a source (locally determinate but globally indeterminate, κ > κ_Hopf), depending on parameter κ = 1 + (θ + ρ)/δ.

Bogdanov-Takens Bifurcation. Using global dynamical methods, the paper demonstrates richer indeterminacy than local analysis permits. Near the Bogdanov-Takens point (κ, Ā), the system can exhibit: (a) infinite equilibrium trajectories converging to the bad steady state; (b) saddle-loop bifurcation at κ = κ_SL ≈ 14.25 (under the baseline calibration); (c) stable or unstable periodic orbits for κ ∈ (κ_Hopf, κ_SL) — endogenous business cycles in a perfect-foresight equilibrium; and (d) multiple trajectories from near the source that converge to the good saddle equilibrium.

Simulation of Clustered Defaults. With a two-state Markov process for productivity (Ah = 10, Al = 9.34) and pessimistic sentiment shifts (the “ugly” state), the model replicates the cluster pattern: in the good/high-productivity state, the default rate is near zero; when productivity falls to low and sentiment turns pessimistic, the default rate can spike to approximately 12%, consistent with the Great Depression observation. Critically, the paper shows that the cluster pattern is generated only under global dynamics — restricting to local dynamics produces substantially smaller fluctuations in the default rate, confirming that the ugly (sink) equilibrium is essential.

Policy. A countercyclical subsidy to non-defaulting entrants — financed by a lump-sum tax, calibrated as tr(Vt) = τ(VG − Vt) — shifts the ˙Mt = 0 locus downward and can eliminate the bad steady state entirely, leaving only the good saddle-path equilibrium. The paper provides a closed-form sufficiency condition for τ (Proposition 7).

Scope Conditions. Multiple equilibria require: (i) productivity in the intermediate range A < A < Ā; (ii) the elasticity of substitution σ not too large (below a threshold σ̄ that itself depends on µ); (iii) the borrowing constraint binding (δ > θσ/((σ–1)κ), which can always be ensured by choosing δ sufficiently large). Clustered defaults in the simulation require the joint occurrence of a negative fundamental shock (productivity falling from high to low) and a shift to pessimistic sentiment; either factor alone generates only limited default amplification.

Layer 2 — Q&A

Q1. What is the core empirical motivation for the model, and what does the regime-switching analysis establish?

The paper documents that the corporate bond default rate, drawn from Moody’s data covering 1866–2008, clusters sharply in episodes: the long-run average is 1.50%, yet the worst three-year period of the Great Depression totaled 12.88% and 1873–1875 reached 35.80%. A Markov switching regression on 1951–2017 data strongly rejects a linear no-regime-switch model across all four criteria (log-likelihood, AIC, HQ, SC). The two-regime model identifies a high-default regime with unconditional mean 1.93% and standard deviation roughly six times the low-default regime’s, a persistence probability of approximately 0.83 (duration ≈ 5.81 years), and a low-default regime with unconditional mean 0.23% and persistence approximately 0.87 (duration ≈ 7.52 years). The regime-switching result supports the prior literature’s claim (Das et al. 2007; Duffie et al. 2009; Azizpour et al. 2018) that observable fundamentals alone cannot account for clustered defaults.

Q2. How does the Dixit-Stiglitz CES structure generate a demand externality that links aggregate output to individual firm default decisions?

Under CES aggregation with elasticity σ, each firm’s gross revenue equals y_jt^(1–1/σ) · Y_t^(1/σ) (equation 7), so aggregate output Yt directly enters individual firm revenue. Each firm takes Yt as given, yet the aggregation of all firms’ output determines Yt. When aggregate output falls — because more firms have defaulted and exited production — each remaining firm’s revenue and profit fall, reducing the firm’s continuation value Vt. A lower Vt tightens the borrowing constraint (wtnjt ≤ θVjt), reduces working capital, and raises the probability that the firm’s idiosyncratic liquidity shock will exceed the default threshold Z*, producing further defaults. This positive feedback constitutes the demand externality: individual firms’ decisions are strategic complements, both statically (through CES demand) and dynamically (through the borrowing constraint on working capital).

Q3. What is the two-dimensional dynamical system that summarizes the equilibrium, and what do the two loci look like in the phase diagram?

The entire equilibrium reduces to two differential equations in (Mt, Vt): ˙Mt = –δ[Mt – µG(Z(Vt))] and ˙Vt = κδVt[1 – F(Vt, Mt)], where F captures the ratio of monopoly profit to firm value including the borrowing constraint. The ˙Mt = 0 locus slopes strictly upward because a higher firm value Vt raises the default cutoff Z* and lowers the fraction of entrants who default, so more firms survive and Mt rises until absorption equals entry. This locus has a minimum at Mm = µG(zm) because firm value must exceed the threshold that sustains the credit market. The ˙Vt = 0 locus is non-monotonic: it first slopes upward (more firms raise aggregate demand and profit through the scale/externality channel) and then slopes downward (more firms tighten the labor market, raising wages and lowering profits). The two opposing channels make the ˙Vt = 0 locus hump-shaped, creating the possibility of two intersections and hence two steady states.

Q4. Under what conditions do multiple steady states exist, and what does each look like?

Multiple steady states exist when productivity A satisfies A < A < Ā, where A and Ā are closed-form thresholds given by Equations (A.3) and (A.4), and the elasticity of substitution σ is below a threshold σ̄ (Equation A.5). When A < A, neither locus intersects and no equilibrium is sustainable. When A > Ā, a single good saddle-point equilibrium exists. In the multiple-equilibria range, the good steady state has a higher firm value and a smaller fraction of firms defaulting; the bad steady state has a lower firm value and a higher default rate. Under the paper’s numerical calibration (A = 10, η = 6.5, Zmin = 0.88), the low default rate at the good steady state is approximately 1.5% and the high default rate at the bad steady state is between 12% and 13%.

Q5. What are the local dynamics around each steady state, and how does parameter κ determine whether the bad steady state is a sink or a source?

Proposition 5 shows that the good steady state is always a saddle point, ensuring a unique convergent path for initial Mt near Mg_0. The bad steady state’s local nature depends on κ = 1 + (θ + ρ)/δ and the critical value κ_Hopf = 1 + ψ/(θMb_0Vb_0). When κ is between 1 and κ_Hopf, the Jacobian trace is negative and the bad steady state is a sink with one order of indeterminacy: given Mt close to Mb_0, infinitely many initial values of the control variable Vt satisfy all equilibrium conditions. When κ > κ_Hopf, the bad steady state is a source point; the economy diverges from it. Because κ does not affect the steady-state locations (Proposition 3), one can vary κ to change the dynamic character without moving the equilibria in the phase diagram.

Q6. What does the global dynamics analysis reveal that local analysis misses?

Global analysis via Bogdanov-Takens bifurcation (Proposition 6) reveals three classes of dynamics absent from local analysis. First, even in the saddle-source case (locally determinate), there exist multiple equilibrium trajectories diverging from near the bad (source) steady state and converging to the good (saddle) steady state; these paths satisfy all equilibrium conditions including transversality but are incorrectly ruled out by local methods. Second, at the critical value κ_SL ≈ 14.25 (under the baseline calibration), a homoclinic saddle-loop orbit connects the saddle point to itself — all trajectories interior to the loop converge to the bad steady state. Third, for κ between κ_Hopf and κ_SL, periodic orbits arise in a perfect-foresight equilibrium with no external shocks. For example, at κ = 14.9, the phase diagram displays a unique periodic orbit around the bad steady state, with two distinct initial values of Vt for any given Mt near the orbit — endogenous, perpetual oscillations without any exogenous driving force. Numerical experiments confirm that Mt = 0.23 admits two rational-expectations values of Vt (2.09 and 3.55) on the saddle path alone, illustrating abundant indeterminacy even at the endpoint.

Q7. How does the paper simulate the clustered default pattern and what is the role of the “ugly” equilibrium?

The paper constructs a three-state Markov economy: “good” (high productivity Ah = 10, single saddle equilibrium, near-zero default rate), “bad” (low productivity Al = 9.34, saddle-path equilibrium, modestly elevated defaults), and “ugly” (low productivity, sink-path equilibrium, sharply elevated defaults). The ugly state is reached when, upon a productivity decline, firms adopt pessimistic expectations and the economy slides to the high-default sink instead of remaining on the low-default saddle path. Transition probabilities are set so that the average ugly-state duration is approximately 6 years and roughly 45% of periods are ugly, consistent with the regime-switching estimates. With Zmin = 0.2 and η = 15, the ugly-state default rate can reach approximately 12%, matching the Great Depression observation. The counterfactual experiment deletes the ugly state (pGU = 0) and resets pGB = 0.45: the resulting default rate stays close to zero with no cluster pattern, demonstrating that global dynamics (the ugly sink) rather than the fundamental shock alone generate the clustering.

Q8. Can purely sentiment-driven cycles generate the clustered default pattern?

Section 6.2 fixes productivity at a low level (A = 9.53) and drives switches between the bad (saddle path) and ugly (sink path) states by pure sentiment shocks alone (πBU and πUB). The simulated default rate does spike upward when sentiment turns pessimistic, but the rises are generally more modest than in the combined fundamental-plus-sentiment exercise, and the default rate can no longer be characterized as countercyclical. The authors conclude that the realistic observed default cluster is the result of a combination of negative fundamental shocks and pessimistic sentiment shifts; either ingredient alone is insufficient to replicate all features of the data.

Q9. How does the collateral constraint on working capital create dynamic strategic complementarity?

Following Jermann and Quadrini (2012), Liu and Wang (2014), and Lian and Ma (2021), each operating firm must borrow to pay wages each period, subject to the constraint wtnjt ≤ θVjt. Since Vt is forward-looking (the discounted present value of the firm’s monopoly profit stream), optimistic expectations about future output raise Vt, relax the borrowing constraint, allow firms to hire more labor and produce more output today, and thereby validate optimism. This intertemporal complementarity means that the equilibrium is sensitive not only to current fundamentals but also to beliefs about the future, opening the channel for sentiment-driven multiple equilibria and self-fulfilling cycles.

Q10. What is the policy remedy for the bad equilibrium, and how does it work?

Proposition 7 establishes that a countercyclical lump-sum-tax-financed subsidy to non-defaulting entrants, tr(Vt) = τ(VG − Vt), with τ exceeding a computable threshold, eliminates the bad steady state. The subsidy works by effectively raising the value of continuing for a firm at any given Vt and Mt, shifting the ˙Mt = 0 locus downward until it lies below the ˙Vt = 0 locus everywhere in the relevant range, eliminating the second intersection and leaving only the good saddle-path equilibrium. The numerical illustration uses parameters from Section 6 with A = 9.67 and τ = 1/3 to demonstrate that the bad steady state vanishes and the phase diagram has a single equilibrium. The subsidy is self-limiting: in normal conditions when firm value is already high (Vt ≈ VG), the transfer is near zero.

Q11. How does this paper differ from Cui and Kaas (2021), the most closely related predecessor?

Cui and Kaas (2021) show default cycles from self-fulfilling beliefs in a fully competitive firm environment, focusing on intertemporal default coordination. The present paper differs in three respects. First, firms engage in monopolistic competition under CES preferences, and the main novel mechanism is cross-firm default contagion through the demand externality — which can produce multiple equilibria even in a static setting, without any intertemporal coordination. Second, the paper examines the joint role of fundamental shocks and aggregate-demand externalities together, showing that multiple equilibria arise only in the presence of sufficiently low productivity (A < A < Ā), making indeterminacy contingent on external fundamentals rather than structural parameters alone. Third, the continuous-time framework with full global analysis via Bogdanov-Takens bifurcation allows characterization of periodic orbits and the interaction of the ugly sink path with Markov productivity regimes — dynamics not covered in Cui and Kaas (2021).

Q12. What is the markup prediction of the model, and is it consistent with empirical evidence?

Under Dixit-Stiglitz CES with elasticity σ, the equilibrium markup of each intermediate good equals σ/(σ–1) at the firm level. However, the measured gross markup — which includes the effective collateral constraint — is predicted to comove positively with the default rate in the model, and hence the markup is countercyclical. The paper notes this is consistent with the well-documented empirical regularity in Bils (1987) and Rotemberg and Woodford (1999). Additionally, the model replicates the finding in Gilchrist and Zakrajšek (2012) that a low default rate is associated with a high firm entry rate.

Key Concepts

Demand Externality (Dixit-Stiglitz type). In the paper’s sense, this is the mechanism by which individual firms’ revenues depend on aggregate output Yt through the CES aggregator: each firm’s gross revenue is y_jt^(1–1/σ) · Y_t^(1/σ). Each firm takes Yt as given, but the aggregation of all firms’ output determines Yt. This creates a positive spillover: more operating firms raise aggregate output, which raises each firm’s revenue, and vice versa. The paper uses this as the central transmission channel for self-fulfilling defaults, in contrast to prior literature that emphasized debt networks or asymmetric information contagion.

Self-Fulfilling Default Cycle. A dynamic equilibrium path in which pessimistic expectations about aggregate output are validated: if firms anticipate that more other firms will default (lowering Yt), their own continuation value Vt falls, raising the probability that their idiosyncratic liquidity shock will exceed the default threshold, increasing actual defaults, further lowering Yt, and so on. The paper distinguishes this from shock-amplifier stories by constructing a model with multiple rational-expectations equilibria in which the aggregate default rate is determined in part by initial beliefs.

Bogdanov-Takens Bifurcation. A mathematical tool for global dynamics analysis applied to two-dimensional continuous-time systems. In the paper, it is used to characterize system behavior when the parameters (κ, A) are near the point (κ̄, Ā) at which the Jacobian has two zero eigenvalues. Near this point, the system can exhibit saddle-loop bifurcations, Hopf bifurcations, homoclinic orbits, and stable or unstable periodic orbits — all of which are invisible to local linearization analysis. The paper uses this to establish that indeterminacy is more pervasive than local analysis suggests.

Good / Bad / Ugly Steady States. In the paper’s three-regime framework: the “good” state is the unique saddle-point equilibrium under high productivity Ah, with near-zero default rates; the “bad” state is the saddle-path equilibrium under low productivity Al, with modestly elevated defaults; the “ugly” state is the sink-path equilibrium under low productivity, characterized by self-fulfilling high default rates (up to ~12%). The ugly state is reached only when pessimistic sentiment coincides with the low-productivity regime, and it is the ugly state that generates the cluster pattern in simulation.

Collateral Constraint on Working Capital. The firm-level borrowing constraint wtnjt ≤ θVjt, where θ is the collateral ratio and Vjt is the firm’s continuation value. This constraint means that higher expected future profits — by raising Vt — relax the current borrowing limit, increase current labor demand and output, and create dynamic strategic complementarity between current and future production. It is this constraint, combined with the CES demand externality, that makes the dynamical system two-dimensional and generates the non-monotonic ˙Vt = 0 locus.

Global Indeterminacy. The existence, given an initial state variable Mt, of multiple equilibrium trajectories — each satisfying all equilibrium conditions including transversality — that converge to different steady states or follow periodic paths. In the paper, global indeterminacy arises even when the system is locally determinate (e.g., in the saddle-source case): trajectories diverging from near the source steady state can converge to the saddle steady state along multiple paths, none of which is detectable by local linearization.

Periodic Orbit (Endogenous Cycle). In the paper, a closed trajectory in the (Mt, Vt) phase plane that the economy follows indefinitely in perfect-foresight equilibrium without any exogenous shocks. Such orbits exist for κ ∈ (κ_Hopf, κ_SL), are stable if S < 0 and unstable if S > 0 (where S is a computable quantity defined in Equation A.13). Their existence demonstrates that business cycles can arise purely from internal forces — the demand externality and borrowing constraint — consistent with the view in Beaudry, Galizia, and Portier (2020).

Balance-Sheet Policy and the Term Premium: High-Frequency Evidence

Mon, 01 Jan 0001 00:00:00 +0000

When a central bank shrinks its balance sheet, how much do long-term interest rates actually move — and through which channel? Using minute-by-minute market data around balance-sheet announcements, the authors estimate that much of the long-rate response works through the term premium rather than through changed expectations of future short rates. The result is an estimate for their 2009–2024 sample under their identifying assumptions — evidence consistent with a term-premium channel, not a universal constant.

Summary of a forthcoming paper, AI-assisted and human-reviewed. See the linked original for the authoritative claims and full conditions.

In depth

Q1. Does balance-sheet policy move long rates through the term premium or through expected short rates?

The paper estimates that a substantial share of the long-rate response operates through the term premium, with a smaller role for revised short-rate expectations — though it frames this as identification within their window, not a structural decomposition that holds in all regimes. This sits against a literature that has split the response into a signaling channel and a portfolio-balance channel; the contribution here is using intraday yields to isolate the announcement effect from contaminating macro news.

Q2. How is the effect identified, and why high-frequency?

By measuring yield changes in narrow windows around scheduled balance-sheet announcements, so that other macroeconomic news is unlikely to move rates within the window. The maintained assumption is that within a tight enough window, the announcement is the dominant shock — a standard high-frequency identification premise. The authors note the assumption is weaker around unscheduled communications, and restrict the main sample accordingly.

Q3. What does this imply for the pace of balance-sheet runoff?

If transmission runs through the term premium, the pace and predictability of runoff plausibly matter for long rates — but the paper presents this as suggestive, stopping short of a calibrated policy rule. The reading is that quantity and communication interact, consistent with prior work on announcement effects, rather than that runoff has a single mechanical effect on yields.

Key concepts

term premium: The extra return investors require for holding a long-term bond instead of rolling over short-term ones — here, the part of long rates not explained by expected future short rates.
balance-sheet policy: A central bank changing the size or composition of its asset holdings (expansion via purchases, runoff via “quantitative tightening”) as a policy tool distinct from setting the short-term rate.
high-frequency identification: Inferring a policy action’s effect from price moves in a very short window around the announcement, on the assumption that little else moves markets inside that window.

Costs of Financing U.S. Federal Debt Under a Gold Standard: 1791-1933

Mon, 01 Jan 0001 00:00:00 +0000

Overview

This paper constructs a new dataset of US federal bond prices and uses it to estimate the full term structure of yields on gold-denominated US federal debt from 1791 to 1933 — the entire gold standard era. The core research question is how the costs of financing US federal debt evolved over this period and what monetary, fiscal, and financial policy changes drove that evolution, with the ultimate aim of understanding how the US built fiscal capacity and transformed its debt from a “junk bond” into a global “safe asset.”

Data and Methodology. The authors compile monthly prices, quantities, and descriptions of all US Treasury securities from 1776 to 1960 (the Hall et al. 2018 dataset). Bonds with less than one year to maturity are excluded from the main estimation due to liquidity premia. The primary estimation uses a Dynamic Nelson-Siegel (DNS) model with stochastic volatility (Diebold and Li 2006; Hautsch and Yang 2012), estimated by Bayesian MCMC. A key methodological innovation is the addition of bond-specific idiosyncratic pricing errors (Assumption 3), which allows the authors to include bonds with heterogeneous contract features — call options, indefinite maturities, conversion features — that characterize 19th-century US debt without either dropping them from the sample or having their idiosyncrasies distort the common yield curve. The data are “big” in the time-series dimension but sparse in the maturity (cross-sectional) dimension, frequently offering fewer than five price observations per month; the DNS framework pools information across time to address this sparsity.

For the greenback period (1862–1878), the authors extend the approach by modeling the greenback yield curve as a function of the gold yield curve and a time-varying VAR model of exchange rate expectations (Assumptions 4–5). Only nine greenback-denominated bonds exist in the sample, most of them short-term; the VAR is estimated jointly using exchange rate data and the relative prices of greenback and gold bonds.

Main Findings.

Long-run decline in yields. The 10-year gold-denominated zero-coupon yield fell from approximately 8% in 1800 to approximately 2% in 1900, consistent with global secular decline trends, but the trajectory stabilized near 2% after 1900 — suggesting US debt began to play a distinctive “safe-asset” role from the turn of the 20th century.
War spikes were much larger than previously understood. The paper’s estimate of the 10-year gold yield reaches a peak of approximately 16% near the end of the Civil War. This is substantially higher than the Homer and Sylla (2004) peak of 6% at the start of the war. The discrepancy arises because Homer and Sylla used bonds trading at par — which did not exist during the Civil War — while this paper uses the full universe of bonds at monthly frequency.
Yield curve slope switched sign. The term spread (10-year minus 2-year gold yield) was typically negative before the Civil War (inverted yield curve) and turned persistently positive afterward. The authors link this switch to a change in long-run inflation predictability: inflation was relatively hard to forecast before the Civil War and easier to forecast after, consistent with a negative inflation-risk premium in the pre-war period.
Default risk premium disappeared around 1905. Comparing hypothetical gold-denominated US consols to UK consols (the 19th-century benchmark safe asset), US yields were persistently above UK yields until approximately 1905, when US yields fell below UK yields. This indicates that US federal debt acquired safe-asset characteristics well before World War I, foreshadowing the shift in global reserve asset status during and after Bretton Woods.
Nominal anchor during the Civil War. Despite a 60% depreciation of the greenback against gold during the Civil War (100 greenback dollars could be purchased for as few as 40 gold dollars in summer 1864), investors expected greenbacks to eventually return to gold parity. Estimated long-run exchange rate expectations remained anchored at one-for-one parity throughout the period. This kept greenback-denominated bond yields flat at approximately 6% — bonds traded around par — explaining the “Civil War yield puzzle” noted by Friedman and Schwartz (1963).
Short-rate disconnect. Short-maturity government bonds (less than one year) traded with a premium of approximately 0.25 to 0.5 percentage points relative to model-implied yields throughout most of the 19th century, reflecting scarcity of money-like assets. This premium effectively disappeared from the 1880s until World War I — coinciding with the National Banking Era — and then reappeared in the 1920s after the Federal Reserve created a secondary market for Certificates of Indebtedness.

Q&A

Q1: Why does the paper restrict estimation to bonds with maturity greater than one year? Short-maturity Treasury notes exhibited particularly large estimated bond-specific pricing errors in preliminary analysis, which the authors attribute to a liquidity premium: short-term government debt was used for transactions and thus commanded a money-like premium that a common discount function cannot accommodate. To keep this liquidity premium from distorting estimates of the longer end of the curve, these bonds are excluded from the main estimation. Short-maturity bonds are then studied separately as an “out-of-sample” exercise (the short-rate disconnect).

Q2: How does the Dynamic Nelson-Siegel model with stochastic volatility solve the cross-sectional sparsity problem? The DNS model parameterizes the entire yield curve at each date using only three latent factors — level (L), slope (S), and curvature (C) — which follow a driftless random walk. The stochastic volatility component, captured in the covariance matrix Σt, governs how much information is pooled across adjacent time periods. When Σt → 0, the yield curve is assumed constant (full pooling); when Σt → ∞, estimates are date-by-date (no pooling). By allowing Σt to vary, the model pools more heavily in sparse periods and less during wars when yields change rapidly. The companion paper (Payne et al. 2023a) confirms via information criteria that stochastic volatility and correlated shocks improve fit without overfitting.

Q3: What is the bond-specific pricing error and why is it essential for historical data? Assumption 3 adds to each bond i a Gaussian pricing error with mean zero and bond-specific standard deviation σ(i)_m (scaled by Macaulay duration to approximate yield-space errors). This allows bonds with idiosyncratic contract features — call options, conversion clauses, ambiguous payment currency — to inform the common yield curve without unduly distorting it. Bonds with larger σ(i)_m receive less weight in estimation. In modern datasets, researchers pre-select homogeneous bonds and use time-specific pricing errors; the historical sparsity prevents that approach here.

Q4: How large were Civil War yields compared to prior estimates, and why does the discrepancy arise? The paper’s posterior median for the 10-year gold zero-coupon yield peaks at approximately 16% near the end of the Civil War. Homer and Sylla (2004) report a peak of 6% at the start of the war. The discrepancy arises because Homer and Sylla used bonds trading close to par, but during the Civil War no federal bonds traded at gold-price par (Lincoln’s re-election was uncertain in summer 1864; 100 greenback dollars could be purchased for 40 gold dollars, implying 6% coupon bonds were priced at 40% of par, implying yields in excess of 15%). This paper uses the full universe of Treasury bonds at monthly frequency and allows all bonds — regardless of trading price — to inform the yield curve.

Q5: When did US debt cease to carry a default risk premium relative to UK debt, and how is this measured? The authors compare yields-to-maturity on gold-denominated UK consols to those on hypothetical gold-denominated US consols promising the same coupon flows. Because both countries were on a gold standard for most of the period and UK consols were the 19th-century safe asset, the spread is interpreted as a risk premium on US debt. US yields fell below UK yields persistently after approximately 1905, indicating that US debt was priced as a safe asset well before World War I. US yields were temporarily close to UK yields in the 1820s but the spread re-widened after the Jacksonian era, state defaults in the 1840s, and the Civil War. The spread closed only after Civil War disruptions resolved, the National Banking System matured, and gold-greenback parity was restored in 1879.

Q6: What is the “nominal anchor” finding during the greenback era, and what econometric method uncovers it? During 1862–1878, the federal government issued non-convertible greenback dollars alongside gold bonds. The greenback depreciated substantially (to 40 cents per gold dollar in 1864), yet greenback-paying bonds traded near par, implying greenback yields near 6%. The authors model the greenback yield curve as a product of the gold discount function and a “multiplier” z(j)_t capturing the expected future gold-to-greenback exchange rate at each horizon j (Assumption 4). The exchange rate expectations are estimated via a time-varying VAR(2) model of the gold-to-greenback and gold-to-goods exchange rates (Assumption 5), jointly constrained by the prices of greenback bonds via an interest-rate parity condition. The resulting estimates show that throughout the greenback era — even during large wartime depreciations — investors’ long-run expectations of the exchange rate remained anchored near gold parity, consistent with anticipated eventual resumption.

Q7: How did political events affect exchange rate expectations during and after the Civil War? The time-varying VAR captures shifts in exchange rate expectations associated with identifiable political events. Grant’s victory in 1869 (which resolved uncertainty about whether debts would be honored in gold) coincided with an increase in the price of greenbacks, a decrease in expected greenback appreciation, and a closing of the gap between greenback and gold 10-year yields. In the early 1870s, following the Panic of 1873 and uncertainty about resumption, investors came to expect that gold-greenback discrepancies would persist almost indefinitely, causing gold and greenback yields to converge. The Resumption Act of January 1875 then shifted 2-year and 10-year expectations back toward parity.

Q8: What is the short-rate disconnect and what does it reveal about the National Banking Era? The short-rate disconnect is the difference between observed yields-to-maturity for bonds with less than one year to maturity and the yields-to-maturity implied by the model estimated on bonds with more than one year maturity. A positive disconnect means short-maturity bonds yielded less than long-maturity bonds conditional on the model — indicating a liquidity premium on short-term debt. The authors find a persistent premium of 0.25 to 0.5 percentage points through most of the 19th century, reflecting scarcity of money-like assets when state bank notes circulated at variable discounts. The premium disappeared from approximately the 1880s to World War I, coinciding with the mature National Banking Era after greenback-gold parity was restored in January 1879. The authors interpret this as evidence that the National Banking Acts (1862–1866), which allowed National Banks to issue standardized bank notes backed by long-term US government bonds, ultimately succeeded in supplying liquid assets and equalizing the pricing of short- and long-term federal debt — but only after the currency risk from the greenback period had been resolved.

Q9: How does the composite long-term yield series (Officer-Williamson / Homer-Sylla) distort historical narratives? The composite series combines Homer and Sylla US federal yields (1798–1861), New England Municipal bond yields (1862–1899), and corporate bond yields (1900–1940). The paper shows that this composite series substantially underestimates the increase in US federal borrowing costs during Civil War deficits (peak of 6% vs. this paper’s 16%) and overstates post-Civil War borrowing costs by mixing in riskier private obligations. The authors argue that earlier findings of no strong association between 19th-century interest costs and deficits (Evans 1985, 1987) may reflect the composite series’ failure to accurately capture federal borrowing costs during large deficit episodes.

Q10: How did the yield curve slope change after the Civil War and what explains it? The term spread (10-year minus 2-year gold yield) was typically negative before the Civil War and positive after the late 1870s. Major wars caused sharp temporary decreases (inversions). The authors connect the sign switch to a change in long-run inflation dynamics documented in a companion paper (Payne et al. 2023b): long-run inflation was hard to predict before the Civil War and easier to predict after, suggesting gold bonds provided a better inflation hedge in the pre-war period (negative inflation-risk premium), which is consistent with asset pricing theory producing a downward-sloping yield curve. After the Civil War, as inflation became more predictable, the inflation-risk premium became positive and the yield curve turned upward-sloping.

Q11: What did the National Banking Acts seek to do and was the puzzle of bank note under-issuance resolved? The National Banking Acts (1862, 1863, 1865, 1866) authorized federally chartered banks to issue bank notes up to 90% of the par or market value of eligible US Treasury bonds deposited as collateral, subject to a 1% annual tax on notes outstanding (0.5% after 1900), compared to a 10% tax on state bank notes. The intended goals were to increase the supply of short-term liquid assets and to increase bank demand for long-term federal debt, thereby lowering long-term yields and eliminating the short-rate disconnect. A long-standing puzzle (Friedman-Schwartz, Cagan, Champ, Calomiris-Mason) held that yields on eligible Treasuries did not fall enough to equal the note tax rate, implying under-issuance. The paper’s analysis of the short-rate disconnect offers a resolution: if one focuses on the disconnect rather than the yield-tax spread, the National Banking Acts appear to have largely achieved their goals by the 1880s — but only after greenback-gold parity was restored, suggesting that currency devaluation risk had initially restrained bank note issuance, as hypothesized by Cagan (1965).

Key Concepts

Dynamic Nelson-Siegel (DNS) model with stochastic volatility: A parametric yield curve model (Diebold-Li 2006) parameterizing zero-coupon yields at each date as a function of three latent factors — level (L), slope (S), curvature (C) — following a driftless random walk. The paper extends this with time-varying shock volatilities (stochastic volatility) to allow the degree of information pooling across time periods to vary with institutional and wartime disruptions. Used here to handle cross-sectional sparsity in historical bond data.

Bond-specific pricing error: A Gaussian pricing error with bond-specific standard deviation σ(i)_m (scaled by Macaulay duration) added to each bond’s observed price. Allows bonds with heterogeneous and idiosyncratic contract features (call options, conversion clauses) to inform a common discount function without distorting it, by automatically down-weighting “peculiar” bonds through higher estimated σ(i)_m.

Short-rate disconnect (liquidity premium): The systematic difference between observed yields-to-maturity on bonds with less than one year to maturity and yields implied by a pricing kernel fitted on bonds with more than one year to maturity. Interpreted as a money-like convenience yield (liquidity premium) on short-term debt: when money-like assets are scarce, short-term bonds are overpriced (lower yields) relative to the term structure implied by longer maturities. Measured here as an out-of-sample fit residual from the DNS model.

Denomination risk: The risk that the unit of account in which bond payments are promised may change in value relative to gold. During the greenback era (1862–1878), bonds denominated in greenbacks carried denomination risk because greenbacks could depreciate against gold. The paper distinguishes denomination risk from default risk by estimating separate gold and greenback yield curves and modeling exchange rate expectations.

Nominal anchor: The phenomenon in which long-run market expectations of the gold-to-greenback exchange rate remained anchored near gold parity (one-for-one) even during large short-run depreciations during the Civil War. Inferred from the observation that greenback-denominated bonds traded near par (yield ~6%) while the spot greenback depreciated by up to 60% against gold, implying investors anticipated eventual full appreciation.

Default risk premium (US-UK yield spread): The difference between yields on hypothetical gold-denominated US consols and yields on UK consols. Since both were on a gold standard (so inflation expectations are similar), and UK consols were the 19th-century benchmark safe asset, the spread is interpreted as the compensation investors demanded for the risk that the US might default or alter payment terms. Persistently positive until approximately 1905, then became negative.

Convenience yield: An implicit yield that accrues to holders of money-like or safe assets because of their use in transactions or as collateral. In this paper, it emerges as the spread between yields on US federal bonds and other low-risk bonds in the late 19th century, reflecting increased demand for Treasuries as reserves under the National Banking System. Historically identified via the short-rate disconnect disappearing in the National Banking Era.

Credit Easing versus Quantitative Easing: Evidence from Corporate and Government Bond Purchase Programs

Mon, 01 Jan 0001 00:00:00 +0000

Using security-level data on individual corporate bond prices and the Bank of England’s published purchase quantities across its gilt purchase programs (QE1: £200bn, QE2: £125bn, QE3: £50bn, QE4: £60bn) and Corporate Bond Purchase Scheme (CBPS: £10bn of investment-grade sterling corporate bonds), this paper estimates supply effects of QE and CE on UK corporate bond prices, credit spreads, and new issuance separately, exploiting cross-sectional variation in quantities purchased as identifying variation via an instrumental variables approach. In the case of QE alone, supply effects on corporate bond prices are significant at announcement and larger over the full stock-effect horizon, but pass-through to credit spreads is found to be limited to the default-free component of corporate yields under normal market conditions — an exception is QE1 during the financial crisis, when QE’s cross-asset supply effects also significantly lowered credit spreads in the longer run. CE via the CBPS is found to be more effective than QE in reducing credit spreads for higher-rated investment-grade bonds even under normal conditions, and is the only program that generates a statistically significant increase in sterling corporate bond issuance. The results are consistent with QE and CE working through partially distinct channels — QE primarily affecting the default-free component of corporate yields, CE additionally compressing the credit-spread component — and complementing each other for higher-rated bonds.

Summary of a forthcoming paper, AI-assisted and human-reviewed. See the linked original for the authoritative claims and full conditions.

In depth

Q1. What is the empirical strategy and why use a security-level approach?

The paper uses a two-stage instrumental variables (IV) approach at the individual corporate bond level, with pre-program bond characteristics — maturity, yield-curve fitting errors, the BoE’s prior ownership share in the gilt bucket — serving as instruments for the expected distribution of purchases across bonds, allowing isolation of the supply channel from signaling and duration channels. The security-level approach offers three advantages over aggregate or event-study methods: it enables construction of “substitute buckets” (bonds whose maturity is close to the purchased bonds’) to estimate cross-asset supply effects; it permits direct comparison of the price elasticity with respect to gilt purchases (cross-asset effect) versus corporate bond purchases (within-asset effect); and it allows estimation of both the announcement-day effect and the stock effect — the cumulative price and spread change over the life of each program — which captures the longer-run portfolio-rebalancing contribution separately from the initial market reaction.

Q2. What are QE’s effects on corporate bond prices and credit spreads?

For QE alone (QE1–3), the instrumented gilt substitute purchases have positive and statistically significant effects on corporate bond prices at announcement across all three programs — in the case of QE1, the average 30 basis-point decline in corporate yields on the announcement day is attributed in full to QE supply effects in the paper’s regression. The stock effect — estimated over the full life of each program — is significantly larger than the announcement-day effect, consistent with gradual portfolio rebalancing as predicted by Greenwood, Hanson, and Liao (2018). However, except for QE1, the supply effects do not carry through to credit spreads in either the short run or the longer run, which the paper interprets as consistent with QE working primarily through the default-free component of the corporate yield: corporate yields fell in line with gilt yields, but spreads over gilts were unchanged.

Q3. When does QE affect credit spreads?

QE1’s cross-asset supply effects significantly lowered credit spreads in the longer run, even though QE2 and QE3 do not generate significant credit spread compression in either the short or long run, suggesting that the supply channel interacts with the liquidity channel specifically under conditions of financial market distress. The paper interprets the QE1 exception as reflecting the severe disruption during the 2008–09 financial crisis: when capital mobility across markets is constrained and liquidity premia are elevated, central bank purchases of safe assets may also improve trading conditions in indirectly targeted, less liquid markets such as the corporate bond market, reducing the liquidity component of corporate spreads. This interaction does not appear to be operative in the more normal market conditions of QE2 and QE3.

Q4. How does CE compare to QE in reducing credit spreads and stimulating issuance?

CE via the CBPS is found to be more effective than QE in reducing credit spreads for higher-rated investment-grade bonds even under normal financial market conditions, and a corporate bond’s price sensitivity to its own CBPS purchases is substantially higher than its price sensitivity to gilt substitute purchases; CE is also the only program with a statistically significant positive effect on new sterling corporate bond issuance. Across QE1–3, there is no statistically significant impact of gilt purchases on sterling corporate issuance, while CBPS purchases have positive and statistically significant effects on new sterling corporate bond issuance. The paper characterizes CE and QE as complementary for higher-rated bonds: CE’s credit-spread reduction layers on top of QE’s default-free component effect, making the total stock effect larger than either program alone.

Q5. What happens for lower-rated investment-grade bonds?

For lower-rated investment-grade bonds, the evidence for both cross-asset QE supply effects and within-asset CE supply effects is weaker, and the paper suggests that CE’s stimulation of new bond issuance may have counterbalanced its positive price effects for these bonds through the dilutive effect of new supply. The mechanism is that CE’s reduction in the cost of corporate bond issuance for lower-rated firms induced enough new bond issuance to partially offset the price increase from CBPS purchases, consistent with the issuance channel being most active for the market segment where CBPS created the largest pricing improvement. This dilution effect implies that the net price benefit of CE for lower-rated bonds is smaller than the gross supply-effect estimate.

Key concepts

stock effect : the cumulative effect of the total quantity of bonds purchased under a program on bond prices and spreads, estimated over the full life of the program; in this paper the stock effect is significantly larger than the announcement-day effect, consistent with gradual portfolio rebalancing.

cross-asset supply effect : the pass-through of government bond (gilt) purchase supply shocks to the prices of corporate bonds — an asset class not directly targeted by QE; the paper provides the first estimates of this cross-market supply channel at the security level.

credit spread : the difference between the yield on a corporate bond and the yield on a risk-free government bond of the same maturity; the paper finds QE pass-through is generally limited to the default-free component of corporate yields rather than the credit spread.

default-free component : the part of a corporate bond’s yield attributable to the risk-free interest rate rather than credit risk; the paper finds that QE supply shocks affect this component but generally leave the credit spread unchanged in normal market conditions.

within-asset substitution effect : the price effect of CE purchases on the bonds directly purchased and their corporate bond substitutes, as distinct from cross-asset effects; the paper finds this effect is substantially larger in magnitude than the cross-asset QE effect on corporate bonds.

issuance channel : the mechanism by which lower corporate borrowing costs induced by CE stimulate new corporate bond issuance; the paper finds this channel operates under CE (CBPS) but not under QE (gilt purchases).

Expectation-driven term structure of equity and bond yields

Mon, 01 Jan 0001 00:00:00 +0000

Overview

Research Question. What drives the joint historical dynamics of the term structure of equity yields and nominal bond yields — and can a single unified equilibrium model explain the procyclical equity yield slope, the switch in bond-stock correlation from positive to negative after the late 1990s, the maturity-declining predictability of dividend strip returns, and standard aggregate stock market puzzles?

Key Departure from Prior Literature. Existing equilibrium models (habit formation, long-run risk, disaster risk) rely on time-varying risk premia to explain asset prices. Recent survey evidence challenges this: De La O and Myers (2021) show that most aggregate stock price movements are driven by cash-flow growth expectations rather than return expectations, and Van Binsbergen et al. (2013) show that equity yields are driven mainly by dividend growth expectations. This paper constructs an equilibrium model in which equity (bond) yield variation is attributable to subjective dividend growth (GDP growth) expectations, with a constant subjective risk premium implied by CRRA utility.

Model Architecture. The representative agent has CRRA utility with risk-aversion coefficient γ = 4 and subjective discount factor β = 1.0065 (calibrated to the average 10-year equity yield). The agent departs from rational expectations by having the “belief in the law of small numbers” (Tversky and Kahneman 1971): she perceives small samples to represent their population as well as large samples, leading to subjective learning gains that differ from the rational Kalman gain. The subjective belief updating rule is a modified Kalman filter in which the likelihood is exaggerated by factor (1+θ), producing a subjective learning gain ν that exceeds the Kalman gain K when overreaction applies and falls below it when underreaction applies.

The model has three blocks of fundamentals, each decomposed into a stable and a transitory component. (1) Real GDP growth is decomposed into PCE growth (stable, with a random-walk trend state µ_g) and a volatile gap component (stationary state x_g, persistence ρ_g = 0.941). (2) Inflation is decomposed into core inflation (stable, with trend state µ_π) and a volatile gap (persistence ρ_π = 0.932). (3) Real aggregate dividend is decomposed into a long-duration dividend component dl (levered on log real GDP with leverage λ = 3) and the share of long-duration dividend ds (stationary with persistence ρ_d = 0.94). This cross-sectional decomposition uses firm-level long-term earnings growth (LTG) forecasts from IBES as a model-free equity duration measure.

Estimation. State-space parameters are estimated by maximum likelihood with the Kalman filter on data from NYSE/NASDAQ/AMEX firms (CRSP/Compustat), quarterly, from 1987Q4 to 2019Q4. Subjective learning gains are estimated by minimizing RMSE between model-implied expectations and consensus forecasts: 1-year real GDP growth and inflation from the Survey of Professional Forecasters (SPF, 1981Q3–2019Q4), and 1-year aggregate dividend growth extended from De La O and Myers (2021) to 2019Q4. Equity yield data are from Giglio et al. (2021); bond yields are end-of-quarter zero-coupon nominal yields from Gürkaynak et al. (2007).

Main Findings.

Equity Term Structure Dynamics. The model’s subjective dividend growth expectations drive equity yields. The 1-year model-implied equity yield correlates 0.68 with data; the 10-year correlates 0.79; the 10Y–1Y slope correlates 0.59 with data. Consistent with “belief in the law of small numbers,” the agent overreacts to dividend news (estimated learning gains νl_d = 0.166 and νs_d = 0.458, both below their Kalman gains, which under the level-to-growth translation implies overreaction to dividend growth news, confirmed by negative CG(2015) regression slope coefficients of −0.69 at 1Y and −0.97 at 5Y).
Procyclical Equity Yield Slope. During recessions, the average equity yield slope (10Y–1Y) in the model is −3.77%; during expansions it is +3.96%, matching the data (−5.50% in recessions, +3.93% in expansions). The sign reversal is driven primarily by the dividend-specific component of the decomposition: in recessions, short-run dividend growth expectations fall much more sharply than long-run expectations.
Bond Pricing. The model’s 1-year and 10-year nominal bond yields achieve correlations of 0.92 and 0.95 with their data counterparts, inheriting the explanatory power of Zhao (2020) for the bond market. The agent underreacts to GDP growth and inflation news (estimated learning gains well below Kalman gains, confirmed by positive CG(2015) slope coefficients of +2.08 at 1Y for GDP growth and +1.01 at 1Y for inflation).
Bond-Stock Correlation Switch. In data, 10Y bond vs. dividend strip return correlation (5Y strip) goes from +0.46 before 2000 to −0.49 after 2000. The model produces +0.14 before and −0.56 after (for the 5Y strip). Decomposing the change in bond-stock return covariance: the “inflation real effect” (correlation between expected inflation and real growth) accounts for approximately 27–31% of total changes (for 5Y to 10Y strips); the “real growth correlation” channel — stronger co-movement between real GDP and real dividend growth expectations after 2000 — accounts for approximately 89–95% of total changes. The paper identifies this real bond hedging channel as the dominant and previously unexamined driver.
Dividend Strip Return Predictability. The price-dividend ratio predicts annual market excess returns with R² of 10.3% (data) vs. 9.0% (model). Strip return predictability is downward-sloping by maturity: in data, the R² is 20.2% for 5-year strips and 14.5% for 10-year strips; the model generates 14.2% and 10.4% respectively. This is decomposed into three sources: bond return predictability (small contribution), dividend forecast error predictability (dominant for short maturities), and forecast revision predictability (negative contribution that offsets). The downward slope occurs because current news has smaller impact on long-term dividend expectations.
Aggregate Market Puzzles. The model-implied log dividend-price ratio correlates 0.86 with data, with AR(1) coefficient 0.96 (data: 0.95). Model-implied average market return is 9% (data: 8%); annualized return volatility 12% (data: 16%). The model replicates the switch of the bond-stock aggregate return correlation from +0.13 before 2000 to −0.46 after 2000 (data: +0.39 to −0.64).

Scope Conditions. Results apply to U.S. equity and bond markets over 1987Q4–2019Q4 (with bond learning using data back to 1959Q1). The model assumes a representative agent with CRRA utility and constant subjective risk premium. It is silent on the term structure of expected returns in the statistical sense (which requires identification of latent states under the physical measure). The aggregate market results require a reduced-form specification for stochastic equity duration H_t linked to the value-weighted LTG average.

Q&A

Q1: What is the core psychological mechanism generating subjective beliefs, and how does it differ from the diagnostic expectations approach?

The agent has the “belief in the law of small numbers” (Tversky and Kahneman 1971): she treats small samples as equally representative of their population as large samples. Formally, this is embedded by exaggerating the likelihood in the Bayesian update: p(x_t|I_t) ∝ p(y_t|x_t)^{1+θ} × p(x_t|I_{t-1}), where θ captures the magnitude of cognitive bias. The resulting subjective learning gain ν = (1+θ)P̃ / [(1+θ)P̃ + σ²_ε] can exceed the Kalman gain K when θ is large (overreaction) or fall below it when θ is small (underreaction). This differs from diagnostic expectations (Bordalo et al. 2019, 2020a,b), which are based on the representativeness heuristic; the paper notes the two notions of news are highly correlated in simulation (Table IA.2) and that both can imply overreaction.

Q2: Why does the model generate overreaction to dividend growth news even though the dividend-level learning gains are smaller than the Kalman gains?

The model separates dividend learning into level and growth. Section 2.2 derives that underreaction to dividend level news (νl_d < Kl_d, νs_d < Ks_d, estimated values 0.166 and 0.458 against Kalman gains 0.19 and 0.49 respectively) translates into overreaction to dividend growth news. This is confirmed by the CG(2015) rationality test: regressing forecast errors on lagged forecast revisions yields slope coefficients of −0.69 (1Y) and −0.97 (5Y) for real dividend growth, both statistically significant (t-statistics −3.63 and −3.22). In contrast, the same test yields positive slope coefficients for GDP growth (2.08 at 1Y) and inflation (1.01 at 1Y), confirming underreaction for these series.

Q3: How well does the model match subjective dividend growth expectations in the survey data?

The model-implied 1-year subjective dividend growth forecast is estimated by minimizing RMSE against the consensus dividend growth forecast series (extended from De La O and Myers 2021 to 2019Q4, with a replication correlation of 0.92 over the overlapping sample). The unconditional correlation between model-implied and data 1-year forecasts is 0.80. Although only 1-year forecasts are used in estimation, the model also achieves a correlation of 0.80 for 2-year forecasts, providing an out-of-sample validation.

Q4: What explains the higher volatility of short-term equity yields relative to long-term equity yields?

Short-term subjective dividend growth expectations are more volatile because the agent’s short-run expectation mean-reverts toward the less volatile long-run (levered) GDP growth expectation. In the model’s two-component dividend structure, the transitory dividend-share component xd has persistence ρ_d = 0.94 and its effect on equity yields decays as maturity increases (via the factor (1−ρ^n_d)/n). Similarly, the effect of the transitory GDP growth state x_g decays with maturity. Long-term equity yields are thus anchored by the slower-moving trend components µ_g and µ_d. In the data from Giglio et al. (2021), 1-year yields have a standard deviation of 8.89% annualized vs. 2.70% for 10-year yields; the model generates 8.22% and 1.89% respectively.

Q5: What is the quantitative importance of the “real growth correlation” channel vs. the “inflation real effect” channel in explaining the bond-stock correlation switch?

For the switch in bond-stock return correlation (using the 10-year nominal bond and various maturity dividend strips), the decomposition in Table 4 shows that the “real growth correlation” channel accounts for 89.1% (5Y strip), 92.1% (7Y strip), and 94.8% (10Y strip) of total bond-stock covariance changes, while the “inflation real effect” (correlation between expected inflation and expected real growth) accounts for 27.3%, 29.3%, and 31.1% respectively. The “volatility of shocks to expected inflation and real growth” makes a negative contribution (−16.4%, −21.4%, −25.9%), mostly attributable to more volatile beliefs during the 2008 global financial crisis. The real growth correlation channel reflects that after 2000, real bonds provide a better hedge to aggregate real dividend risks because real GDP growth expectations and real dividend growth expectations became more positively correlated.

Q6: Does the same real growth correlation story hold for the “Fed model” (bond-stock yield correlation)?

Yes, but with a quantitatively different balance. For yield correlations (Table 5), the “real growth correlation” channel accounts for 72.4%–80.1% of bond-stock yield covariance changes (5Y to 10Y strip), while the “inflation real effect” now accounts for 41.2%–43.9%. The inflation real effect is proportionally larger for yield levels because persistent expected inflation correlates strongly with the level of expected real GDP growth — even though inflation expectations do not move fast enough at high frequency to explain return correlation, they co-move strongly with expected growth at low frequency.

Q7: How does the model generate a downward-sloping term structure of return predictability?

The strip excess return is decomposed into three components (Equation 44): maturity-matched bond excess return (Bond), dividend forecast error within the holding period (FE), and forecast revision regarding dividend growth after the holding period (FR). For short maturities, bond predictability contributes little (R² ≈ 6.7% for 5Y strip), while FE predictability (R² ≈ 31.5%) and FR predictability (R² ≈ 35.6%) dominate. As maturity increases, the current news has smaller impact on long-term dividend expectations, reducing the predictability of FE (R² ≈ 26.6% for 10Y) and FR (R² ≈ 26.5% for 10Y). Taken together, total model-implied strip R² declines from 14.2% (5Y) to 10.4% (10Y), matching the data pattern (20.2% to 14.5%). The paper identifies forecast revision predictability as a new channel not previously documented.

Q8: Why do forecast errors and forecast revisions have opposite signs in the predictability regressions?

Bad news (high equity yields, i.e., low current stock prices) triggers excessively pessimistic subjective dividend growth expectations because the agent overreacts to dividend news. These overly pessimistic forecasts tend to be disappointed in the future — actual dividend realizations exceed the forecast — producing positive subsequent forecast errors (FE is positively predicted by high yields, with R² ≈ 31.5% for 5Y strips). However, as dividend levels mean-revert, higher subsequent realizations cause the agent to revise down the forecast for dividend growth thereafter, leading to negative forecast revisions (FR is negatively predicted by high yields, with R² ≈ 35.6% for 5Y strips, opposite sign from FE). The net effect on return predictability is thus a combination of positive (FE) and negative (FR) contributions.

Q9: How does the model handle the aggregate market dividend-price ratio and its persistence?

The aggregate stock price is modeled as the sum of dividend strip prices up to a stochastic horizon H_t, which is parameterized as a linear function of the value-weighted average of LTG forecasts: H_t = a + b·LTG_t. Parameters a and b are estimated by minimizing RMSE between model-implied and data log dividend-price ratio. The model-implied ratio achieves a correlation of 0.86 with data, an AR(1) coefficient of 0.96 (data: 0.95), and an annualized volatility of 26% (data: 30%). The time-variation is driven entirely by strip yield variations and exogenous LTG movements.

Q10: Is the overreaction to dividend news and underreaction to GDP/inflation news consistent in a single framework?

Yes. The model’s subjective learning framework (based on “belief in the law of small numbers”) generates both over- and underreaction depending on the estimated subjective learning gain relative to the Kalman gain. For GDP growth and inflation, the learning gains (ν*_g = 0.012, νgap_g = 0.065; ν*_π = 0.049, νgap_π = 0.228) are below their Kalman gains (0.29 and 0.67 for GDP components; 0.67 and 0.48 for inflation components), producing underreaction. The paper hypothesizes this is related to the Fed’s dual mandate: agents rationally assign lower weight to GDP and inflation shocks expecting the Fed will stabilize them. For dividend growth, a level-to-growth translation converts level underreaction into growth overreaction.

Q11: What are the robustness checks, and what do they show?

The paper checks three alternative equity duration measures: those from Dechow et al. (2004), Weber (2018), and Gonçalves (2021b), as well as the book-to-market ratio following Lettau and Wachter (2007). Table IA.1 shows that replacing LTG with these measures still produces model-implied equity yields that replicate key data moments with high time-series correlations. Changing the cross-sectional breakpoint for long-duration dividends from the median LTG to the 40th or 60th percentile leaves results similar. The paper also presents an Internet Appendix extension in which the agent has ambiguity about real GDP and dividend growth (model misspecification fear), yielding equity yields and returns even closer to data.

Q12: What is the paper’s contribution to the bond market relative to Zhao (2020)?

The bond pricing block closely follows Zhao (2020), inheriting its explanatory power for bond market stylized facts. The model’s 1-year and 10-year nominal bond yields achieve correlations of 0.92 and 0.95 with data, respectively. The new contribution is the joint model covering both equity and bond markets simultaneously, enabling the decomposition of bond-stock covariance and the identification of the real growth correlation as the dominant driver of the bond-stock correlation switch — a channel not addressed by Zhao (2020), which focused on bond market puzzles alone.

Key Concepts

Equity Yield (Dividend Strip Yield). Defined as ey^(n)_t = (1/n)(d$_t − p^(n)_t), where p^(n)_t is the log price of the n-period dividend strip (a claim to the nominal dividend n periods ahead) and d$_t is the log nominal aggregate dividend. It decomposes into the bond yield, a subjective dividend growth component, and a (constant) risk premium component.

Belief in the Law of Small Numbers. A cognitive bias (Tversky and Kahneman 1971) in which the agent perceives small samples to represent their population as well as large samples. Modeled by exaggerating the likelihood in Bayesian updating: p(x_t|I_t) ∝ p(y_t|x_t)^{1+θ} × p(x_t|I_{t-1}). This generates a subjective learning gain ν that can exceed the Kalman gain (overreaction) or fall below it (underreaction) depending on θ and the signal-to-noise ratio.

Subjective Learning Gain. The coefficient ν in the subjective Kalman filter update ẽ_t x_t = ρẽ_{t-1}x_{t-1} + ν(y_t − ρẽ_{t-1}x_{t-1}). It equals (1+θ)P̃ / [(1+θ)P̃ + σ²_ε], where P̃ is the subjective predictive variance. When ν > K (the rational Kalman gain), the agent overreacts to news; when ν < K, the agent underreacts.

Long-Duration Dividend Component. The portion of aggregate real dividend (dl_t) attributable to “long-duration” firms — those with above-median analyst LTG forecasts in CRSP/Compustat/IBES data. Levered on log real GDP with leverage parameter λ = 3, it carries aggregate risk. The complementary short-duration dividend share ds_t is stationary and carries no aggregate risk. The decomposition allows the model to exploit cross-sectional cash-flow duration information when learning about future aggregate dividend growth.

Real Growth Correlation Channel. A bond-stock covariance component defined as Cov(RGDP^(N), RDIV^(n)), where RGDP^(N) is the real GDP growth expectation component of 10-year nominal bond returns and RDIV^(n) is the real dividend growth expectation component of n-period strip returns. This channel captures whether real bonds hedge aggregate real dividend risks. The paper shows this channel accounts for approximately 89–95% of the post-2000 bond-stock covariance change for dividend strips.

Inflation Real Effect. The covariance component Cov(INFL^(N)_B, RGDP^(n) + RDIV^(n)), defined as the correlation between shocks to expected inflation (embedded in nominal bond returns) and shocks to expected real growth (in strip returns). In the paper’s framework this is distinct from the standard inflation risk premium story, as it concerns the correlation between subjective beliefs rather than realized covariances under the physical measure.

Forecast Error (FE) and Forecast Revision (FR) Predictability. Two of three components of realized strip excess return (Equation 44). FE = ∆d${t+1:t+h} − ẽ_t∆d${t+1:t+h} is the realized dividend growth forecast error within the holding period; FR = (ẽ_{t+h} − ẽ_t)∆d$_{t+h+1:t+n} is the forecast revision for dividend growth beyond the holding period. Because the agent overreacts to dividend news, bad news triggers overly pessimistic forecasts (positive subsequent FE) and, as dividends mean-revert, downward forecast revisions (negative FR). These two have opposite signs in predictive regressions, generating the downward-sloping term structure of return predictability.

Fed Model. The empirical positive correlation between equity yields (real) and nominal bond yield levels. The paper shows that this yield-level correlation switched from strongly positive (≈ 0.85 before 2000) to significantly negative (≈ −0.60 to −0.62 after 2000) for 5Y–10Y dividend strips, and that the same real growth correlation and inflation real effect decomposition applies, albeit with the inflation real effect proportionally larger (≈ 40%) for yield levels than for returns (≈ 30%) because persistent inflation expectations co-move with the level of expected real GDP growth.

Hedge funds and the Treasury cash-futures basis trade

Mon, 01 Jan 0001 00:00:00 +0000

The U.S. Treasury market is the deepest and most liquid fixed-income market in the world, yet in March 2020 it experienced unprecedented dysfunction—widening bid-ask spreads, skyrocketing repo rates, and diverging arbitrage spreads that prompted massive Federal Reserve intervention. This paper documents the rise and near-collapse of the Treasury cash-futures basis trade—an arbitrage strategy among hedge funds exploiting a persistent disconnect between cash Treasury prices and futures prices—as a central feature of that episode. Using regulatory datasets on hedge fund exposures and repo transactions, the authors show that at its peak the basis trade accounted for an estimated $400–$500 billion in positions, constituting more than 60% of total hedge fund Treasury exposure, more than 70% of hedge fund repo borrowing, and more than 25% of primary dealers’ repo lending. A model and empirical evidence link the trade’s growth after 2016 to broader Treasury market developments, and show how the trade’s reliance on short-term repo financing creates both margin risk and rollover risk. In March 2020 many of these risks materialized, though the unwinding of basis positions was likely a consequence rather than the primary cause of the stress; prompt Federal Reserve intervention may have prevented a liquidity spiral.

Summary of a forthcoming paper, AI-assisted and human-reviewed. See the linked original for the authoritative claims and full conditions.

In depth

Q1. What is the Treasury cash-futures basis trade and why did it become popular?

The basis trade exploits the arbitrage relationship Pₜ,τ = ΣBₜ,ₛcₛ + Bₜ,T Fₜ,τ,T: when futures prices are too high relative to the present value of the deliverable bond, traders go “long the basis” by buying the cash bond and shorting the futures, financing the long position in the overnight repo market. The trade became popular following 2016 as demand for long Treasury futures positions grew (from institutional investors seeking leveraged duration exposure) while the supply of warehousing capacity from dealers contracted under post-crisis regulatory constraints. Hedge funds stepped in as the marginal warehouser, exploiting the resulting premium embedded in futures prices. The trade is nearly zero net-cash but requires continuous repo rollover.

Q2. How large did the trade become and how was its size estimated?

Using regulatory data—specifically CFTC Form 40 (hedge fund futures positions), SEC Form PF (AUM and derivatives exposures), and FR 2004 (primary dealer repo data)—the authors estimate basis trade positions peaked at $400–$500 billion, comprising more than 60% of hedge fund Treasury exposure, more than 70% of hedge fund repo borrowing, and more than 25% of primary dealer repo lending to hedge funds. The data allow the authors to identify basis positions directly, distinguishing them from outright long Treasury positions, by matching the simultaneous long cash / short futures pattern that defines the trade. The estimates underscore that hedge funds had become systemically important participants in Treasury market intermediation.

Q3. What financial stability risks does the basis trade create?

The basis trade creates two interrelated risks: margin risk (variation margin calls on futures positions can force immediate liquidation) and rollover risk (if repo lenders withdraw funding, the cash Treasury position must be sold). The paper’s model formalizes how limits to arbitrage—specifically repo market illiquidity and margin requirements—impair risk-sharing between dealers and holders of long futures positions. These constraints mean that even a moderate adverse price move can trigger a self-reinforcing cycle: higher basis volatility → margin calls → forced sales → further basis widening → further margin calls.

Q4. What happened in March 2020 and what was the Federal Reserve’s role?

Beginning in early March 2020, the COVID-19 pandemic triggered a “dash for cash” that disrupted Treasury market functioning: bid-ask spreads widened dramatically, repo rates spiked, and the cash-futures basis moved sharply against basis traders, generating large margin calls. The authors find that while Treasury market disruptions spurred hedge funds to sell Treasuries, the unwinding of the basis trade was likely a consequence rather than a primary cause of the stress. The Federal Reserve intervened by dramatically expanding Treasury purchases from dealers and offering unlimited repo and reverse repo facilities, which likely prevented a liquidity spiral by removing the constraint on dealer intermediation capacity. The paper argues this episode highlights structural vulnerabilities in Treasury market intermediation arising from the shift of warehousing capacity to hedge funds.

Key concepts

Treasury cash-futures basis trade : an arbitrage strategy in which a trader simultaneously holds a long position in cash Treasury bonds (funded via repo) and a short position in Treasury futures, profiting from the convergence of cash and futures prices at delivery.

warehousing role of hedge funds : the function of holding Treasury bonds on behalf of institutional investors who want long futures exposure, financed in the repo market; this creates a link between Treasury, futures, and repo markets and exposes the system to repo rollover and margin risk.

rollover risk : the risk that short-term repo lenders decline to roll over funding at maturity, forcing the borrower to sell the collateral asset (Treasury bonds) at potentially distressed prices.

Stock market participation and macro-financial trends

Mon, 01 Jan 0001 00:00:00 +0000

This paper documents a puzzle for canonical limited-participation models: when U.S. stock market participation rose from 31.6% to 53% between 1989 and 2007—a period also characterized by the Great Moderation—the equity premium and stock return volatility increased rather than fell as those models would predict. The paper resolves this puzzle using an RBC model with concentrated capital ownership in which capitalists have external habit utility with a habit stock that depends on aggregate per capita consumption. As participation rises, the representative capitalist’s consumption converges to aggregate consumption, shrinking the surplus-consumption ratio and raising endogenous average risk-aversion; this risk-aversion channel dominates the conventional risk-sharing channel (which predicts a lower equity premium under higher participation). The model implies that higher participation generates a sizeable rise in both the equity premium and stock return volatility while reducing the risk-free rate and aggregate consumption volatility—jointly explaining the observed U.S. macro-financial patterns. Household-level data from the Consumption Expenditure Survey (1984–2017) and cross-state variation support the model’s mechanism.

Summary based on a working paper version, AI-assisted and human-reviewed. See the linked published article for the authoritative version.

In depth

Q1. What is the puzzle the paper addresses?

Existing limited-participation models predict that higher stock market participation should reduce the equity premium (by improving risk-sharing), yet the U.S. experienced a rising equity premium and higher stock return volatility precisely during the period of sharp participation growth (1989–2007), at the same time as the Great Moderation. The standard channel predicts that as more households access financial markets, the representative capitalist’s risk burden falls and the covariance between capitalists’ consumption and equity returns declines, lowering the equity premium. The data contradict this prediction, motivating the paper’s novel mechanism.

Q2. What is the novel risk-aversion channel?

As stock market participation rises, the representative capitalist’s consumption converges toward aggregate per capita consumption, shrinking the surplus-consumption ratio and thereby raising the endogenous effective risk-aversion of the economy—this risk-aversion channel dominates the conventional risk-sharing channel. The key assumption is that capitalists’ habit stock depends on aggregate per capita consumption. The surplus-consumption ratio (the gap between the capitalist’s consumption and the habit level) determines risk-aversion in the external habit utility framework. As participation rises, the capitalist’s consumption approaches the habit level, increasing risk-aversion and the equity premium, even as aggregate consumption volatility falls.

Q3. What are the model’s predictions for macro-financial variables?

In the model economy, an increase in stock market participation generates a sizeable rise in both the equity premium and the volatility of stock returns, a moderate increase in the price-dividend ratio, and a fall in the average risk-free rate and aggregate consumption volatility—jointly accounting for the U.S. macro-financial experience since the 1980s. The rise in equity premium and stock volatility produced by higher participation substantially counteracts the shrinking effect due to lower aggregate uncertainty from the Great Moderation, providing a unified explanation for the co-movement of these macro-financial trends.

Q4. What is the empirical evidence supporting the mechanism?

Household-level data from the U.S. Consumption Expenditure Survey (1984–2017) show that the model-implied average risk-aversion for the representative stockholder trended upward over time closely tracking the rate of participation, while the stockholder-to-aggregate consumption ratio trended downward; cross-state data document a negative relationship between participation and the stockholder-to-aggregate consumption ratio. Both the time-series and cross-sectional patterns are consistent with the model’s prediction that higher participation compresses the gap between stockholder and aggregate consumption, the key driver of the risk-aversion channel.

Key concepts

participation puzzle : the empirical regularity that only a fraction of the population participates in the stock market; exploited in asset pricing models to explain the equity premium with plausible average risk-aversion; this paper studies the consequences of the upward trend in participation since the 1980s. surplus-consumption ratio : the gap between the capitalist’s consumption and their habit level, normalized by consumption; the key state variable in external habit utility models; determines endogenous risk-aversion so that a shrinking surplus-consumption ratio raises risk-aversion. risk-aversion channel : the novel mechanism introduced in this paper: as stock market participation rises, the capitalist’s consumption converges to aggregate consumption, shrinking the surplus-consumption ratio and raising endogenous risk-aversion and thus the equity premium; dominates the conventional risk-sharing channel in the model. risk-sharing channel : the conventional channel in limited-participation models: higher participation improves risk-sharing, reducing the covariance between stockholder consumption and equity returns and tending to depress the equity premium; present in the model but dominated by the risk-aversion channel.

Unconventional monetary policy spillovers and the (in)convenience of Treasuries

Mon, 01 Jan 0001 00:00:00 +0000

Layer 1 — Overview

Research Question

The paper asks why unconventional monetary policy (UMP) spillovers from the European Central Bank (ECB) to the U.S. Treasury yield curve vary so substantially over time, and whether the time-varying “convenience” of Treasuries — their non-pecuniary premium as the world’s preeminent safe asset — can explain that variation. The core claim is that a declining convenience yield on Treasuries makes them more substitutable with other safe sovereign bonds, thereby amplifying the portfolio-balance channel through which foreign large-scale asset purchases (LSAPs) depress U.S. term premia.

Data and Methodology

The authors use high-frequency identification of ECB monetary policy surprises following Altavilla et al. (2019), defined as the first principal component of intraday changes in 1-, 3-, 6-, 12-, and 24-month euro OIS rates plus 5- and 10-year German and French bond yields, measured in the 10-20 minute window bracketing each ECB decision press conference. Surprises are normalized so that one unit raises the 24-month euro OIS by 10 basis points. The sample runs from March 2001 to December 2023, covering approximately 265-268 ECB announcement dates. U.S. zero-coupon Treasury yields come from Gürkaynak et al. (2007); the yield is decomposed into an expected short-rate path and a term premium using the shadow-rate term structure model (SRTSM) of Wu and Xia (2016). The convenience yield on Treasuries is proxied by the spread between the 10-year Treasury yield and the maturity-matched overnight index swap (OIS) rate, so that a positive (and rising) spread indicates declining convenience. Structural breaks in the convenience yield are identified via the Bai-Perron test.

The empirical strategy has three main components: (i) 700-business-day rolling regressions of Treasury yields and their decomposition on ECB surprises to document time variation; (ii) interaction regressions (following equation 5/9) that condition the ECB shock effect on lagged convenience-yield proxies, net Treasury supply, intermediary balance-sheet constraints (proxied by G10 covered-interest-parity deviations), and inflation-anchoring indicators; and (iii) a policy decomposition following Swanson (2021) that decomposes ECB surprises into “target,” “forward guidance,” and “LSAP” components. These empirical findings are rationalized in a two-country preferred-habitat model, extending Gourinchas, Ray, and Vayanos (in press) (GRV) by allowing the demand-slope parameter governing investor price elasticity to vary with the convenience yield. Functional derivatives and Malliavin calculus are used to characterize dynamic impulse responses to elasticity shifts.

Main Findings with Quantitative Magnitudes

Rising spillovers post-GFC, concentrated at long maturities. Rolling regressions show that ECB-to-U.S. spillovers were statistically indistinguishable from zero during the conventional-policy era but grew significantly after 2010, well before the ECB’s Expanded Asset Purchase Programme (EAPP) launched in 2015 and before “whatever it takes” (summer 2012). Spillovers began to dissipate not when ECB purchases ended (March 2022) but when the Fed announced tapering in November 2021 — consistent with the convenience channel rather than mere co-movement in LSAP volumes. A Bai-Perron test detects five structural breaks in the relationship between ECB surprises and 10-year Treasury yields.
Term-premium dominance, amplified by inconvenient Treasuries. At average convenience-yield levels, a one-standard-deviation ECB loosening shock (lowering the 24-month euro OIS by 10 basis points) reduces the 10-year Treasury yield by approximately 4.4 basis points (column 5, Table 2). When the Treasury convenience yield is one standard deviation below its historical average (i.e., Treasuries are less convenient), the spillover increases by 1.64 basis points, making the total effect approximately 6.1 basis points — a shift from the bottom 20th to below the 12th percentile of the unconditional distribution of daily Treasury yield changes. This amplification operates entirely through the term premium; the expected path of short rates shows no statistically significant sensitivity to the convenience yield interacted with ECB shocks.
Net Treasury supply amplification. Conditional on the net publicly available U.S. debt stock (Treasury debt less Fed holdings, as a percent of GDP), a one-standard-deviation ECB shock at average supply reduces the 10-year yield by approximately 3.9 basis points; when net supply is one standard deviation above its historical average (approximately 7.6 percentage points of GDP), the same shock generates a 5.35 basis-point decline — a 50-percent amplification (Table 5, column 5).
Intermediary constraints amplification. Conditioning on the first principal component of G10 CIP deviations against the dollar (a proxy for intermediary balance-sheet tightness), a CIP deviation one standard deviation above average amplifies the ECB spillover from approximately 3.9 basis points to 6.2 basis points (Table 7).
Inflation anchoring. Periods when inflation expectations lie outside the interquartile range of the historical distribution are associated with larger spillovers to 10-year Treasury yields, an effect that is statistically significant both above the 75th and below the 25th percentile of expectations, with point estimates of the interaction coefficient reaching approximately 5.0-5.3 basis points (Table 6).
Policy asynchronicity. Spillovers are especially pronounced when the Federal Reserve is tightening while the ECB is easing. The rolling regressions show term-premium spillovers become dominant (relative to expected-path spillovers) post-2014, coinciding with U.S. normalization. The calibrated model shows that, during policy asynchronicity combined with lower convenience, the home short-rate tightening is partially offset by capital inflows induced by foreign QE, with the attenuation especially pronounced at intermediate and long maturities and persistent across multiple periods.
Alternative channels ruled out. Horse-race regressions against the VIX, MOVE index, Economic Policy Uncertainty (EPU) index, Monetary Policy Uncertainty (MPU) index, and 30-day EUR/USD spot variance show none of these candidates displaces the convenience channel. Short-rate-risk decompositions (Bundick et al. 2017) and equity-orthogonal risk premium shocks (Leombroni et al. 2021) cannot explain the post-Taper Tantrum timing pattern of rising term-premium spillovers.

Scope Conditions

All empirical results apply to ECB-to-U.S. spillovers; the paper explicitly leaves Bank of England-to-U.K. Gilt spillovers for future work.
The portfolio-balance amplification through convenience is specific to unconventional monetary policy (LSAP shocks); target and forward-guidance components drive spillovers through different channels (expected short-rate path) and do not exhibit the same convenience-contingent amplification.
The mechanism operates through preferred-habitat investors demanding sovereign-grade credit; the Bund convenience yield does not amplify U.S. spillovers, consistent with Bunds being an imperfect representation of the full portfolio requiring substitution under ECB capital-key-based purchases.

Layer 2 — Q&A

Q1: How do the authors measure ECB monetary policy surprises, and why do they prefer this measure?

A1: Surprises are the first principal component of intraday changes in 1-, 3-, 6-, 12-, and 24-month euro OIS rates plus 5- and 10-year German and French bond yields, measured from 10-20 minutes pre-announcement to 10-20 minutes post-press conference. This cross-section of yields is preferred because it summarizes shocks to the overall stance of policy both at and away from the effective lower bound, including effects on different parts of the yield curve. The composite measure therefore subsumes both conventional rate actions and unconventional (LSAP, forward guidance) dimensions. Surprises are normalized so one unit raises the 24-month euro OIS by 10 basis points.

Q2: What is the key empirical fact about the timing of spillover emergence and dissipation?

A2: Rolling regressions show ECB spillovers to U.S. Treasury yields became statistically significant when the rolling window began integrating observations starting in approximately 2010 — substantially before the ECB’s EAPP (2015) and even before “whatever it takes” (summer 2012). Moreover, spillovers began to dissipate not when the ECB’s Pandemic Emergency Purchase Programme ended (March 2022) but when the Fed announced tapering in November 2021. This timing pattern is inconsistent with a simple “both central banks doing QE simultaneously” explanation and instead points to the importance of Federal Reserve balance sheet behavior for the convenience of Treasuries.

Q3: How do the authors decompose the Treasury yield, and what does the decomposition reveal about the channel of transmission?

A3: Following standard term-structure decomposition, the n-year yield equals the expected path of short-term rates over the maturity plus a maturity-specific term premium. Rolling regressions on this decomposition show that term-premium spillovers dominate expected-path spillovers, especially post-2014 when the Federal Reserve is out of sync with other advanced economies. Early ECB UMP spillovers showed a more even mix of expected-path and term-premium effects; later spillovers loaded much more heavily on the term premium. This is consistent with the portfolio balance channel — LSAPs remove duration risk and compress term premia, and this effect transmits internationally.

Q4: How is the convenience yield proxied, and why does the paper use this proxy in particular?

A4: The authors use the spread between the sovereign bond yield and the maturity-matched overnight index swap rate (Y − OIS), expressed so that a larger spread (sovereign yield higher than OIS) reflects less convenience. Prior to the GFC, Treasury yields ran below swap rates (negative spread, high convenience); post-GFC, the spread reversed and turned positive, reflecting deterioration in Treasury specialness. This proxy is preferred because it captures the relative convenience as priced by the marginal investors the model focuses on — those with sovereign credit quality preferences and arbitrageurs — rather than broader measures such as the Treasury-to-corporate spread.

Q5: What is the quantitative impact of convenience yield variation on the size of ECB spillovers to U.S. yields?

A5: In the most conservative specification (Table 2, column 5), an ECB loosening shock that lowers 24-month euro OIS by 10 basis points reduces the 10-year Treasury yield by 4.4 basis points when the convenience yield is at its historical average. When the convenience yield falls one standard deviation below average (Treasuries are less convenient), the spillover increases by 1.64 basis points to approximately 6.1 basis points. A one-standard-deviation change in 10-year Treasury yields in the sample is 5.86 basis points; the 4.4 bp response falls in the bottom 20th percentile of unconditional daily yield changes, while the 6.1 bp response falls below the 12th percentile.

Q6: Does the amplification of spillovers from ECB shocks by Treasury inconvenience operate through the term premium or the expected short-rate path?

A6: The amplification operates entirely through the term premium. In Table 2, columns 7 and 8, the interaction coefficient between the ECB shock and the convenience yield proxy is positive and statistically significant for the 10-year term premium but is not statistically different from zero for the expected path of short rates. The authors interpret this as confirming the portfolio balance channel: displaced Bund investors substitute into Treasuries, raising Treasury prices and compressing term premia, with no mechanical connection to market participants’ updating of expected future Federal Reserve policy rates.

Q7: How does net Treasury supply interact with the size of ECB spillovers?

A7: Net U.S. Treasury supply (debt outstanding as a percent of GDP, less Fed holdings) is strongly positively correlated with the swap spread, confirming the link between supply and convenience. Interaction regressions (Table 5) show that a one-standard-deviation ECB shock at average net supply reduces 10-year yields by 3.9 basis points. When net supply is one standard deviation above average (approximately 7.6 percentage points of GDP), the same shock generates a 5.35 basis-point decline — roughly a 50 percent amplification. The point estimates suggest this operates primarily through term premia, though those interaction coefficients are statistically insignificant in the term premium specification.

Q8: How do intermediary balance-sheet constraints relate to Treasury convenience and ECB spillover amplification?

A8: The authors follow Du, Hébert, and Huber (2023) in using deviations from covered interest parity (CIP) among G10 currencies against the dollar as a proxy for the shadow cost of intermediary balance-sheet constraints. When CIP deviations are at historical average, the ECB spillover to 10-year Treasury yields is approximately 3.9 basis points; when CIP deviations are one standard deviation above average, the spillover rises to approximately 6.2 basis points. The authors also use the plausibly exogenous variation from quarter-end “window dressing” (per Correa, Du, and Liao 2020): LSAP-type ECB surprises landing near quarter-end generate larger spillovers to the term premium, and the further into the quarter an announcement occurs, the larger the LSAP shock’s effect on the term premium — consistent with balance-sheet constraints amplifying the portfolio balance channel.

Q9: What is the theoretical model, and what is the key innovation relative to the baseline GRV framework?

A9: The paper extends the two-country preferred-habitat model of Gourinchas, Ray, and Vayanos (in press), in which segmented investors demand bonds of specific maturities and currencies while capital-constrained global arbitrageurs partially bridge the segmentation. The key innovation is allowing the demand-slope parameter α_j(τ) — which in GRV is fixed and governs how inelastic investors are with respect to price — to vary over time as a function of the convenience yield. When Treasuries are special (high convenience), α_H(τ) is large, demand is inelastic, and foreign shocks have limited pass-through. When convenience falls, α_H(τ) shrinks, demand becomes more elastic, investors reallocate more aggressively in response to yield differentials, and U.S. term premia respond more strongly to ECB purchases. Functional derivatives and Malliavin calculus are used to characterize both instantaneous and dynamic amplification effects.

Q10: What does the calibrated model predict about the maturity structure of spillover amplification?

A10: In the calibration exercise (Figure 4), the elasticity perturbation is modeled as a smooth function (transformed Cauchy distribution) centered at the 10-year maturity, and the ECB QE shock is a purchase concentrated at the 5-year maturity amounting to 10 percent of euro-area GDP. The marginal change in the home yield impulse response (the quantity ∂²_{α_H,b} log P^τ_{Hs}) is positive across nearly all maturities and horizons, but is most pronounced around the 5-year maturity and during the first few periods after the shock — where the ECB purchase profile and the demand perturbation are most closely aligned in tenor. Amplification effects are persistent across horizons due to the dynamic multiplier in Theorem 3.1.

Q11: How does the model rationalize the 2019 yield curve inversion?

A11: In August 2019, the 10-year Treasury yield fell below short-term rates despite a robust domestic labor market, while the Fed was raising rates and the ECB remained accommodative. The model’s asynchronicity exercise (Section 3.3) shows that combining a home short-rate increase with ongoing foreign QE and a contemporaneous decline in Treasury convenience produces attenuated or even reversed yield curve responses. More elastic investors facing a flatter demand curve shift into longer-term Treasuries — whose relative yields remain attractive globally — resulting in a yield-curve inversion driven not by recession expectations but by asymmetric monetary policy and a time-varying convenience premium.

Q12: Do alternative explanations — risk sentiment, policy uncertainty, exchange rate volatility — explain the time variation in ECB spillovers?

A12: No. Horse-race regressions in Table 9 condition the ECB shock on lagged VIX, MOVE index, Economic Policy Uncertainty (Baker et al. 2016), Monetary Policy Uncertainty (Husted et al. 2020), and 30-day EUR/USD spot variance. None of these measures displaces the baseline convenience-yield interaction, which remains statistically significant across all specifications. Elevated EPU is associated with smaller spillovers (consistent with uncertainty impairing substitution), but this does not reduce the magnitude or significance of the convenience-yield interaction. Exchange-rate variance does not alter spillover size. A rolling regression decomposing the term premium into a short-rate-uncertainty component (Bundick et al. 2017) and a residual shows the empirical pattern is more consistent with the residual — not the short-rate-volatility channel. An equity-orthogonal risk premium shock (Leombroni et al. 2021) explains some term premium effects in the early GFC period (2008-2012) but cannot rationalize the post-Taper Tantrum pattern of growing term-premium spillovers.

Q13: How does the Swanson (2021) decomposition confirm the portfolio balance channel?

A13: Following Swanson (2021), the authors decompose ECB surprises into a “target surprise” (change in 3-month OIS futures), a “forward guidance surprise” (residual from projecting 24-month futures onto the target surprise), and an “LSAP surprise” (residual from projecting French and German 10-year bond yields onto target and forward guidance). In the full sample (Table 3), LSAP shocks drive spillovers to U.S. yields exclusively at higher maturities and exclusively through the term premium; they have no statistically significant impact on the expected path of short rates. Conditioning LSAP shocks on the convenience yield (Table 4, panel c) shows that it is specifically LSAP-type announcements combined with Treasury inconvenience that generate larger medium- and long-term term-premium spillovers, confirming the portfolio balance mechanism.

Q14: What are the implications for fiscal and monetary policy?

A14: The paper argues that the persistently low long-term rates and yield curve inversions observed between the GFC and the COVID-19 pandemic were driven partly by ECB LSAPs amplified by U.S. quantitative tightening, which increased net Treasury supply, reduced Fed absorption, constrained dealer balance sheets, and lowered Treasury convenience. Simultaneously, U.S. monetary tightening raised short-term rates while ongoing ECB easing depressed long rates, reshaping the yield curve in a manner consistent with the model. More broadly, the effectiveness of conventional domestic monetary policy tightening is attenuated when the convenience yield is compressed and foreign QE is ongoing — not because the short rate fails to move, but because more elastic investors reallocate around it. This suggests policy asynchronicity, combined with declining convenience, creates a constraint on monetary independence that may require more forceful or coordinated policy action.

Key Concepts

Convenience yield (Treasury convenience premium) The non-pecuniary value that investors derive from holding U.S. Treasury securities over and above cash flows and credit risk — arising from their deep and liquid markets, broad regulatory compatibility, high-quality collateral function, and reserve-currency status. Operationalized in this paper as the spread between the n-year Treasury yield and the maturity-matched overnight index swap (OIS) rate; a positive and rising spread indicates declining convenience, not increasing yield risk.

Portfolio balance channel (of unconventional monetary policy transmission) The mechanism by which large-scale asset purchases by one central bank displace investors from their target allocations, inducing them to substitute into other assets — including foreign sovereign bonds — thereby compressing yields and term premia in those markets. Distinguished from the signaling/expected-path channel in that it operates through changes in duration risk (term premia) rather than revisions to expected future short rates, and is unique to UMP because it targets long-duration assets.

Preferred habitat investors Investors with persistent, institutionally determined demand for bonds of specific maturities and issuers (e.g., insurance companies, pension funds), arising from regulatory constraints, risk management practices, or balance sheet matching. Their demand is modeled as relatively price-inelastic when assets command a convenience premium, and more elastic when that premium erodes.

Demand-slope parameter α_j(τ) In the extended GRV preferred-habitat model, the parameter governing the price elasticity of preferred-habitat investor demand for country-j bonds of maturity τ. Large values imply inelastic demand (strong habitat preferences), small values imply elastic demand and greater cross-border substitutability. The paper’s key innovation is treating this parameter as time-varying — specifically, as a function of the observed Treasury convenience yield rather than a fixed structural constant.

Policy asynchronicity The condition in which the Federal Reserve is tightening monetary policy (raising rates or conducting quantitative tightening) while other advanced-economy central banks (specifically the ECB) are simultaneously easing through LSAPs. The paper argues that asynchronicity interacts with a declining convenience yield to amplify ECB spillovers to U.S. term premia and attenuate the effectiveness of Federal Reserve tightening at the long end of the yield curve.

Swap spread (as inconvenience proxy) The spread of the sovereign bond yield over the maturity-matched OIS rate (Y − OIS). Expressed so that a larger positive value indicates greater Treasury inconvenience. Prior to the GFC, 10-year Treasury yields ran below swap rates (negative spread); post-GFC, this relationship reversed, with the spread turning persistently positive and exhibiting structural breaks consistent with Bai-Perron tests.

Exorbitant privilege The benefit the United States accrues from the global dominance of its sovereign debt and currency, which structurally insulates U.S. financial markets from foreign monetary policy shocks through inelastic global demand for Treasuries. The paper argues this insulation is not structural but endogenous and state-dependent: erosion of exorbitant privilege — operationalized as a declining convenience yield — substantially increases U.S. vulnerability to foreign monetary shocks.

Gâteaux/Malliavin functional derivative (as used in the model) Mathematical tools used to characterize how the impulse response function of the yield curve to policy shocks changes when the demand-slope parameter α_k(τ) is perturbed. The mixed Gâteaux differential ∂²_{α_k,b} log P^(τ)_{js} captures both the instantaneous amplification (direct pass-through increase) and the intertemporal propagation (dynamic multiplier) of a foreign policy shock under lower convenience, enabling a tractable decomposition of state-contingent spillover magnitudes across maturities and horizons.