Aggregate Bank Capital and Credit Dynamics N. Klimenko S. Pfeil J.-C. Rochet G. De Nicolò (Zürich) (Bonn) (Zürich, SFI and TSE) (IMF and CESifo) MFM Winter 2016 Meeting The views expressed in this paper are those of the authors and do not necessarily represent those of the IMF or IMF policy. 1/28
MOTIVATION Financial regulators and central banks now control powerful macro-prudential tools for promoting systemic stability. Long-term impact on growth and financial stability? DSGE models cannot really help: they were designed to reproduce short-term reactions of prices and output to monetary policy decisions. To study the long-term impact of macro-prudential policies on growth and financial stability, one needs a different type of model. We provide an example of such a model. 2/28
OUR CONTRIBUTION General equilibrium dynamic model with financial frictions, in the spirit of Brunnermeier-Sannikov (2014) and He-Krishnamurthy (2013). Banks are explicitly modeled. Bank capital serves as a loss-absorbing buffer and determines the volume of lending. Model allows the analysis of the long-run effects of minimum capital requirements on lending and systemic stability. Main implications are in line with empirical evidence. 3/28
RELATED LITERATURE 1. Macro-finance in continuous time Brunnermeier-Sannikov (2014, 2015), He-Krishnamurthy (2012, 2013), Di Tella (2015), Phelan (2015). 2. Welfare impact of capital requirements Van den Heuvel (2008) Martinez-Miera and Suarez (2014) DeNicolò-Gamba-Lucchetta (2014) Nguyen (2014) Begenau (2015) 4/28
ROADMAP 1. Model 2. Competitive equilibrium 3. Long run dynamics 4. Credit market failure 5. Application to macro prudential policy analysis 5/28
MODEL General equilibrium model: real sector and banking sector. One physical good, can be consumed or invested. Households invest their savings in bank deposits and bank equity. Banks invest in (risky) loans to entrepreneurs and reserves (can be <0). Equity acts as a buffer to guarantee safety of deposits (no deposit insurance) and interbank borrowings. Entrepreneurs have no capital and must borrow from banks, who monitor them: no direct finance. 6/28
GLOBAL PICTURE Central bank Firms Loans Reserves Banks Liabilities (deposits, interbank loans, Interests on deposits Repayments Loans K t CB loans) Households Profits Equity E t Dividends Entrepreneurs 7/28
MODEL Households and entrepreneurs are risk neutral and discount future consumption at rate ρ. Interbank rate r is fixed and less than ρ. Households receive interest r D on deposits. At equilibrium r D = r. Households derive utility from holding riskless deposits (transactional demand for safe assets as in Stein (2012)). Supply of deposits is fixed and is a decreasing function of (ρ r). For simplicity, r 0 (all qualitative results hold when r > 0). 8/28
MODEL Firms: can borrow 1 unit of productive capital from banks at time t, must repay 1 + R th at t + h if borrow, produce xh unit of good, where x is distributed over [0, R] with density f (x) borrow when x > R t; aggregate demand for loans is a decreasing function of loan rate R L(R) = R R f (x)dx productive capital is destroyed (default) with probability pdt + σ 0 dz t, where {Z t, t 0} is a standard Brownian motion (aggregate shocks) 9/28
MODEL Aggregate shocks in the real sector translate into banks profits/losses Book equity of an individual bank evolves: de t = k t[(r t p)dt σ 0 dz t] }{{} return on a bank s loans dδ t }{{} dividends where k t is the volume of lending to firms at time t Aggregate bank equity evolves: de t = K t[(r t p)dt σ 0 dz t] }{{} return on total loans where K t is aggregate lending d t }{{} dividends + di }{{} t, recapitalizations + di }{{} t, recapitalizations Main friction: issuing new equity entails proportional cost γ Markovian competitive equilibrium: R t = R(E t) and K(E t) = L(R(E t)) 10/28
AN INDIVIDUAL BANK S PROBLEM An individual bank chooses lending, dividend and recapitalization policies to maximize shareholder value: v(e t, E t) = max k s,dδ s,di s [ + E t ] e ρ(s t) (dδ s (1 + γ)di s) Shareholder value is linear in e: v(e, E) eu(e), where u(e) is the Market-to-Book ratio. Only aggregate capital E matters for banks policies. 11/28
DIVIDEND AND RECAPITALIZATION POLICIES Dividend/recapitalization policies of a barrier type: banks distribute dividends when E t = E max, such that u(e max) = 1; banks recapitalize when E t = E min = 0 E max E t Dividends E min=0 Recapitalizations 12/28
EQUILIBRIUM LOAN RATE Positive loan spread: [ R(E) p = σ0k(e) 2 u (E) ], u(e) }{{} where u (E) < 0 lending premium Source of lending premium: implied risk-aversion of bankers with respect to variations in aggregate capital u(.) is a discounted martingale: ρu(e) = L(R)(R(E) p)u (E) + σ2 0L 2 (R) u (E) 2 From these two equations we deduce R 1 (E) = H[R(E)], where H(R) = σ2 0[L(R) (R p)l (R)] 2ρσ0 2 + (R p)2 13/28
EQUILIBRIUM LOAN RATE AND MTB RATIO R( E) Loan rate u( E) 1+ γ MTB ratio of bank equity R max p 1 E min = 0 E max E E min = 0 E max E E = = Emax min E 0 14/28
COMPETITIVE EQUILIBRIUM (CE) Aggregate bank capital evolves according to: ] de t = L(R(E t)) [(R(E t) p)dt σ 0 dz t The loan rate function R(E) : [0, E max] [p, R max] is implicitly given by E = Rmax R(E) H(s)ds, where H(s) = σ2 0[L(s) (s p)l (s)] 2ρσ0 2 + (s p)2 R max and E max increase with financing friction γ Testable predictions: equilibrium loan rate and market-to-book ratio are decreasing functions of aggregate capital 15/28
LOAN RATE DYNAMICS Loan rate R t = R(E t) has explicit dynamics dr t = µ(r t)dt + σ(r t)dz t, p R t R max, with σ(r) = 2ρσ2 0 + (R p) 2 ( σ 0 where h(.) is explicit. 1 (R p) L (R) L(R) ) and µ(r) = σ(r)h(r), 16/28
NUMERICAL EXAMPLE Particular specification of the demand for loans (max. lending 1): ( R R ) β L(R) = where β > 0, R > p R p Μ R Loan rate drift Σ R Loan rate volatility (stable DSS) 0.005 0.020 0.025 0.030 0.035 0.040 0.045 0.050 0.004 0.0001 0.003 0.0002 0.002 0.0003 Deterministic steady-states 0.001 0.0004 R Remark: µ(r) is very small compared to σ(r). Linearization around the (stable) DSS can be very misleading! 17/28
LONG RUN BEHAVIOR OF THE ECONOMY Full description of long run behavior of the economy: stochastic steady state. We can compute the ergodic density function of R (or E): g (R) g(r) = 2µ(R) σ 2 (R) 2σ (R), on [p, Rmax] σ(r) σ(r) Endogenous volatility, σ(r) g(r) Ergodic density of R R 120 0.008 100 0.006 80 γ small 0.004 60 40 0.002 20 γ large 0.02 0.03 0.04 0.05 0.06 R Rmin p Rmax 0.02 0.03 0.04 0.05 0.06 R Remark: the long run behavior of the economy is driven by the endogenous volatility. 18/28
CE IS NOT CONSTRAINED EFFICIENT Banks do not internalize the impact of their lending decisions on the dynamics of E (i.e., endogenous volatility and expected profits). Compared to Second Best (SB), banks lend too much (overexposed to aggregate risk) when E is low and too little when E is high. K(E) 1.00 0.95 0.90 0.85 Implied R/A 6 5 4 3 0.80 2 0.75 1 SB E max 0.02 0.04 0.06 0.08 Emax E 0. SB CE 19/28
APPLICATION: MINIMUM CAPITAL RATIO What happens if banks are subject to a minimal Capital Ratio (CR) Λ? e t Λk t Maximization problem of an individual bank: v Λ(e, E) = max k t e Λ,dδ t,di t [ + ] E e ρt (dδ t (1 + γ)di t) 0 Homogeneity property is preserved: v Λ(e, E) eu Λ(E) We find that CR constraint binds for low E and is slack for high E. u Λ(.) and equilibrium loan rate R Λ(.) have different expressions in constrained (E < E Λ c ) and unconstrained (E E Λ c ) regions. 20/28
CAPITAL RATIO AND BANK POLICIES E R 0.8 0.6 0.4 0.2 Emax 0.07 0.06 0.05 0.04 0.03 Λ,% 20 40 60 80 100 Λ Λ Λ E min E c E max 0.02 20 Banks increase their target level of capital (E Λ max > E max) and recapitalize earlier (E Λ min > 0). Small and moderate Λ: both the unconstrained and constrained regimes co-exist. Very high Λ: the unconstrained region disappears (no extra capital cushions). 21/28
CAPITAL RATIO AND LENDING K(E) μ(e) 1.0 0.030 0.9 Λ = 5 % 0.025 0.020 0.8 0.7 Λ = 30 % Λ = 65 % 0.015 0.010 0.005 Λ = 5 % Λ = 30 0.00 0.05 0.10 0.15 0.20 SB CE E - Emin 0.05 Banks reduce lending not only in the constrained region, but also in the unconstrained one. Moderate capital requirements can bring lending closer to the SB level in the states with low capitalization. Very high capital requirements induce a severe reduction in lending in all states. 22/28
CAPITAL RATIO AND FINANCIAL (IN)STABILITY Capital requirements affect the probabilistic behavior of the system. Under low capital requirements, the ergodic density of E is concentrated in low capitalized states. g(e) 10 Tγ(E) 16 8 6 4 2 Λ = 5 % Λ = 30 % Λ = 65 % 14 12 10 8 6 0.05 0.10 0.15 0.20 E - Emin 5 SB CE 23/28
CAPITAL RATIO AND FINANCIAL (IN)STABILITY Stability measure: T γ(e) - the average time to recapitalization starting from the average level of aggregate capital E. For low Λ, the system becomes even less stable than in the absence of regulation. For very high Λ, the system is more stable than in the Second Best. Tγ(E) 16 14 12 10 8 6 0.20 E - Emin 5 10 15 20 25 30 Λ,% CE SB 24/28
CONCLUSION Tractable dynamic macro model where aggregate bank capital drives credit volume. Asymptotic behavior described by ergodic distribution (stochastic steady state). Model shows that pecuniary externalities in credit markets can arise even in the absence of fire-sales. Model permits simple analysis of macro-prudential policy. Further investigations: interaction between macro-prudential and monetary policies market financing complementary to bank financing 25/28
Thank you! 26/28
EMPIRICAL EVIDENCE: DATA DESCRIPTION Panel of publicly traded banks in 43 advanced and emerging market economies (1992-2012): U.S. banks: 728 banks Japan: 128 banks Banks in advanced economies: 248 banks Banks in emerging market economies: 183 banks Identifier Variable Measurement ret bank gross return on assets total interest income/earning assets mtb market to book equity ratio market equity/book equity logta Bank size Log Assets loanasset % of loans to assets Total loans/total assets bequity bank book equity bank book equity npl non performing loans non performing loans TBE total bank equity sum of bequity 27/28
EMPIRICAL EVIDENCE: CONDITIONAL CORRELATIONS Predictions: Loan rate and MTB ratio are decreasing functions of aggregate bank capital Y it = α + β E t 1 + γ 1 bequity it 1 +... + γ 5 Timedummy it + ɛ it }{{} <0 28/28