Liquidity Risk of Corporate Bond Returns Viral Acharya(NYU Stern), Yakov Amihud (NYU Stern) and SreedharBharath(ASU) Forthcoming, JFE Sponsored by Centre for Advanced Financial Research and Learning (CAFRAL) and Fixed Income Money Market and Derivatives Association of India (FIMMDA) A short introduction: The effect of market liquidity on asset pricing Our formal model assumes that Assets are characterized by dividendstream and trading costs. The prevailing theory of asset pricing: Investors’need to trade occurs randomly. Positive risk-return relation. However, the empirical evidence for the stock market is that on In equilibrium, we prove that … average, RM -Rf> 0. 1. Asset returnsare increasingfunction of trading costs. Across stocks, empirical evidence is scarceor non-existent, or (The function is concave.) higherrisk loweraverage return. Or Problems in estimating risk. Asset pricesare decreasingand convexfunction of trading costs. The theory of Amihud & Mendelosn(1986): 2. Netreturns too are an increasingfunction of trading costs. Positive illiquidity-return relation. The expected excess monthly return (or yield) on a stock as a function of the stock’s bid-ask spread, reflecting clienteles (Amihud-Mendelson1986) P/E ratio and liquidity(Loderer& Roth, JEF 2003) R= 0.0065 + 0.01β+ 0.0021ln(S) + year dummies i i i The effect of illiquidity (relative bid-ask spread) on the P/E ratio, controlling for 0.80% (1) beta, (2) dividend payout, (3) current EPS growth and (4) expected earnings 0.70% growth (from analysts’reports). 0.60% Excess Monthly Return000...345000%%% Result: discount of over 20%for a median-spread stock compared to zero- 0.20% spread stock (1995-2001). 0.10% Discount as a function of spread is observed for both Nasdaqand Swiss stocks. 0.00% 0.0% 0.5% 1.0% 1.5% 2.0% 2.5% 3.0% 3.5% 4.0% 4.5% 5.0% Bid-Ask Spread (%) Restricted stock. Price discount of about 1/3. (Silber 1991). There is ample empirical support for this relation by independent studies. Why do small trading costs have a big price effect? Liquidity is hard to observe, but we observe trading frequency, which by Amihud- Because they are incurred repeatedly, for ever. Mendelson(1986) is affected by trading costs. Turnover= (volume /number of shares) proxies for trading frequency. A quick calculation: More liquid stocks are traded more frequently. Valuation of transaction cost of c PV= c / (r-g). The effect of turnover on stock returns –cross-section analysis It growswith the stock price, whose growth rate is r –D/P. Explanatory Variables: All months Excl. January PV= c * P/D Turnover: -.04 (8.58) -.04 (7.91) Book/Market: .14 (5.97) .08 (3.29) Assume that trading is once a year. log(Size): -.05 (4.65) .02 (1.60) Stock dividend yield, D/P, is now about 2%-2.5%. β: -.37 (5.76) -.05 (6.84) the price multipleof trading cost cis 40-50. 0.1% trading cost leads to at least 4% discount in stock price. Higherliquidity, or turnover lowerexpected returns. The effect of ILLIQ= avg(|R|/$Volume) on stock expected return (constant omitted), monthly, 1964-1997 [From Amihud (2002)] Liquidity changes over time: Evidence from the recent crisis Variable All months Excl. January 1964-1980 1981-1997 U.S. trading costs as % of stock prices. Based on data from ITG. BETA 0.217 (0.64) 0.260 (0.79) 0.297 (0.59) 0.137 (0.30) 1.8% Small Cap ILLIQMA 0.112 (5.39) 0.103 (4.91) 0.135 (3.69) 0.088 (4.56) 1.6% All 1.4% Large Cap LnSIZE -0.134 (3.50) -0.073 (2.00) -0.217 (3.51) -0.051 (1.14) 1.2% 1.0% StdDevof Return -0.179 (1.90) -0.274 (2.89) -0.136 (0.96) -0.223 (1.77) 0.8% 0.6% DIVYLD -0.048 (3.36) -0.063 (4.28) -0.075 (2.81) -0.021 (2.11) 0.4% 0.2% R100 0.888 (3.70) 1.335 (6.19) 0.813 (2.33) 0.962 (2.92) 0.0% Q3  Q1  Q3  Q1  Q3  Q1  Q3  Q1  Q3  Q1  Q3  Q1  RYR 0.359 (3.40) 0.439 (4.27) 0.324 (2.04) 0.395 (2.82) 2005 2006 2006 2007 2007 2008 2008 2009 2009 2010 2010 2011 The effects of expectedand unexpectedilliquidity(illiquidity shocks) on excess monthly stock returns, 1964-1996. Current paper, Liquidity Risk of Corporate Bond Returns Note: The (absolute) effect of liquidity declines in size. The yield spread on corporate bonds is considered a riskand defaultpremium. Excess returns on size-based portfolios RM-Rf RSZ -Rf RSZ -Rf RSZ -Rf RSZ -Rf RSZ –Rf (EW) 2 4 6 8 10 Corporate bonds are usually less liquidthan Treasury bonds, especially the Constant -3.876 -4.864 -4.335 -4.060 -3.660 -1.553 high-yield ones. (1.97) (2.03) (2.12) (2.13) (2.05) (0.99) LnMILLIQ 0.712 0.863 0.808 0.761 0.701 0.319 m-1 (2.12) (2.11) (2.33) (2.36) (2.30) (1.18) Therefore, bond returns should respond to liquidity shocks (in addition to other LnMILLIQ U -5.520 -6.513 -5.705 -5.238 -4.426 -3.104 shocks that affect bond prices) because the required yield changes then. m (4.42) (4.53) (4.34) (4.12) (4.04) (3.38) The yield spread reflects both risk\default premium and illiquidity premium. JANDUM 5.280 8.067 5.446 4.232 3.000 1.425 m (4.20) (5.03) (4.08) (3.45) (2.64) (1.47) Chen, Lesmond& Wei (2007) –pricing of the levelof illiquidity. R-squared 0.144 0.188 0.140 0.119 0.089 0.049 D-W 1.98 1.99 1.96 1.99 2.03 2.14 deJong& Driessen(2007), Lin, Wang & Wu (2011) –pricing liquidity risk. Liquidity costs and corporate bond yields Liquidity and Treasury securities yields Yield spreads are known to exceed the expected cost of default, given data on default probability and recovery rate. 1) Amihud-Mendelson(JF 1991): The excess yield compensates for both riskand illiquidity. Treasury billsand Treasury noteswith the same(short) maturity: Lower ratinglower liquidity(higher bid-ask spread and other measures of Riskis the same. illiquidity) higher illiquidity premium. Bills are more liquidthan bonds, bills have lower yieldthan notes. Chen, Lesmond& Wei (JF 2007) estimate the effect of the levelof trading costs on the cross-section of bond yields, 2) On-the-run bonds are more liquid than off-the-run bonds, and have lower controlling for bond and firm characteristics, such as rating, leverage, risk. yield. Results: Trading costs have a positiveand highly significant effect on yield spread. Estimating the effect of Liquidity Risk on bond returns Research questions: (current paper) Market liquidity changes over time. We study liquidity risk, the exposureof bond prices to liquidity shocks (the R = a+ β TERM + β DEF+ β Silliq+ β Billiq e , returns-liquidity shocks covariance). j,t j T,j t D,j t SI,j t BI,j t+ j,t -Does the liquidity risk changeover time? (risk in liquidity risk) -Is this change different for different ratingclasses of bonds? R, = excess return on bond portfolio (over 30-day T-Bill rate) jt -Is the liquidity risk conditional? TERM: Long-term govt(30yr) minus 30-day T-Bill return t -If so –is there an economic identificationof changes in liquidity risk? DEF:Eq-wtdreturns of all corporate bonds (maturity > 1 yr) –average return on t 1-yr and 30-yr govtbonds A two-step approach: 1) Statisticalanalysis: Test for a pattern in changes over time in liquidity risk Silliq , Billiq:Innovations in stock and Treasury bond illiquidity (from AR(2) t t 2) If there is a pattern of such a change –identify its economic determinants. and AR(3) models). Related models and theories: Firm’s policy-related model: Focus on incentives and endogenizedconstraint: Brunnermeierand Pedersen(2009): marketliquidity can be adversely affected Acharyaand Viswanathan(2011): by fundingliquidity. Because of margin constraints, a negative value shock Adverse value shock affect financial firms\intermediaries causes a liquidity shock because of correlated liquidations. This lowers asset greater firm’s leverage values and exacerbates the effect of the shock. incentive of firm’s managers to risk-shift greater constraint on outside funding (rolling over debt) He and Krishnamurthy(2010): Households invest through intermediaries. A worsening funding liquidity negative wealth shock makes them allocate money away from risky to riskless need of firm to de-lever assets, lowering intermediaries’wealth and causing capital constraints and sale of assets forced liquidation. worsening liquidity. This in turns affects asset prices. Sample period: 1973-2007, 420 months. Bond data are from Lehman Fixed Income Database (Warga, 1998) for 1981-1996, and Merrill Lynch corporate bond index database (Schafer & Strebulaev, 2008) thereafter, incl. 2008-9. Returnsare calculated from monthly prices and accrued interest. Corporate bonds are largely held in institutionalportfolios rather than in retail ones. Studying their return-liquidity relations is an appropriate setting to identify -We use actual prices, no matrix pricing. Bonds with no options(call, sinking these liquidity effects. funds). Excluded: bonds not in Lehman or Merrill indexes; with maturity < 1 year; not rated; non-identical S&P\Moody’s rating; special features (call, sinking funds, floating rate). -Average # bonds in each month: 2,234(between 245 and 9,286). -We construct indices of bond returns, VW, by rating class. Illiquidity innovations Stock illiqinnovations Equity-market illiquidity: Amihud’s(2002) ILLIQ, the equally-weighted monthly average of daily |return|/dollar volume, as modified by Acharyaand Pedersen (2005). ILLIQmeasures price impact, related to Kyle’s (1985) λ. Treasury bond market illiquidity: the monthly quoted % bid-ask spread of short maturity on-the-run treasuries (source: Goyenko(2006)). Was used by Longstaff, Mithal, Neis(2004), deJongand Driessen(2009). The innovations are residualsfrom an autoregressivemodel, AR(3) for stocks and AR(2) for bonds. The coefficients are adjusted for finite sample by Shaman and Stine’s (1989) method. Unconditional liquidity risk (red=significant) Bond illiqinnovations Coefficients Rating α ßT(allsignif.) ßD(allsignif.) ßSI ßBI Adj-Rsq AAA 2.68 0.42 0.76 73.70 13.58 0.76 AA 5.68 0.47 0.81 61.69 1.81 0.79 A 3.55 0.50 0.90 40.39 -1.66 0.82 BBB 3.72 0.47 0.97 17.06 -11.42 0.75 BB (Junk) 14.91 0.38 0.98 -90.15 -57.28 0.51 B 23.61 0.35 0.99 -193.55 -70.07 0.30 CCC & 84.52 0.21 0.89 -328.70 -63.19 0.11 below TERM DEFAULT SILLIQ DEF -0.529 1 Silliq 0.041 -0.153 1 Billiq -0.057 -0.057 0.086 Time-varying betas Time-varying betas Estimate a Markov regime-switching model in a two-equation model, for Investment Grade (IG) and Junk (Jnk) • Estimate a Markov regime-switchingmodel Regime-switching analysis, Hamilton (1994) Regime-Dependent Variance-Covariance Matrix (s= 1,2): t R , = a + β TERM+ β , DEF+ β Silliq+ β Billiq+e , IGt IG IG,T t IGD t IG,SI t IG,BI t IGt R ,=a + β TERM +β , DEF + β Silliq + β Billiq+ JNkt IG JNK,T t JNKD t JNK,SI t JNK,BI t e , Markov switching probability for state transition: JNKt P(s= 1| s = 1) = p t t–1 P(s= 2| s = 2) = q t t–1 Liquidity betas changesubstantially between regimes Wald tests for differences in coefficients–Chi-sq tests Numbers are p-values Regime 1 Investment G t-stat Junk Grade t-stat Parameters Constant 2.34 1.36 27.21 4.72 P 0.96 TERM 0.35 44.38 0.28 12.56 q 0.93 DEF 0.37 12.06 1.08 10.07 Between regime 1 and 2 Between IG and Junk Silliq 13.95 1.21 -68.89 -2.08 ρSt =1 0.10 Investment G Junk Regime 1 Regime 2 Billiq -2.40 -0.49 -14.11 -0.91 ρSt =2 -0.40 TERM & DEF 0.00 0.00 0.00 0.15 σi 24.31 82.96 Regime 2 Liquidity 0.01 0.01 0.04 0.00 Investment G t-stat Junk Grade t-stat TERM 0.00 0.01 0.00 0.36 Constant 7.21 1.59 22.07 1.44 DEF 0.00 0.92 0.00 0.47 TERM 0.52 29.92 0.46 7.56 Silliq 0.03 0.01 0.01 0.00 DEF 0.97 26.76 1.06 8.78 Billiq 0.02 0.10 0.44 0.00 Silliq 64.77 3.13 -195.19 -4.31 Billiq 20.69 2.37 -65.76 -2.37 σi 53.18 188.23 Probability of “stress”regime. Pairs of estimates: Stress regime linked to recessions (1)OLS, with logittransformation of prob(Regime2) (2)Logitestimation, with dummy = 1 if prob(Regime2)> 0.70 Variables lagged (1) (2) (3) (4) (5) (6) (7) (8) Const. -1.92*** -1.03*** -1.11*** -.70*** -2.69*** -1.40*** -1.92*** -1.06*** NBER Recession 5.88*** 2.62*** Stock-Watson Index -1.69*** -.76*** Prob(Recession) 4.71*** 2.01*** -Hamiliton Negative Market 3.12*** 1.78*** Return dummy Business -1.81*** -.93*** Conditions Index Paper-Bill Spread .01** .004** TED Spread .03*** .01*** Obs. 419 419 419 419 419 419 419 419 AdjR2 / PsedoR2(%) 18 13 11 8 14 10 23 16 Out of sample predictions of the “stress”regime Probability of Regime 2 Dep. Var= 1 if the actual prob(Regime2)> 70%, from statistical model Variables lagged (9) (10) (11) (12) (13) (14) Predicted prob(Regime2)is rolling monthly estimate from the economic Const. -4.57*** -2.50*** -4.69*** -2.54*** -4.75*** -2.62*** NBER Recession 1.43* 1.20* prediction model (14), we start with estimates from 1973-1989 (1/2 the sample), Stock-Watson Index 0.12 .06 0.006 -0.03 and predict for 1990-2007 Prof(Recession)-Hamilton 1.08 1.01** 1.32** 1.21** Regime 2 (as per Regime Switching Model 1990-2007) Negative Market Return 0.85 0.85 1.11 1.04* Business Conditions -0.99*** -0.47** -1.13*** -0.60** Constant -1.78*** Index (.24) Paper-Bill Spread .002 -0.005 0.004 -0.002 Predicted prob(Regime2) 5.77*** TED Spread .03*** 0.01*** 0.03*** 0.01*** (.94) EE measure year growth -229.49*** -245.46*** -200.11*** -239.90*** -206.00*** -239.09*** __________________________________________________________________ _ Equity Volatility 93.82*** 53.44*** 80.39*** 49.93*** 80.53*** 50.01*** Obs. 216 Equity Volatility* EE 5099.01*** 5009.99*** 4248.32*** 4011.05*** 4364.55*** 4029.97*** Pseudo R2(%) 27 measure year growth _____________________________________________________________________ Obs. 419 419 419 419 419 419 _ Adj/ Pseudo R2(%) 28 23 44 36 43 35 Flight to Liquidity Out-of-sample prediction of conditional bond returns Junk-IG Junk-IG DEF -(T-Bill -(T-Bill Short Medium Long Return Return Return Yld Yld Junk-IG Junk-IG (Junk-IG) for the financial crisis years, 2008-2009 -Fed -Fed Funds) Funds) (1) (2) (3) (4) (5) (6) (7) (8) Const. 26.46*** 26.02*** 6.89 68.09** 48.57*** 24.24*** 28.43*** 24.13** In each month, we calculate Prob(Regime2)using our logitprediction model Prob(Regime2) -2.80 -13.27 -.10 50.71*** -3.50 -27.00 13.40 TERM -.07*** -.08*** .002 -.18*** -.47*** (column (14)). DEF .84*** .77*** -.07** -.11** .55*** .61*** .62*** We calculate portfolio returns using the coefficients of each ofthe two regimes, Silliq -64.66* -75.38** 25.02 -10.08 -57.79* -64.59 -126.09* Billiq -2.00 -29.67** 21.37** -7.63 -7.38 -5.81 -13.50 conditional on the realized factors TERM, DEF, BILLIQ, SILLIQfor that month. Prob(Regime2)* .04 .03 .01 -.06 .15 TERM Prob(Regime2)*DEF -.66*** -.67*** 0.5 -.37** -.71*** -.82*** Then, denoting p2= Prob(Regime2), Prob(Regime2)* -210.23* -66.43 58.05 -132.14 -274.55** -233.20* Silliq PBrilolibq(Regime2)* -90.79** 35.84 57.14*** -28.04 -76.95* -104.61** Predicted return= (1-p2)*(predicted return using regime 1 coefficients) Obs. 420 420 420 420 420 420 420 420 AdjR2(%) 11 18 3 3 12 20 30 42 + p2*(predicted return using regime 2 coefficients) Predicting investmentgrade bond returns in 2008-2009 Predicting junkbond returns in 2008-2009 Actual Bond Returns vs. Predicted Bond Returns Actual Bond Returns vs. Predicted Bond Returns 1500 Investment Grade, Year 2008-9 11 1500 Junk Grade, Year 2008-9 15 11 Actual Bond returns (bps)-1000-50005001000 RMR8MSES E(4 (51r3 edgerge9rseseio lnin)e =) 2=11 0240251141.22132211371.426960A231R2tc42-1s-t07uStaaqtlu =a(18 r08e.15.d858 4=) P 7 r7 e % d i c t e d ( 0+. 141.6)5 Actual Bond returns (bps)-1000-500050010008 RMRSME5S9 E(4 (5r edg1e2r1ge139rsesei2o 1lnin)e1 2=1)67 3=12 032633.9703.754314AcRt-tsu-Sta2a2qlt = u 1( a608r..e842d0642 4 )=1P 8 r7 e 6 d % i c t e d (+0 .5717.)15 -1500 -1000 -500 0 500 1000 -1500 -1000 -500 0 500 1000 Regime Switching Model Prediction (bps) Regime Switching Model Prediction (bps) Data source: Regime Switching Model, Table 3 Data source: Regime Switching Model, Table 3 Out-of-sample predictions during the financial crisis 2008-2009 The effects on stocks, classified by Book/Market Predicted value use estimated prob(Regime2) from the logitmodel, using the economic time series, the estimated coefficients of each regime and the current values of TERM, DEF, BILLIQ, SILLIQ Famaand French (1995): “Firms with high BE/ME…tend to be persistently (SE in parentheses) distressed. They have low ratios of earnings to book equityfor at least 11 Dependent variable:  Actual IG Returns Actual Junk years around portfolio formation. Conversely, low BE/ME…is associated with Returns sustained strong profitability.” Constant 4.65 (42.93) 51.15 (66.82) Recent studies (e.g., Chen, Noe& Tice, 2009) confirm that. Predicted cond. IG return 0.839 (0.098) Predicted cond. Junk return 0.862 (0.102) We replicate the analysis for the high and low BE/ME quintiles. R-sqr(%) 77 76 p-value of F-test if slope = 1.0 0.12 0.19 High and low BE/ME are taking the role of “junk”bonds and IG bonds, Obs 24 24 respectively. Liquidity betas change substantially between regimes Wald tests for differences in coefficients–Chi-sq tests Regime 1 Numbers are p-values Low BM t-stat High BM t-stat Parameters Constant -71.88 -7.95 -5.17 -0.43 P 0.96 Rm-Rf 113.44 50.65 86.20 26.69 q 0.90 TERM -0.07 -2.11 0.05 1.28 DEF -0.35 -2.89 0.36 2.04 ρSt =1 -0.650 Between regime 1 and 2 Between High & Low BM Silliq 83.38 1.01 -54.92 -0.72 ρSt =2 -0.495 Low BM High BM Regime 1 Regime 2 Billiq 55.15 3.11 -65.46 -2.63 Rm-Rf 0.17 0.66 0.00 0.00 σi 117.50 156.09 TERM 0.62 0.48 0.06 0.28 Regime 2 DEF 0.30 0.71 0.01 0.07 Low BM t-stat High BM t-stat Constant -49.15 -1.42 -12.76 -0.31 Silliq 0.92 0.02 0.36 0.00 Rm-Rf 107.66 33.70 82.79 12.83 Billiq 0.23 0.67 0.00 0.27 TERM -0.03 -0.38 0.16 1.17 DEF -0.16 -1.18 0.50 1.77 Silliq 73.62 1.70 -242.21 -4.20 Billiq 6.30 0.18 -88.32 -1.48 σi 179.18 366.86