2.1 Fundamentals

Time is discrete and continues forever. The economy is inhabited by a unit mass of anonymous ex-ante identical agents, who cannot commit to future actions. Two different goods are available in the economy. One good is durable and can be either consumed or accumulated as capital, $k$ . All the agents can produce the durable good with labor used as input into a linear production function. Labor generates linear disutility for the agents. All the agents wish to consume the durable good from whose consumption they derive linear utility. The other good is perishable, and its production requires capital as an input. The perishable good is produced with a differentiable production function $f ( k )$ that satisfies $f ( 0 ) =0$ , $f^{\prime } ( 0 ) =\infty$ , and $f^{\prime } ( \infty ) =0$ , with $f^{\prime }\gt 0\gt f^{\prime \prime }$ . At the beginning of each period, half of the agents are randomly selected by an i.i.d. process to become producers of the perishable good. We call these agents entrepreneurs and the rest investors. Capital depreciates after production at rate $\delta \lt 1$ . We will use the notation $F ( k ) \equiv f ( k ) + ( 1-\delta ) k$ . If not used in production, capital can be stored without cost. Only the producers of the perishable good wish to consume it, obtaining linear utility from its consumption. The perishable good disappears if not consumed immediately after production. All the agents discount future payoffs at rate $\beta \lt 1$ .

2.2 Trade

In each period, the agents can interact in three different markets, a liquidity market (LM), a secondary market (SM) for previously accumulated capital, and a primary market (PM) for new capital, opening sequentially. In the LM, the agents may choose to trade liquidity at a competitive price $p$ .Footnote ¹³ There is neither production nor consumption at this stage. Capital accumulated from the past can be traded in the SM. Trade in this market is bilateral, with each entrepreneur being matched to an investor, and the price is determined by an increasing function, $q ( \kappa )$ , of the amount traded in the SM, $\kappa$ , which we assume linear in order to stay as close as possible to the competitive framework of Kiyotaki and Moore (Reference Kiyotaki and Moore2019).Footnote ¹⁴ Production and consumption of the perishable good occur after capital is traded in the SM but before the PM opens. The durable good is the numeraire and can be traded in the competitive PM. Production and consumption of the durable good, as well as the accumulation of new capital, all occur before the end of the current period. The economy begins in the first period in the PM. Three assets are available for trade, money, $m$ , public bonds, $b$ , and capital, $k$ . Money is an intrinsically worthless durable object whose supply, $M$ , is controlled by the monetary authorities. Its price in numeraire units is $v$ . Bonds, whose supply is denoted by $B$ , are sold by the fiscal authority for money during the PM of each period and reimbursed in money during the following PM with a competitively determined gross interest rate $i$ . The bonds cannot be traded in the SM due to a legal restriction that prevents them from serving as direct payment instruments, but they can be traded in the LM for money.Footnote ¹⁵ The output produced with capital is perishable and specific for the use of entrepreneurs; hence, it cannot be pledged to investors to acquire capital in the SM, but capital, whose aggregate stock is denoted with $K$ , is identifiable and can be seized by outsiders; hence, the agents can issue equity on its undepreciated value. Equity, however, can be counterfeited on the spot without cost by the entrepreneurs.Footnote ¹⁶ The investors are unable to recognize counterfeits unless they incur a cost $c$ at the beginning of the period. If the investors incur the cost, in the SM, they can use a technology that distinguishes counterfeited from genuine equity. Equity issued in any given period, whether genuine or counterfeited, disappears before the beginning of the following period. Equity may also be interpreted as a one-period security or loan backed by a real asset.

2.3 Government

The monetary and fiscal authority are consolidated in a single agency called the government. The government has a limited ability to tax the agents due to their anonymity. However, since capital is identifiable by outsiders, the government may be able to tax the agents up to the value of their undepreciated capital holdings. The government fulfills its budget constraint, $M_{+1}=M+B-i^{-1}B_{+1}-T$ .Footnote ¹⁷ Lump-sum taxation is represented by $T\equiv \tau ( M+B )$ as a fraction of the outstanding stock of liquid government instruments, with a negative $\tau$ representing a subsidy. We define the bonds to money ratio $x\equiv \frac{B}{M}$ and assume that the government keeps it constant over time. With this notation, the budget constraint of the government can be written as

(1) \begin{equation} \frac{M_{+1}}{M}=\frac{\left ( 1+x\right ) \left ( 1-\tau \right ) }{1+xi^{-1}}. \end{equation}

Hence, we will use $x$ as the monetary policy parameter, capturing open market operations, namely relative shift in the long run proportion of the stock of money and bonds available in the economy, and indirectly controlling the growth rate of the money stock. The fiscal policy parameter $\tau$ also partially controls the growth rate of the money stock. The policy pair $ ( \tau,x )$ is decided and implemented once and forever at the initial date. We restrict attention to the empirically relevant case with $x\geq 1$ and $\tau \in [ 0,1-\beta ]$ . To save on notation, we will sometimes use $z\equiv 1-\beta -\tau \geq 0$ .

2.4 Efficiency

Every period, a randomly selected half of the agents turns out to have an amount of capital for which they have no immediate better use than storing it, while the rest can use it in production. The efficient level of capital accumulation solves the recursive problem,

\begin{equation*} V\left ( k\right ) =\max \text { }\frac {1}{2}F\left ( 2k\right ) +k-k_{+1}+\beta V\left ( k_{+1}\right ), \end{equation*}

where $2k=K$ , as efficiency requires that capital should be allocated entirely to the entrepreneurs for the production of the perishable good if the marginal productivity is larger than depreciation. This is because the best alternative for the investors consists in storing the capital, which gives a zero net return. Optimization with respect to capital accumulation leads to the Euler condition

(2) \begin{equation} 1=\beta F^{\prime }\left ( K\right ). \end{equation}

By continuity and the Inada conditions, a positive solution of (2) exists and by concavity of the production function is unique. Since the marginal productivity of undepreciated capital is $\beta ^{-1}\gt 1$ , which is the return of storage, the allocation of the entire amount of available capital to the entrepreneurs is vindicated. The efficient amount of capital is

(3) \begin{equation} K^{\ast }=f^{\prime -1}\left ( \beta ^{-1}-1+\delta \right ). \end{equation}

The efficient amount of capital accumulation, (3), could be decentralized as a competitive equilibrium for all parameter values if there was full commitment or for $\beta$ sufficiently large if the traders were not anonymous.

3.1 Liquid equilibrium

Consider the case in which the investors, at the beginning of the period, decide to incur the cost $c$ to distinguish genuine from counterfeited equity. In this scenario, bonds are used to trade money in the LM, and then, money and equity are traded in the SM for second hand capital. An entrepreneur chooses how much money to acquire in the liquidity market, $m^{d}$ , and how much capital to trade in the secondary market, $\kappa$ , to maximize

\begin{equation*} V^{E}\left ( m,b,k\right ) =\max \text { }f\left ( k+\kappa \right ) +\left ( 1-\delta \right ) \left ( k+\kappa \right ) -q\kappa +vm^{d}-pm^{d}+W\left ( m,b\right ) \end{equation*}

subject to the constraints

(4) \begin{equation} pm^{d}\leq vb. \end{equation}

in the LM and the constraint

(5) \begin{equation} q\kappa \leq vm+vm^{d}+\left ( 1-\delta \right ) k, \end{equation}

in the SM. These two constraints reflect the purchase of money in the liquidity market using bonds and, then, the purchase of additional capital in the secondary market using all the money held by the entrepreneur, including the cash just acquired in the liquidity market, and equity on undepreciated capital. An investor chooses how much money to sell in the liquidity market, $m^{s}$ , and trade in the secondary market, to maximize

\begin{equation*} V^{I}\left ( m,b,k\right ) =\max \text { }k-\kappa +q\kappa +pm^{s}-vm^{s}+W\left ( m,b\right ) \end{equation*}

subject to the constraint

(6) \begin{equation} vm^{s}\leq vm, \end{equation}

and

(7) \begin{equation} \kappa \leq k. \end{equation}

These constraints reflect the limited amount of cash and capital currently in the hands of the investor. In the primary market, an agent chooses money, $m_{+1}$ , bonds, $b_{+1}$ , and capital, $k_{+1}$ , to solve

\begin{equation*} W\left ( m,b\right ) =\max \text { }vm+vb-t-vm_{+1}-i^{-1}vb_{+1}-k_{+1}+\beta V\left ( m_{+1},b_{+1},k_{+1}\right ), \end{equation*}

where $t\equiv \tau vM ( 1+x )$ and the value function satisfies

\begin{equation*} V\left ( m,b,k\right ) =\frac {1}{2}\left [ V^{E}\left ( m,b,k\right ) +V^{I}\left ( m,b,k\right ) \right ]. \end{equation*}

The distribution of assets is degenerate at equilibrium by virtue of the linearity of the payoffs, as in Lagos and Wright (Reference Lagos and Wright2005). The market clearing conditions are $m^{s}=m^{d}$ for trade in the LM; $m=M$ and $b=B$ for money and bonds, and the market clearing condition for the durable good. The amount traded in the SM match since meetings are bilateral. A competitive equilibrium requires the agents to optimize taking prices as given and the prices to clear the competitive markets. We consider stationary equilibria, namely equilibria in which real variables are time invariant. The equilibrium conditions are fully derived in the Appendix. Since money and bonds are traded for each other in the liquidity market, by arbitrage, their returns are equated, that is $\frac{p}{v}=i$ . Define the gross return of capital as $r\equiv \frac{F^{\prime }\left ( K\right ) }{q}$ . All the constraints are binding at equilibrium, except possibly (4). The stationary equilibrium conditions are the Euler condition for money

(8) \begin{equation} 1=\frac{\beta }{2}\frac{\left ( i+x\right ) \left ( r+i\right ) }{\left ( 1-\tau \right ) i\left ( 1+x\right ) }, \end{equation}

since money is used by the entrepreneurs to acquire capital in the secondary market and sold for bonds by the investors in the liquidity market earning the corresponding interest, with the return of money being the inverse of (1); the Euler condition for capital accumulation

(9) \begin{equation} 1=\frac{\beta }{2}\left [ q\left ( r+1\right ) +\left ( r-1\right ) \left ( 1-\delta \right ) \right ], \end{equation}

where the first term in brackets on the RHS is the fundamental value of capital, while the second corresponds to the liquidity premium, reflecting a pecuniary externality that is at work in the accumulation of capital; and the complementary slackness condition for the liquidity constraint (4)

(10) \begin{equation} \left ( r-i\right ) \left ( x-i\right ) =0. \end{equation}

To guarantee that the investors have the incentive to accept bonds in the LM and sell capital in the SM, it has to be that $i\geq 1$ , $r\geq 1$ , and $q\geq 1$ . The technology to distinguish genuine from counterfeited equity is adopted by all investors. Next, we define the equilibrium with liquid equity.

The next Proposition establishes existence and uniqueness of such an equilibrium. An equilibrium is constrained if the liquidity constraint is binding and unconstrained otherwise.

The restriction for $\tau$ guarantees $q\geq 1$ . The restriction for $c$ guarantees that each investor has the incentive to adopt the technology that distinguishes genuine from counterfeited equity when everybody else does. There are two possibilities, as the liquidity constraint may be binding or not. When the liquidity constraint is binding, the equilibrium is constrained and the interest rate is $\widetilde{i}=x\geq 1$ ; when the constraint is slack, the equilibrium is unconstrained and the interest rate is $\widetilde{i}=\widetilde{r}\geq 1$ . In both cases, the return of capital is

(11) \begin{equation} \widetilde{r}=\frac{\beta +z\left ( 1+x\right ) }{\beta }, \end{equation}

and the price of second hand capital is

(12) \begin{equation} \widetilde{q}=\frac{2-z\left ( 1+x\right ) \left ( 1-\delta \right ) }{2\beta +z\left ( 1+x\right ) }. \end{equation}

This is an equilibrium in which the liquidity market is open, debt serves to reshuffle and reward with interest money holdings that would otherwise remain idle, and equity is used as payment instrument together with money to trade capital in the secondary market. In this sense, equity is liquid.

3.2 Illiquid equilibrium

Suppose now that the investors decide not to pay the cost $c$ , and, hence, payment with equity is refused in the SM since the investors are worried that equity may be counterfeited. The only difference with the previous case is that the constraint (5) becomes

(13) \begin{equation} q\kappa \leq vm+vm^{d}, \end{equation}

since capital is illiquid. The equilibrium conditions are the same except for (9) that becomes

(14) \begin{equation} 1=\frac{\beta }{2}q\left ( r+1\right ), \end{equation}

since there is no liquidity premium for capital anymore, and, hence, capital has only fundamental value. To guarantee that the investors have the incentive to accept bonds in the LM and sell capital in the SM, it has to be that $i\geq 1$ , $r\geq 1$ , and $q\geq 1$ . The technology to distinguish genuine from counterfeited equity is not adopted by any investor. Next, we define the equilibrium with illiquid capital.

The next Proposition establishes existence and uniqueness of such an equilibrium. An equilibrium is constrained if the liquidity constraint is binding and unconstrained otherwise.

The restriction for $\tau$ guarantees $q\geq 1$ . The restriction for $c$ guarantees that each investor has no incentive to adopt the technology that distinguishes genuine from counterfeited equity when nobody else does. The equilibrium values of $i$ and $r$ are the same as in the previous case, with $\widehat{i}=x$ , when the equilibrium is constrained, $\widehat{i}=\widehat{r}$ , when unconstrained; and

(15) \begin{equation} \widehat{r}=\frac{\beta +z\left ( 1+x\right ) }{\beta }. \end{equation}

The price of second hand capital, instead, is

(16) \begin{equation} \widehat{q}=\frac{2}{2\beta +z\left ( 1+x\right ) }, \end{equation}

which is larger than at the liquid equilibrium for $\tau \lt 1-\beta$ and the same for $\tau =1-\beta$ . In this equilibrium, capital is illiquid. When this occurs, the equity premium disappears, which makes the price of second hand capital higher than with liquid equity.

3.3 Implications

The model has implications for the so-called Tobin’s Q, leverage, capital, and output, as we document next.

Tobin’s Q The Tobin’s Q is the ratio between the market value of a company and the replacement cost of its capital. In the current model, the market value of the entrepreneur’s company is $ ( 1-\delta ) K$ and the replacement cost of capital is $qK/2$ . Hence, the Tobin’s Q is $Q\equiv 2 ( 1-\delta ) q^{-1}$ . Inserting into it the equilibrium value of $q$ , at the two equilibria, (12) and (16), we obtain, respectively,

(17) \begin{equation} \widetilde{Q}=\frac{2\left ( 1-\delta \right ) \left [ 2\beta +z\left ( 1+x\right ) \right ] }{2-z\left ( 1+x\right ) \left ( 1-\delta \right ) }, \end{equation}

at the liquid equilibrium, and

(18) \begin{equation} \widehat{Q}=\left ( 1-\delta \right ) \left [ 2\beta +z\left ( 1+x\right ) \right ], \end{equation}

at the illiquid equilibrium, with (17) strictly larger than (18) for $\tau \lt 1-\beta$ and equal to it for $\tau =1-\beta$ . We conclude that the Tobin’s $Q$ is higher when equity is liquid. This is consistent with the available evidence and stands in contrast to the model of Kiyotaki and Moore (Reference Kiyotaki and Moore2019), that gives rise to the counterfactual prediction that the equity price is higher when equity is less liquid, as pointed out by Shi (Reference Shi2015).Footnote ¹⁸

Leverage Interpreting equity as an asset-backed security, the model determines also leverage in the sense of Geanakoplos (Reference Geanakoplos2010). Leverage is the ratio of the asset value to the cash needed to purchase it. In our model, this is given by $L\equiv qK ( 4vM ) ^{-1}$ . In this model, leverage depends on the equilibrium that realizes. At the liquid equilibrium, $4vM= ( q-1+\delta ) K$ , by the binding payment constraint. Inserting into it the value of $q$ at the liquid equilibrium, (12), we obtain

(19) \begin{equation} \widetilde{L}=\frac{2-z\left ( 1+x\right ) \left ( 1-\delta \right ) }{2\left [ 1-\beta \left ( 1-\delta \right ) -z\left ( 1+x\right ) \left ( 1-\delta \right ) \right ] }, \end{equation}

which is larger than 1. At the illiquid equilibrium, we have that $4vM=qK$ , by the binding payment constraint. Hence, at the illiquid equilibrium, there is no leverage,

(20) \begin{equation} \widehat{L}=1. \end{equation}

This is because the asset-backed securities are not traded. This is broadly consistent with the evidence for the US, where the leverage for asset-backed securities was largely above 1 for the entire period between 2000 and the 2008 financial crisis, and was down to 1 during the crisis.Footnote ¹⁹

Capital and Output The stock of capital is $K=f^{\prime -1} ( rq-1+\delta )$ , which is a decreasing function of its argument, since the production function is strictly concave. At the liquid equilibrium, inserting the equilibrium values (11) and (12), we obtain the capital stock

(21) \begin{equation} \widetilde{K}=f^{\prime -1}\left ( \frac{2\left [ 1-\beta \left ( 1-\delta \right ) \right ] \left [ \beta +z\left ( 1+x\right ) \right ] -z^{2}\left ( 1+x\right ) ^{2}\left ( 1-\delta \right ) }{\beta \left [ 2\beta +z\left ( 1+x\right ) \right ] }\right ). \end{equation}

At the illiquid equilibrium, inserting the equilibrium values (15) and (16), we obtain the capital stock

(22) \begin{equation} \widehat{K}=f^{\prime -1}\left ( \frac{2\left [ 1-\beta \left ( 1-\delta \right ) \right ] \left [ \beta +z\left ( 1+x\right ) \right ] +z\left ( 1+x\right ) \beta \left ( 1-\delta \right ) }{\beta \left [ 2\beta +z\left ( 1+x\right ) \right ] }\right ), \end{equation}

which is strictly smaller than (21) for $\tau \lt 1-\beta$ and equal to it for $\tau =1-\beta$ . Since output is an increasing function of the capital stock, $f ( K )$ , and the capital stock is larger at the liquid than the illiquid equilibrium, it follows that GDP is higher when the economy is liquid than illiquid. This is consistent with the evidence on the great recession for the US that saw a drop of 8% of GDP in the last quarter of 2008.Footnote ²⁰

3.4 Welfare

Due to the linearity of the payoffs, the ex-ante welfare of the individuals at any stationary equilibrium of the model is given by

(23) \begin{equation} V\left ( K\right ) =\frac{\beta F\left ( K\right ) -K}{2\left ( 1-\beta \right ) }. \end{equation}

Since $rq\geq \beta ^{-1}$ , the equilibrium capital stock is never larger than $K^{\ast }$ . It follows that $\beta F^{\prime } ( K ) \geq 1$ . The function (23) is strictly concave in $K$ . Hence, any increase in capital accumulation turns directly into a welfare improvement. Since (21) is never smaller than (22) and strictly larger for $\tau \lt 1-\beta$ , it follows immediately that the equilibrium with liquid equity dominates the illiquid one in terms of welfare. We need only to establish that both equilibria exist for the same parameter values, in particular, that there exists a non-empty region of the cost of adopting the technology that allows traders to distinguish genuine from counterfeited equity such that both the liquid and illiquid equilibrium exist. This is what the next Proposition does. Define $\alpha =\alpha \left ( K\right ) \equiv -\frac{f^{\prime \prime }\left ( K\right ) K}{f^{\prime }\left ( K\right ) }$ , as the curvature of the production function. Assume that $\alpha ^{\prime } ( K ) \geq 0$ , taht is the curvature of the production function is non-decreasing in the capital stock.

When all investors adopt the technology that allows to distinguish counterfeits from genuine private securities, these securities are accepted as payment, setting off the pecuniary externality that affects the price and amount of capital traded in the SM; when no investor adopts the technology, instead, the pecuniary externality generates opposite effects. Hence, the strategic complementarity arises from this general equilibrium effect, but one still needs to check that there is indeed a multiplicity of equilibria within the same region of parameters. Since the benefit of adopting the technology for an investor depends both on the price and the amount traded of second hand capital, and these move in opposite directions across the two equilibria, it is key to find out whether the price or quantity effect dominates, that is the elasticity of the benefit, which is controlled by the curvature of the production function. The bound on the curvature of the production function serves precisely to make sure that both equilibria above, with and without liquid securities, exist for the same parameters values. When both equilibria exist, they are immediately Pareto-ordered as capital accumulation is higher at the liquid than illiquid equilibrium. Since capital accumulation, output, welfare, the Tobin’s Q, and leverage are all larger when the equilibrium is liquid than illiquid, it seems appropriate to interpret the former as a boom and the latter as a liquidity crisis.

3.5 Endogenous liquidity cycles

In this model, whether the economy ends up liquid or illiquid and, hence, in a liquidity boom or crisis, depends on how the traders coordinate their expectations over different outcomes. To illustrate this point, we introduce sunspot events in the spirit of Cass and Shell (Reference Cass and Shell1983), namely payoff irrelevant events that can affect the fundamentals only through the agents’ expectations. For concreteness, we limit attention to stationary sunspot events of order two that alternate randomly over time, with the probability that next period the event $s^{\prime }=1,2$ will occur, given that today the event $s=1,2$ has occurred, represented by $\pi _{ss^{\prime }}$ . Suppose that, if the first event occurs, all the investors pay the cost $c$ to activate the verification technology that helps them distinguish between genuine and counterfeit equity, while, if the second event occurs, they do not pay the cost and the technology is not activated. Debt is never used as a payment instrument, due to the legal restriction advocated by Kocherlakota (Reference Kocherlakota2003), but still serves to reallocate money. Define $\mu \equiv ( 1-\tau ) ( 1+x )$ and the indicator function $I_{s}\in \{ 0,1 \}$ with $I_{1}=1$ and $I_{2}=0$ . The equilibrium conditions are the Euler condition for money,

(24) \begin{equation} v_{s}=\frac{\beta }{\mu }\sum _{s^{\prime }=1,2}\pi _{ss^{\prime }}v_{s^{\prime }}\left ( r_{s^{\prime }}+x\right ), \end{equation}

and the Euler condition for capital, that can be rewritten so as to obtain

(25) \begin{equation} q_{s}=\frac{2-\beta \left ( 1-\delta \right ) I_{s}\left ( r_{s}-1\right ) }{\beta \left ( r_{s}+1\right ) }\equiv g_{s}\left ( r_{s}\right ), \end{equation}

for each $s$ . The complementary slackness condition for the liquidity constraint in the LM determines the interest rate, which is either $i_{s}=x$ or $i_{s}=r_{s}$ , for both $s$ . We limit attention to equilibria that are always either constrained or unconstrained in both states. From the binding constraint in the SM, obtain the value of money, $v_{s}=G_{s} ( r_{s} ) ( 4M ) ^{-1}$ , where $G_{s} ( r_{s} ) \equiv f^{\prime -1} ( r_{s}g_{s} ( r_{s} ) -1+\delta ) [ g_{s} ( r_{s} ) - ( 1-\delta ) I_{s} ]$ , for each $s$ . Using this into (24), we obtain the two equilibrium conditions

(26) \begin{equation} G_{s}\left ( r_{s}\right ) =\frac{\beta }{\mu }\sum _{s^{\prime }=1,2}\pi _{ss^{\prime }}\left ( r_{s^{\prime }}+x\right ) G_{s^{\prime }}\left ( r_{s^{\prime }}\right ), \end{equation}

for each $s=1,2$ in the two unknowns, that is the returns in the two sunspot states, $r_{s}$ for $s=1,2$ . The returns need to be different in the two states and larger than or equal to one, to guarantee the incentive to lend money in each state. Next, we define stationary sunspot equilibria.

The following Proposition proves the existence of a sunspot equilibrium.

Since the case with $\pi _{ss^{\prime }}=0$ with $s^{\prime }=s$ for each $s$ is included, this also establishes the existence of a deterministic cycle of period two. Due to the self-fulfilling expectations of the traders, the economy ends up oscillating randomly between good times in which equity is liquid and the economy is booming and bad times in which capital is illiquid and the economy is in the dumps. These situations arise endogenously from the coordination of the agents’ expectations on different scenarios in which equity is perceived as either trustworthy, hence, liquid, or not. Notice that this is not the conventional situation in monetary theory where there is a no-trade equilibrium in which money has no value and another equilibrium with trade and valued money.Footnote ²¹ Here, in both equilibria, money is valued and there is some trade of capital in the SM, but equity may be liquid or not. In turn, this determines whether capital has a liquidity premium, which alters the price of capital with knock-on effects on the capital stock, output, and welfare.

4.1 Subset of instruments

Given the imperfections of the environment, the legal restriction on the use of government bonds in the SM, and the technological restriction on the use of equity in the LM, there are three feasible alternative arrangements, in which either trade in the SM is conducted using only equity, only money, or a combination of money and equity but no bonds. In all three cases, the agents skip trade in the LM and show up directly for trade in the SM. In the first case, the entrepreneurs issue equity on the value of the undepreciated capital stock after production to pay for the acquisition of second hand capital in the SM, without using any other payment instrument. Trade by the entrepreneurs in the SM is subject to the constraint $q\kappa \leq ( 1-\delta ) k$ . We assume that the cost $c$ is not too large to impede the use of equity as the sole means of payment. In the second case, the entrepreneurs pay for the acquisition of second hand capital in the SM with money, without using any other payment instrument. Trade by the entrepreneurs in the SM is subject to the constraint $q\kappa \leq vm$ . In the third case, the entrepreneurs pay for the acquisition of second hand capital in the SM with money and equity. Trade by the entrepreneurs in the SM is subject to the constraint $q\kappa \leq vm+ ( 1-\delta ) k$ . We assume that the cost $c$ is not too large to impede the use of equity as means of payment. We compare the equilibria of these trading arrangements with those examined above according to the ex-ante welfare criterion.

The following result compares the feasible arrangements in terms of ex-ante welfare.

The equilibrium with only equity limits the amount of capital that can be reallocated trading in the SM. This is because the equilibrium price of second hand capital cannot be smaller than 1, since the investors can store capital one-for-one. A price larger than 1, however, is incompatible with the constraint $q\kappa \leq ( 1-\delta ) k$ , since depreciation is non-negative and the amount of capital that is available to be reallocated is $k$ . Therefore, at equilibrium, it has to be that $q=1$ and $\kappa = ( 1-\delta ) k$ . Thus, not all the capital in the hands of the investors is acquired by the entrepreneurs in the SM. This is a distortion relative to efficiency, that requires all the capital to end up in the hands of the entrepreneurs. The traders compensate this distortion accumulating capital above the efficient amount over time. The liquid equilibrium with money, government bonds, and equity outperforms this arrangement at least for $\tau$ not too small, since it reallocates capital properly in the SM, thus, avoiding the overaccumulation of capital over time. As regards the arrangement with money and equity, without the use of bonds in the LM, the liquid equilibrium with money, government bonds, and equity outperforms this arrangement for $\tau$ not too small since it reallocates money according to trading needs and rewards idle money balances with interest using government bonds. The equilibrium of the arrangement with only money being used as payment instrument is dominated by the one with money and equity. This shows that the equilibrium we have identified as a liquidity boom is indeed the best arrangement among those that are feasible given the imperfections of the environment and the existing legal and technical restrictions. Thus, the results do not depend on having selected a dominated arrangement. On the other hand, the illiquid equilibrium at best replicates the arrangement in which only money is used as payment instrument, which shows that this equilibrium can indeed be identified as a liquidity crisis.

4.2 No legal or technical restrictions

Next, we ask what would happen if we were to lift the legal restriction on bonds for their use in the SM and the technological restriction on equity for its use in the LM. To address this question, in the Appendix, we set up a general scheme that captures all the alternative possibilities and compare the ensuing equilibrium allocations and the associated equilibrium welfare. It turns out that the technological restriction on the use of equity in the LM is not crucial for our results, since equity would have a premium even when used as a liquid instrument in the LM. The only difference would be that the premium would be smaller, being discounted by the interest rate. Hence, the price of second hand capital would be larger and the equilibrium allocation worse than the one obtained at the liquid equilibrium above. The question whether the legal restriction imposed on government bonds in the SM is socially beneficial as in Kocherlakota (Reference Kocherlakota2003) is a bit more subtle, since there are four different situations to be compared, when bonds are used in the LM with liquid and illiquid equity and when bonds are used in the SM with liquid and illiquid equity. There exist values of taxation such that the liquid equilibrium when bonds are used in the LM dominates the liquid equilibrium when bonds are used in the SM. The same holds for the illiquid equilibria of the arrangements with bonds in the LM and SM, respectively, provided the bonds to money ratio is not too large. However, the illiquid equilibrium when bonds are used in the LM is dominated by the liquid equilibrium when bonds are used in the SM for all parameter values. Hence, the payment of interest on otherwise idle money balances alone is not enough to generate a welfare improvement in this economy. The presence of a liquidity premium for capital, with the ensuing pecuniary externality generated through the price of second hand capital, is required to obtain a welfare improvement relative to an economy in which the legal restriction on the use of bonds as payment instruments is absent. Overall, the combination of these results confirms that the liquid equilibrium of the arrangement considered above with money, government bonds used in the LM, and equity used in the SM is the best scenario, given the informational imperfections of the environment, while the illiquid equilibrium of the same arrangement may be pretty bad.

5.1 Lump-sum taxation

The fiscal policy parameter, $\tau$ , which represents lump-sum, that is, non-distortionary, taxation, has a positive effect on capital accumulation at both equilibria. Thus, the optimal policy consists in setting $\tau =1-\beta$ , which induces the efficient allocation, $K^{\ast }$ . This corresponds to the so-called Friedman rule. However, the Friedman rule may not be feasible in this environment due to the limitation of enforcement. The ability to tax the traders is limited by the available undepreciated capital stock. The following Proposition determines when the Friedman rule can be achieved or not.

When depreciation is sufficiently close to 1, the undepreciated capital stock is small and lump-sum taxation is severely limited, so that the Friedman rule cannot be achieved. The optimal fiscal policy consists in any case in setting $\tau$ as close as possible to the bound.

5.2 Open market operations

When the ability to tax the traders is limited and, hence, the efficient allocation cannot be achieved through fiscal policy alone, monetary policy may be helpful. One type of monetary policy is captured in the model by changes in the bonds to money ratio, $x$ , which represents open market operations. In both equilibria, with liquid and illiquid equity, the interest rates, and the Tobin’s Q are increasing in $x$ . Hence, there is a liquidity effect of open market operations, as an expansionary open market operation—corresponding to a smaller value of $x$ —lowers the interest rate. Notice that, when the equilibrium is constrained, that is when the bonds to money ratio is relatively small, open market operations affect asymmetrically the interest rate of bonds and capital, while, when the equilibrium is unconstrained, the effect is symmetric. This is broadly consistent with the US evidence over the last thirty years, as the returns of equity, the Bond Bill rate and the Tobin’s Q, all correlate positively with the bond to money ratio.Footnote ²² Leverage, on the other hand, is increasing in $x$ at the liquid equilibrium but insensitive to conventional policy at the illiquid equilibrium. In both equilibria and independently whether the equilibrium is constrained or not, capital accumulation is decreasing in the bonds to money ratio, implying that an expansionary open market operation increases capital accumulation with beneficial effects for output and welfare. This is also broadly consistent with the evidence for the US over the last three decades, as gross physical capital formation in the US has been inversely related to the bond to money ratio since the mid-1990s.Footnote ²³ We summarize the discussion in the next Proposition.

Thus, at any given equilibrium, expansionary open market operations have a liquidity effect and are socially beneficial. This policy is, instead, ineffective in moving the economy from an equilibrium with illiquid capital, that is from a liquidity crisis, to an equilibrium with liquid equity, that is a boom, as reflected in its inability to affect leverage when the economy is in a liquidity crisis. When the economy is stuck at the illiquid equilibrium, the government may consider lifting the legal restriction on the use of bonds as payment instrument. The traders would then be able to replace equity which does not function as payment instrument with a publicly issued instrument, such as government bonds. As can be seen from the analysis in the Appendix, the new equilibrium would give rise to a better allocation of resources relative to the illiquid equilibrium, although not as good as the liquid equilibrium. If used as payment instrument, government bonds would become perfect substitutes of money and, as a consequence, the nominal interest rate would vanish, hitting the zero lower bound. This equilibrium would resemble a liquidity trap, in which, depending on the bonds to money ratio, output, and welfare may be slightly higher than during the crisis but still lower than in normal times, with a zero nominal interest rate and ineffective open market operations.Footnote ²⁴ The economy may end up being stuck at a second-rate equilibrium as a consequence of this policy move.Footnote ²⁵ A better alternative is examined next.

5.3 Credit easing

When the economy is mired in a liquidity crisis, a type of unconventional monetary policy known as credit easing may help rescue the situation. Consider the equilibrium in which the investors do not pay the cost and fail to adopt the technology that allows them to distinguish genuine from counterfeited equity. Suppose that not only the private sector but also the government has access to this technology and its cost is $c\in ( \widehat{c},\widetilde{c} )$ . The government internalizes the benefits for all traders, that is both entrepreneurs and investors, and decides to pay the cost and adopt the technology. At the beginning of every period, the government issues an amount of money, $\overline{m}$ , which is exchanged at current market price, $v$ , for equity issued by the traders against a fraction $\gamma$ of their undepreciated capital holdings. Such an amount is withdrawn from circulation before the end of the period when the capital is bought back by the agents in the PM; hence, this policy does not alter the stock of money over time. In other words, the public authorities acquire some private assets with a temporary injection of liquidity, in a move that resembles what has come to be known as credit easing. The constraint (5) becomes $q\kappa \leq vm+vm^{d}+v\overline{m}$ , with $v\overline{m}=\gamma ( 1-\delta ) k$ . The equilibrium is the same as when equity is liquid, with the price of capital in the SM given by

(27) \begin{equation} q=\frac{2-\gamma z\left ( 1+x\right ) \left ( 1-\delta \right ) }{2\beta +z\left ( 1+x\right ) }, \end{equation}

while the return, $r$ , is still given by (11). This policy makes capital at least partially liquid without generating extra inflationary pressures since the stock of money is not altered further over time. This, in turn, helps the economy move from the inferior equilibrium with illiquid capital to the superior equilibrium with liquid equity. With the right injection of liquidity, the allocation of the dominating equilibrium can be attained. Since (27) is decreasing in $\gamma$ , the rate of return $r$ is unaffected, and the capital stock is decreasing in $q$ , the equilibrium capital stock is increasing in $\gamma$ . Welfare is increasing in the equilibrium capital stock; therefore, it is optimal to set $\gamma$ as high as possible. The next Proposition follows immediately.

In other words, in a liquidity crisis, this unconventional policy reinstates the liquidity premium of capital, giving rise to a pecuniary externality that lowers the price of capital with socially beneficial effects. By restoring the confidence in asset-backed securities, unconventional policy also brings back leverage. This provides a rationale for the purchase of asset-backed private securities by the US Federal Reserve during the 2008 financial crisis. Between the end of 2008 and the beginning of 2009, the balance sheet of the Fed doubled, going from about 1 trillion to 2 trillion dollars.Footnote ²⁶ Over that period of time, the Fed exchanged government liquidity for private assets through various facilities, including the Term Auction Facility, the Primary Dealer Credit Facility, and the Term Securities Lending Facility.Footnote ²⁷ The consensus seems to be that unconventional policy had a positive impact on the US economy. Del Negro, Eggertsson, Ferrero, and Kiyotaki (2017) claim that “the economy may have suffered a second Great Depression in the absence of interventions.”Footnote ²⁸