2.1. Structure of the model

The first studies of climate policies in the context of business cycles, for example, Fischer et al. (Reference Fischer and Springborn2011) and Heutel (Reference Heutel2012), largely abstract from economic frictions and compare policy instruments within RBC frameworks. Subsequent studies, such as Annicchiarico and Di Dio (Reference Annicchiarico and Di Dio2015) build on New Keynesian models and emphasise the importance of nominal rigidities for the evaluation of climate policy instruments. Since the presence of frictions affects the behaviour of firms under uncertainty and generally alters aggregate dynamics, a comprehensive assessment of climate policy instruments should take them into account.

Hence, to shed light on the effects and implications of dynamic climate policy instruments, we use a New Keynesian model that features nominal price-setting rigidities. In addition, to account for other types of imperfections, we introduce nominal wage-setting frictions and investment adjustment costs. In modelling emissions, we follow the approach of Fischer et al. (Reference Fischer and Springborn2011), such that emissions evolve on the firm level from the use of a polluting intermediate input factor. In addition, to capture the adverse effects associated with climate change, we adopt the formalisation of Heutel (Reference Heutel2012) and assume that the emissions stock in the atmosphere causes production losses.Footnote ¹ The public sector is kept rather simple and we assume that the government implements climate policy in the form of a dynamic or a static emissions trading system. Within this framework, we consider four different types of aggregate risk, namely shocks to total factor productivity (TFP), demand shocks, government spending shocks and monetary policy shocks.

2.2. Households and labour markets

The economy is populated by a continuum of households I ∈ [0, 1]. The representative household chooses consumption $ {c}_t $ , investment $ {x}_t $ and labour supply $ {h}_t $ in order to maximise expected lifetime utility:

(1) $$ {E}_0{\sum}_{t=0}^{\infty }{d}_t{\beta}^t\left[\frac{c_t^{1-\rho }}{1-\rho }-\psi \frac{h_t^{1+\chi }}{1+\chi}\right],\hskip0.5em \beta \in \left(0,1\right),\chi >0, $$

where $ \beta $ denotes the discount factor of households, $ \psi $ denotes the disutility from labour, $ \chi $ denotes the inverse Frisch elasticity and $ \rho $ denotes the inverse of the elasticity of intertemporal substitution. In addition, $ {d}_t $ represents a time preference shock that is formulated as an AR(1) process in logarithms and evolves according to $ \ln \left({d}_t\right)={\rho}_d\ln \left({d}_{t-1}\right)+{\epsilon}_{d,t} $ , where $ {\epsilon}_{d,t} $ denotes stochastic innovations. As explained by Gali (Reference Gali2013), these demand shocks are a common feature in New Keynesian models. In particular, shifts in time preferences are often used to capture fluctuations in household demand for consumption goods. Households face the following budget constraint:

(2) $$ {c}_t+{x}_t+{b}_t={\mathcal{W}}_t{h}_t+{R}_{t-1}\frac{b_{t-1}}{\pi_t}+{F}_t+{F}_{u,t}+{R}_{k,t}{k}_t-{T}_t, $$

where $ {\mathcal{W}}_t $ denotes the real remuneration of labour, $ {R}_{k,t} $ denotes the real return of capital, inflation is denoted by $ {\pi}_t={p}_t/{p}_{t-1} $ , $ {b}_t $ denotes the stock of risk-free one-period government bonds, $ {R}_t $ denotes the nominal interest rate and $ {T}_t $ denotes a lump-sum tax. Households own firms and consequently receive profits $ {F}_t $ . In addition, wage markup profits from unions $ {F}_{u,t} $ are transferred to households. As in Christiano et al. (Reference Christiano, Eichenbaum and Evans2005), we introduce convex investment adjustment costs:

(3) $$ {k}_{t+1}=\left[1-\frac{\kappa }{2}{\left(\frac{x_t}{x_{t-1}}-1\right)}^2\right]{x}_t+\left(1-\delta \right){k}_t. $$

Here, $ \kappa $ captures the degree of adjustment costs and $ \delta $ denotes the depreciation rate of physical capital.

The solution of the household problem yields the following first-order conditions for consumption, labour supply, bond holdings, capital and investment:

(4) $$ {\lambda}_t={c}_t^{-\rho }, $$

(5) $$ \psi {h}_t^{\chi }={c}_t^{-\rho }{\mathcal{W}}_t, $$

(6) $$ {\lambda}_t=\beta {R}_t{E}_t\frac{d_{t+1}}{d_t}{\lambda}_{t+1}{\pi}_{t+1}^{-1}, $$

(7) $$ 1={q}_t\left(1-\frac{\kappa }{2}{\left(\frac{x_t}{x_{t+1}}-1\right)}^2-\kappa \left(\frac{x_t}{x_{t-1}}-1\right)\frac{x_t}{x_{t-1}}\right)+\beta {E}_t\frac{d_{t+1}{\lambda}_{t+1}}{d_t{\lambda}_t}{q}_{t+1}\kappa \left(\frac{x_{t+1}}{x_t}-1\right){\left(\frac{x_{t+1}}{x_t}\right)}^2, $$

(8) $$ {q}_t=\beta {E}_t\frac{d_{t+1}}{d_t}\frac{\lambda_{t+1}}{\lambda_t}\left(\left(1-\delta \right){q}_{t+1}+{R}_{K,t+1}\right). $$

Here $ {\lambda}_t $ denotes the marginal utility of an additional unit of consumption and $ {q}_t $ denotes Tobin’s q, which is defined as the value of installed capital relative to new capital. Labour market frictions are introduced through a union setup similar to Erceg et al. (Reference Erceg, Henderson and Levin2000). As in Sims and Wu (Reference Sims and Wu2021), we assume that households supply differentiated labour inputs to a continuum of unions $ u\in \left[0,1\right] $ . Unions sell labour inputs $ {h}_{u,t} $ to a labour packer at the price $ {w}_{u,t} $ and remunerate households. Labour packers bundle differentiated labour inputs according To $ {h}_{d,t}={\left({\int}_0^1{h}_{u,t}^{\left({\eta}_w-1\right)/1} du\right)}^{\eta_w/\left({\eta}_w-1\right)} $ . Labour packers operate under perfect competition and maximize profits, which yields the demand curves for each type of union labour relative to aggregate labour demand of the production sector $ {h}_{d,t} $ :

(9) $$ {h}_{u,t}={\left(\frac{w_{u,t}}{w_t}\right)}^{-{\eta}_w}{h}_{d,t}, $$

where $ {\eta}_w>1 $ The equation should be numbered as (9) denotes the elasticity of substitution between differentiated labour inputs and $ {w}_t $ denotes the aggregate real wage. The aggregate real wage can be derived as $ {w_t}^{1-{\eta}_w}={\int}_0^1{w}_{u,t}^{1-{\eta}_w} du $ . Unions set wages to maximise the income of union members by maximising the transfer $ {F}_{u,t} $ that union members receive. Wage inertia results from a nominal wage adjustment rigidity as in Calvo (Reference Calvo1983).

Every period unions can adjust the wage with probability $ 1-{\theta}_w $ . Given the chance that wages cannot adjust over a prolonged period, unions apply the stochastic discount factor of households $ {\varLambda}_{t,t+k}=\beta {\lambda}_{i,t+k}/{\lambda}_{i,t} $ to maximise the expected present discounted value of their members’ labour income. The optimal reset wage $ {w}_t^{\ast } $ is common across unions and reads:

(10) $$ {w}_t^{\ast }=\frac{\eta_w}{\eta_w-1}\frac{E_t{\sum}_{k=0}^{\infty}\hskip0.3em {\theta}_w^k{\varLambda}_{t,t+k}}{E_t{\sum}_{k=0}^{\infty}\hskip0.3em {\theta}_w^k{\varLambda}_{t,t+k}{w}_{t+k}^{\eta_w}{p}_{t+k}^{-1}{h}_{d,t+k}}. $$

Hence, in the absence of wage adjustment rigidities, unions will set wages as a constant markup $ {\eta}_w/\left({\eta}_w-1\right) $ above the level of competitive wages. Under staggered wage setting, the aggregate real wage can be derived as a weighted average of currently adjusted and previous wages:

(11) $$ {w}_t^{1-{\eta}_w}=\left(1-{\theta}_w\right){w}_t^{\ast 1-{\eta}_w}+{\theta}_w{\pi}_t^{\eta_w-1}{w}_{t-1}^{1-{\eta}_w}. $$

2.3. Firms

Final output $ {y}_t $ is produced under perfect competition. Final goods producers combine intermediate goods $ {y}_{j,t} $ into final goods according to the CES aggregator $ {y}_t={\left({\int}_0^1{y}_{j,t}^{\left(\varepsilon -1\right)/\varepsilon}\; dj\right)}^{\varepsilon /\left(\varepsilon -1\right)} $ , where $ \varepsilon >1 $ , denotes the elasticity of substitution between different varieties of intermediate goods. Profit maximisation of final goods producers yields a downward-sloping demand for intermediate goods $ {y}_{j,t}={\left({p}_{j,t}/{p}_t\right)}^{-\varepsilon }{y}_t $ . The demand for good $ j $ is a decreasing function of the individual goods price $ {p}_{j,t} $ relative to the overall price level of intermediate goods $ {p}_t $ . Given the functional forms, the aggregate price level is defined as $ {p}_t={\left({\int}_0^1{p}_{j,t}^{1-\varepsilon } dj\right)}^{1/\left(1-\varepsilon \right)} $ .

Intermediate goods are produced by a continuum of intermediate goods-producing firms $ j\in \left[0,1\right] $ under monopolistic competition. As in Fischer et al. (Reference Fischer and Springborn2011), we assume that intermediate goods production requires a polluting input factor $ {m}_{j,t} $ , which firms buy on international markets at the price $ {p}_{m,t} $ . In particular, we assume that the Cobb–Douglas production function has constant returns to scale:

(12) $$ {y}_{j,t}=\left(1-\varOmega \left({s}_t\right)\right){A}_t{k}_{j,t}^{\alpha }{h}_{j,t}^{1-\alpha -\gamma }{m}_{j,t}^{\gamma },\hskip1em 0<\alpha <1,\hskip1em 0<\gamma <1, $$

where $ {A}_t $ represents TFP. The dynamics of TFP are given by $ \ln \left({A}_t\right)={\rho}_a\ln \left({A}_{t-1}\right)+{\epsilon}_{a,t} $ , where $ {\rho}_a $ denotes the autocorrelation of the AR(1) process and $ {\epsilon}_{a,t} $ denotes i.i.d. innovations in productivity that are assumed to be normally distributed. The parameters $ \gamma $ and $ \alpha $ denote the output elasticities with respect to the polluting intermediate input and to physical capital, respectively. The production losses associated with climate change are captured via $ \left(1-\varOmega \left({s}_t\right)\right) $ , where $ {s}_t $ denotes the stock of pollution in the atmosphere. Here, we assume that the stock of pollution evolves according to $ {s}_t=\left(1-{\delta}_s\right){s}_{t-1}+e{m}_t+e{m}_t^w. $ The decay of atmospheric pollution is denoted by $ {\delta}_s,e{m}_t^w $ denotes emissions of the rest of the world, and for simplicity, we assume that the domestic flow of emissions $ e{m}_t $ is proportional to the aggregate utilisation of polluting inputs $ e{m}_t={m}_t={\int}_0^1{m}_{j,t}\; dj. $ With respect to the damages of climate change, we assume that the damage function is convex and given by $ \varOmega \left({s}_t\right)={\omega}_0+{\omega}_1{s}_t+{\omega}_2{s}_t^2 $ .

Since intermediate goods-producing firms take factor prices as given, cost minimization yields the following optimality conditions for factor inputs:

(13) $$ {R}_{k,t}=m{c}_{j,t}\alpha \left(1-\varOmega \left({s}_t\right)\right){A}_t{k}_{j,t}^{\alpha -1}{h}_{j,t}^{1-\alpha -\gamma }{m}_{j,t}^{\gamma }, $$

(14) $$ {w}_t=m{c}_{j,t}\left(1-\alpha -\gamma \right)\left(1-\varOmega \left({s}_t\right)\right){A}_t{k}_{j,t}^{\alpha }{h}_{j,t}^{-\alpha -\gamma }{m}_{j,t}^{\gamma }, $$

(15) $$ {\hat{p}}_{e,t}=m{c}_{j,t}\gamma \left(1-\varOmega \left({s}_t\right)\right){A}_t{k}_{j,t}^{\alpha }{h}_{j,t}^{1-\alpha -\gamma }{m}_{j,t}^{\gamma -1}, $$

where $ m{c}_{j,t} $ denotes the marginal costs of the firm, specifically the cost of producing an additional unit of output. $ {\hat{p}}_{e,t} $ denotes the price of the polluting intermediate input including the emissions price. It is important to emphasise that we assume that individual firms ignore climate damages in their optimal choice of the polluting intermediate input. This assumption seems warranted given the coordination problem associated with the common good characteristics of global climate. Since conditions (13)–(15) are symmetric across firms, all firms choose the same capital-labour and intermediate inputs-labour ratios, so that marginal costs are the same for all firms, that is, $ m{c}_{j,t}=m{c}_t, $ given by:

(16) $$ m{c}_t={\left(\frac{1}{1-\alpha -\gamma}\right)}^{1-\alpha -\gamma }{\left(\frac{1}{\alpha}\right)}^{\alpha }{\left(\frac{1}{\gamma}\right)}^{\gamma}\frac{w_t^{1-\alpha -\gamma }{R}_{k,t}^{\alpha }{\hat{p}}_{e,t}^{\gamma }}{\left(1-\varOmega \left({s}_t\right)\right){A}_t}. $$

Intermediate goods producers set the price of intermediate goods $ {p}_{j,t} $ in order to maximise discounted real profits. Since households own firms, they apply the stochastic discount factor of households defined as $ {\varLambda}_{t,t+i}=\beta {\lambda}_{t+i}/{\lambda}_t. $ As in Calvo (Reference Calvo1983), we assume that every period only a fraction $ \left(1-{\theta}_p\right) $ of firms can adjust prices, while the other firms remain at their previously chosen prices. Hence, the optimal reset price $ {p}_t^{\ast } $ is given by:

(17) $$ {p}_t^{\ast }={p}_{j,t}=\frac{\varepsilon }{\left(\varepsilon -1\right)}\frac{E_t{\sum}_{i=0}^{\infty }{\theta}_p^i{\varLambda}_{t,t+i}{p}_{t+i}^{\varepsilon }{y}_{t+i}m{c}_{t+i}}{E_t{\sum}_{i=0}^{\infty }{\theta}_p^i{\varLambda}_{t,t+i}{p}_{t+i}^{\varepsilon -1}{y}_{t+i}}. $$

In the absence of price-setting frictions ( $ {\theta}_p=0 $ ), firms charge a constant markup $ \varepsilon /\left(\varepsilon -1\right)>1 $ over marginal costs. For $ {\theta}_p>0, $ the aggregate price level evolves as $ {p}_t={\left[\left(1-{\theta}_p\right){p}_t^{\ast 1-\unicode{x025B}}+{\theta}_p{p}_{t-1}^{1-\varepsilon}\right]}^{1/\left(1-\varepsilon \right)}. $ This can be rewritten in terms of inflation as $ 1=\left(1-{\theta}_p\right){\pi}_t^{\ast 1-\varepsilon }+{\theta}_p{\pi}_t^{\unicode{x025B} -1}, $ where $ {\pi}_t={p}_t/{p}_{t-1} $ and $ {\pi}_t^{\ast }={p}_t^{\ast }/{p}_t. $ Furthermore, we can define the dispersion of intermediate goods prices as $ {v}_t^p=\left(1-{\theta}_p\right){\pi}_t^{\ast -\unicode{x025B}}+{\theta}_p{\pi}_t^{\varepsilon }{v}_{t-1}^p $ .

2.4. Environmental policies, public sector and market clearing

Finally, we turn to the implementation of environmental policies within the model. As is common, we model climate policies in a polluter-pays fashion and assume that intermediate goods-producing firms face a cap $ \overline{em} $ on emissions. This implies that at the aggregate level, the utilisation of polluting intermediate inputs cannot exceed the cap, that is, $ {m}_t\le \overline{em}. $ Footnote ² We assume that intermediate goods producers trade permits in a perfectly competitive market. Hence, the permit price will correspond to the shadow value of an additional permit resulting from the optimization of firms under the emission constraint. From the firm’s perspective, the price of the polluting intermediate input $ {\hat{p}}_{e,t} $ can be decomposed into the constant component $ {p}_m $ and the environmental component $ {p}_{e,t}. $

Since the goal of this study is to evaluate the performance of flexible emissions reduction policies, we consider a reaction function which defines a flexible emissions cap:

(18) $$ \overline{e{m}_t}=\overline{em}+{\nu}_e\left(\frac{p_{e,t}}{\overline{p_e}}-1\right), $$

here $ {\nu}_e $ denotes a reaction parameter that determines how strongly the number of emissions allowances adjusts in response to deviations of emissions prices from the price target $ {\overline{p}}_e. $ The case of $ {\nu}_e=0 $ represents the classical fixed cap-and-trade system as modelled by Annicchiarico and Di Dio (Reference Annicchiarico and Di Dio2015) or Heutel (Reference Heutel2012). In this situation, the number of emissions permits is constant and does not adjust in response to economic fluctuations.Footnote ³ With a dynamic adjustment of the cap ( $ {\unicode{x03BD}}_e>0 $ ), emissions are still limited but allowed to vary with the economic situation. The regulation function, as depicted in (18), implies an increase in the emissions cap when the market price of permits increases above its target value $ {\overline{p}}_e. $ Conversely, the number of permits is reduced whenever the price of emissions falls below the target. This design choice corresponds to the idea proposed by Heutel (Reference Heutel2012) to allow for pro-cyclical adjustments of the policy instruments.

To illustrate the general idea, it is helpful to abstract from the described frictions and to compare the constant rule (blue line) to the dynamic rule (orange line) in a static price-quantity diagram. Figure 1 depicts both regimes at three different demand levels (dashed lines). The demand schedule D depicts a situation where both policies lead to the same price-quantity relation. Unsurprisingly, inelastic permit supply leads to larger price variations compared to the dynamic rule. This is evident for schedule $ \overline{D} $ , where the increase in the price of permits is larger under the constant rule. Since the number of permits increases under the dynamic rule, the price increase is dampened. This stylised illustration reveals that the dynamic rule can also be viewed as a cap-and-trade system with a price range that depends on the reaction parameter $ {\unicode{x03BD}}_e $ . As emphasised by Koch et al. (Reference Koch, Fuss, Grosjean and Edenhofer2014), such a mechanism can potentially reduce distortions in permit markets.Footnote ⁴

Figure 1. Stylised representation of the permit market under a constant cap and a dynamic cap regime.

The government sector is kept simple: the government finances its spending $ {g}_t $ via issuing debt $ {b}_t $ and through lump-sum taxes $ {T}_t $ . In addition, the government receives the revenues from issuing permits $ {p}_{e,t}e{m}_t $ . In real terms, the government flow budget constraint is given by:

(19) $$ {g}_t+{R}_{t-1}{b}_{t-1}/{\pi}_t={b}_t+{T}_t+{p}_{e,t}e{m}_t. $$

To ensure the long-run sustainability of government debt, the government follows the fiscal rule:

(20) $$ {T}_t=\overline{T}+{\phi}_T\left({b}_t-\overline{b}\right), $$

where $ \overline{T} $ denotes steady state lump-sum taxes and $ {\phi}_T $ captures the intensity of adjustments in taxes in response to deviations of the stock of government debt from the debt target $ \overline{b} $ . Similar to the formulation of Perotti (Reference Perotti1999), government expenditures are stochastic and given by:

(21) $$ \ln \left({g}_t\right)=\left(1-{\rho}_g\right)\ln \left(\overline{g}\right)+{\rho}_g\ln \left({g}_{t-1}\right)+{\epsilon}_{g,t}. $$

Here, $ \overline{g} $ denotes an exogenous target of government consumption. The parameter $ {\unicode{x03C1}}_g $ captures the persistence of i.i.d. innovations in government consumption, denoted by $ {\epsilon}_{g,t} $ . Accordingly, government expenditures will be subject to stochastic fluctuations around the target $ \overline{g} $ .

Monetary policy is conducted by the central bank, which has the objective to maintain price stability and reacts to deviations of inflation from inflation target $ \overline{\pi} $ . We assume that the central bank applies the simple Taylor rule:

(22) $$ \frac{R_t}{\overline{R}}={\left(\frac{R_{t-1}}{\overline{R}}\right)}^{\gamma_R}{\left(\frac{\pi_t}{\overline{\pi}}\right)}^{\gamma_{\pi}\left(1-{\gamma}_R\right)}\exp \left({\epsilon}_{R,t}\right). $$

Here, $ {\gamma}_{\pi } $ denotes the coefficient that captures the reaction of the central bank to deviations of inflation from the inflation target and $ {\gamma}_R $ captures the persistence in nominal interest rates. The steady state nominal interest rate is denoted by $ \overline{R} $ and $ {\epsilon}_{R,t} $ denotes stochastic innovations in the nominal rate.

Finally, in equilibrium factor and goods markets clear. Clearing for capital and intermediate input markets implies: $ {k}_t={\int}_0^1{k}_{j,t}\; dj $ and $ {m}_t={\int}_0^1{m}_{j,t}\; dj $ . Taking the demand for intermediate goods into account, integration yields $ {\int}_0^1{y}_{j,t}\; dj={\int}_0^1{\left(\frac{p_{j,t}}{p_t}\right)}^{-\varepsilon }{y}_t\; dj={y}_t{v}_t^p $ , where $ {v}_t^p $ evolves dynamically as defined above. Aggregate final output can thus be written as:

(23) $$ {y}_t=\left(1-\varOmega \left({s}_t\right)\right){A}_t{k}_t^{\alpha }{h}_t^{1-\alpha -\gamma }{m}_t^{\gamma }/{v}_t^p. $$

In equilibrium, we find that $ {v}_t^p>1 $ if $ {\theta}_p>0 $ , which reflects the inefficiency of aggregate output associated with price rigidity. The resource constraint of the economy requires:

(24) $$ {y}_t={x}_t+{c}_t+{g}_t+{p}_{m,t}{m}_t. $$

From the demand function for differentiated labour (9) in combination with aggregate labour supply given by $ {\int}_0^1{h}_{u,t}\; du={h}_t $ , we get $ {h}_t={h}_{d,t}{v}_t^w $ , where $ {v}_t^w $ denotes wage dispersion. By definition we have $ {v}_t^w={\int}_0^1{\left(\frac{w_{u,t}}{w_t}\right)}^{-{\eta}_w}\; du $ , such that the dynamics of wage dispersion are described by:

(25) $$ {v}_t^w=\left(1-{\theta}_w\right){\left(\frac{w_t^{\ast }}{w_t}\right)}^{-{\eta}_w}+{\theta}_w{\pi}_t^{\eta_w}{\left(\frac{w_t}{w_{t-1}}\right)}^{\eta_w}{v}_{t-1}^w. $$