2.1. Supporting the environmental campaign

We first consider the environmental campaign. Our modelling strategy draws insights from social psychology and in particular from the Norm-Activation Theory (Schwartz, Reference Schwartz1970, Reference Schwartz1977), one of the most widely accepted and empirically supported theories of moral motivation. According to this theory, the activation of personally held moral norms influences pro-environmental behavior. As extensively reviewed by Turaga et al. (Reference Turaga, Howarth and Borsuk2010: 212), the activation of personal norms is based on two preconditions: ‘the individual must be aware that her action has consequences for the welfare of others [...] and the individual must feel a personal responsibility to undertake that action.’ Formally, we assume that the policy maker can activate these personal moral norms to pro-environmental behavior by engaging in a costly awareness campaign. In particular, the campaign is capable of creating a bad conscience for brown consumers while at the same time rewarding green consumers for taking eco-friendly actions.Footnote ⁹ Accordingly, a consumer of type θ∈[0, Θ] has the following utility:

(1) $$U(\theta) = \left\{\matrix{\theta q_{H} - p_{H} + \gamma (q_{H} - q_{L}) &\hbox{if she buys the green good}, \hfill \cr \theta q_{L} - p_{L} - \gamma (q_{H} - q_{L}) \hfill &\hbox{if she buys the brown good}, \hfill \cr 0 \hfill &\hbox{if she refrains from buying}, \hfill} \right.$$

where q _H >q _L indicates the environmental qualities of the two goods, whose prices are respectively indicated with p _H and p _L .

The above representation does not directly include pollution. However, compared to the standard model of vertical differentiation (Gabszewicz and Thisse, Reference Gabszewicz and Thisse1979), the utility from buying good i={H, L} is modified by introducing the term γ (q _i −q _j ) with i≠j. It follows that the satisfaction deriving from a product variant can be either amplified or decreased by the environmental characteristics of i as compared to j. The intensity of such relative preferences is measured by γ≥0. The stronger the policy maker's support for the campaign, the higher the value of γ, and thus the higher the impact of the moral component of consumption. On the contrary, when γ→0 we revert to the standard vertical differentiation model. In other words, the campaign represents an indirect approach to fighting pollution emissions by encouraging consumers to increase the consumption of the green good, thus generating a green expansion effect.Footnote ¹⁰

The consumer indifferent between buying the low-quality good and not buying at all is:

$$\theta _{L} = {p_{L} + \gamma (q_{H}-q_{L}) \over q_L},$$

while the consumer indifferent between buying the low- and the high-quality good is:

$$\theta _{H} = {p_{H} - p_{L} - 2\gamma (q_{H} - q_{L}) \over q_{H} - q_{L}}.$$

The demands for the two goods are formally written as: $x_{L} = \theta_{H} - \theta_{L}$ and $x_{H} = \Theta - \theta_{H}$ .Footnote ¹¹ Compared to the traditional setting (γ=0), here at given prices the market share of H increases in γ at the expense of that of L, as θ _H shifts leftward, while θ _L shifts rightward. The green expansion effect consists of a pure stealing effect, as some consumers switch from the brown to the green good. As we assumed that a constant marginal cost c>0 only applies to the production of the green good, profits are given by $\pi _{H}=x_{H}(p_{H}-c)$ and $\pi_{L}=p_{L}x_{L}$ . Additional conditions on c and γ will be specified below.

Proceeding by backward induction, we solve the price competition stage and derive the main results, which are valid for any quality configuration. Using First Order Conditions (FOCs)\reversemarginpar equilibrium prices as a function of qualities are:

$$\eqalign{p_{L}^{\ast E} &= {q_{L}[c + \Theta (q_{H} - q_{L})] - 2\gamma q_{H} (q_{H} - q_{L}) \over 4q_{H}-q_{L}}, \cr p_{H}^{\ast E} &= {2cq_{H} + (q_{H} - q_{L}) [2 \Theta q_{H} + \gamma (3q_{H} - q_{L})] \over 4q_{H} - q_{L}},}$$

where additional superscript E indicates that we are considering environmental qualities.Footnote ¹² Both demands are positive if $p_{H}^{\ast E} \gt p_{L}^{\ast E}$ . If instead $p_{H}^{\ast E} \leq p_{L}^{\ast E}$ , then the demand for the low-quality good would be zero (x _L =0) while that for the high-quality good would be $x_{H} = \Theta - {p_{L}+\gamma (q_{H}-q_{L}) \over q_{L}}$ . We consider the case in which both firms are active in the market. This requires the conditions provided in the following lemma to hold. Define:

(2) $$\underline{\Theta}^{E}\equiv {c(2q_{H} - q_{L}) \over 2q_{H} (q_{H} - q_{L})}, \quad \overline{\gamma }^{E}\equiv {q_{L}[c + \Theta (q_{H} - q_{L})] \over 2q_{H}(q_{H} - q_{L})}$$

We assume that the conditions reported in Lemma 1 hold throughout the paper. They indicate that a sufficiently large consumer heterogeneity together with a non-excessive level of the moral component of consumption activated by the campaign are required for both firms to coexist in the market. We limit our attention to such a case as we want to reproduce a concrete situation where polluting firms compete in the market with non-polluting ones. Equilibrium demands/outputs are:

$$\eqalign{x_{L}^{\ast E} &= {q_{H}\{q_{L}[c+\Theta (q_{H}-q_{L})]-2\gamma q_{H}(q_{H}-q_{L}) \} \over (q_{H}-q_{L})(4q_{H}-q_{L}) q_{L}}, \cr x_{H}^{\ast E} &= {[\gamma (3q_{H}-q_{L}) +2\Theta q_{H}](q_{H}-q_{L}) -c(2q_{H}-q_{L}) \over (q_{H}-q_{L}) (4q_{H}-q_{L})}.}$$

Notice that $x_{L}^{\ast E}$ decreases with γ, while $x_{H}^{\ast E}$ increases with γ. However, $\partial (x_{H}^{\ast E} + x_{L}^{\ast E})/\partial \gamma \lt 0$ : total output diminishes with γ, as expected. This reveals that, in the case of environmental qualities, the campaign gives rise to the classical tradeoff between output provision and pollution abatement that often characterizes the complex relationship between environmental and competition policies. We will come back to this point when considering hedonic qualities. Equilibrium profits are given by:

$$\pi_{L}^{\ast E} = {q_{L} \over q_{H}} (q_{H} - q_{L}) (x_{L}^{\ast E})^{2}, \pi_{H}^{\ast E} = (q_{H} - q_{L}) (x_{H}^{\ast E})^{2}.$$

The social welfare as a function of γ is written in a compact way as:

$$SW^{\ast E}(\gamma) =\pi _{L}^{\ast E}+\pi _{H}^{\ast E}+CS_{L}^{\ast E}+CS_{H}^{\ast E}-e\cdot x_{L}^{\ast E}-s {\gamma ^{2} \over 2},$$

where $e\cdot x_{L}^{\ast E}$ is the environmental damage, while $s {\gamma^{2} \over 2}$ is the cost for the campaign, which is assumed to be convex in γ.Footnote ¹³ This captures the idea that it is increasingly costly for the policy maker to affect consumers’ preferences through the comparative information provided by the campaign.Footnote ¹⁴ Parameter s>0 is inversely related to the effectiveness of the campaign effort. The social welfare is concave in γ only for sufficiently high values of s. In particular, this requires:

(3) $$s \gt {(q_{H} - q_{L}) \lpar 12q_{H}^{3} + 19q_{H}^{2}q_{L} - 13q_{H} q_{L}^{2} + 2q_{L}^{3}\rpar \over q_{L} \lpar 4q_{H} - q_{L} \rpar ^{2}} \equiv \underline{s}.$$

We assume that $s \gt \underline{s}$ and compute the optimal level of γ that maximizes social welfare:Footnote ¹⁵

(4) $$\gamma^{\ast E}= {\matrix{2eq_{H}^{2}(4q_{H}-q_{L}) +q_{L}[2c(6q_{H}q_{L}-10q_{H}^{2}-q_{L}^{2})\cr[3pt] +\,\Theta q_{H}(8q_{H}-3q_{L}) (q_{H}-q_{L}) ]} \over sq_{L}(4q_{H}-q_{L})^{2}-(q_{H}-q_{L}) (12q_{H}^{3}+2q_{L}^{3}-13q_{H}q_{L}^{2}+19q_{H}^{2}q_{L})}.$$

Taking into account that $\gamma ^{\ast E}$ has to be non-negative and that the conditions reported in Lemma 1 have to be satisfied, we find:

Hence, the optimal policy is γ=0 as long as the emission level is very low, since the positive effect resulting from the emission reduction does not compensate for the cost of the campaign. In contrast, for very high values of the emission, the policy maker sets $\gamma =\overline{\gamma }^{E}$ , the expression of which is reported in (2). Only for intermediate levels of e is the optimal policy given by $\gamma =\gamma ^{\ast E}$ . The previous discussion is summarized into:

2.2. Taxing the polluting good

Let us now consider the traditional taxation instrument. According to social psychology (e.g., Frey, Reference Frey1997; Turaga et al., Reference Turaga, Howarth and Borsuk2010) as well as being widely discussed in the public economic literature (e.g., Brekke et al., Reference Brekke, Kverndokk and Nyborg2003; Nyborg et al., Reference Nyborg, Howarth and Brekke2006), when the government adopts a direct taxation policy to reduce pollution, the influence of moral motivation can decrease.Footnote ¹⁶ Accordingly, we assume that when the policy maker decides to levy a tax proportional to the polluting emission on the brown firm, then the pro-environmental component of consumption is not relevant, i.e., $\gamma \rightarrow 0$ .Footnote ¹⁷ Formally, inserting γ=0 in (1) is equivalent to considering a standard vertical differentiation model, where $\theta_{L} = p_{L}/q_{L}$ is the consumer indifferent between buying the low-quality good and not buying at all, while $\theta _{H} = (p_{H} - p_{L})/q_{H} - q_{L}$ is the consumer indifferent between buying the low- and the high-quality good. Demands are given by $x_{L} = \theta_{H} - \theta_{L}$ and $x_{H} = \Theta - \theta_{H}$ .

The green good is produced at cost c, whereas the polluting good is subject to a per-unit tax t. Thus, t can be interpreted as the tax differential between the two firms, while c represents the marginal production cost differential. Profit functions are therefore $\pi_{L} = (p_{L} - t) x_{L}$ and $\pi_{H} = (p_{H} - c) x_{H}$ . Price competition yields:

$$\eqalign{p_{H}^{\ast \ast E} &= {q_{H}[2c + t + 2\Theta (q_{H} - q_{L})] \over 4q_{H} - q_{L}} \gt 0, \cr p_{L}^{\ast \ast E} &= {cq_{L} + 2tq_{H} + q_{L} \Theta (q_{H} - q_{L}) \over 4q_{H} - q_{L}} \gt 0.}$$

Let us now define:

(5) $$\overline{t}^{E}\equiv {q_{L}[c + \Theta (q_{H} - q_{L})] \over (2q_{H} - q_{L})}.$$

We assume that the conditions reported in Lemma 3 hold throughout the paper. They indicate that a sufficiently large consumer heterogeneity together with a non-excessive taxation are required for both firms to coexist in the market. Equilibrium demands are:

$$\eqalign{x_{L}^{\ast \ast E} &= {q_{H}\lsqb cq_{L}-t\lpar 2q_{H}-q_{L}\rpar +\Theta q_{L}(q_{H}-q_{L})\rsqb \over (q_{H}-q_{L}) \lpar 4q_{H}-q_{L}\rpar q_{L}}, \cr x_{H}^{\ast \ast E} &= {2\Theta q_{H}(q_{H}-q_{L})-c(2q_{H}-q_{L})+tq_{H} \over \lpar 4q_{H}-q_{L}\rpar (q_{H}-q_{L})}.}$$

Notice that $\partial x_{L}^{\ast \ast E}/\partial t \lt 0$ and $\partial x_{H}^{\ast \ast E}/\partial t \gt 0$ , as expected. Moreover, $\partial (x_{H}^{\ast \ast E} + x_{L}^{\ast \ast E})/\partial t \lt 0$ : total output decreases with t, and consumer surplus is therefore negatively affected by environmental taxation. Equilibrium profits are given by:

$$\pi _{L}^{\ast \ast E} = {q_{L} \over q_{H}} (q_{H} - q_{L}) \lpar x_{L}^{\ast \ast E}\rpar ^{2}, \pi_{H}^{\ast \ast E} = (q_{H} - q_{L}) \lpar x_{H}^{\ast \ast E} \rpar ^{2}.$$

Social welfare as a function of t can be written in a compact form as:

$$SW^{\ast E} (t) = \pi_{L}^{\ast \ast E} + \pi_{H}^{\ast \ast E} + CS_{L}^{\ast \ast E} + CS_{H}^{\ast \ast E} - e\cdot x_{L}^{\ast \ast E} + t\cdot x_{L}^{\ast \ast E}.$$

Algebraic calculations show that it is concave in t. The optimal tax rate is:

(6) $$t^{\ast E} = {e\lpar 4q_{H} - q_{L}\rpar \lpar 2q_{H} - q_{L} \rpar + q_{L} [\Theta q_{L} (q_{H} - q_{L}) - 2c \lpar 2q_{H} - q_{L} \rpar ] \over q_{H} \lpar 4q_{H} - 3q_{L} \rpar }.$$

Taking into account that t* ^E has to be non-negative, and that the conditions from Lemma 3 have to be satisfied, we demonstrate that:

For low values of e, the optimal tax is set to zero because the negative effect on output is in absolute value stronger than the positive effect obtained by reducing pollution emissions. On the contrary, for high values of e, the optimal tax is $\overline{t}^{E}$ – whose value is expressed in (5) – and the profit of the low brown quality firm tends to zero. However, it is relatively easy to demonstrate that the government would prefer to leave an $\varepsilon \rightarrow 0$ to the polluting firm, and then still have a duopoly, instead of pushing it off the market. We summarize the optimal tax policy in the following remark:

Remark 2 confirms that the optimal tax rate is non-decreasing in the intensity of polluting emissions captured by parameter e.

2.3. Comparing the two instruments under environmental qualities

We compare the social efficiency of taxation vs. campaign to find out which policy instrument should be adopted by the policy maker. First of all, we need to rank the threshold values of e that define the regions where different levels of social welfare occur. In the appendix we detail all the possible cases and evaluate the relative comparisons. The following proposition summarizes the most important results. Let

$$\eqalign{\Theta_{1}&= {2c(28q_{H}^{4}-53q_{H}^{3}q_{L}+36q_{H}^{2} q_{L}^{2}-10q_{H}q_{L}^{3}+q_{L}^{4}) \over q_{H}\lpar 4q_{H}-3q_{L}\rpar (q_{H}-q_{L}) (10q_{H}^{2}-6q_{H}q_{L}+q_{L}^{2})},\cr \Theta _{2}&= {2c\lpar 2q_{H}-q_{L}\rpar ^{2} \over q_{H}\lpar 4q_{H}^{2}-7q_{H}q_{L}+3q_{L}^{2}\rpar}, \hbox{with}\,\Theta_{1} \lt \Theta_{2}.}$$

The above proposition reveals that an indirect instrument such as an environmental campaign can be more efficient than a direct tax levied on the brown good. The two preconditions for this to occur are: (i) the cost of the campaign is not too excessive, and (ii) the average valuation of the environmental quality in the market is sufficiently high ( $\Theta \geq \Theta _{1}$ ). While the first precondition is trivial, the second one is less obvious. In particular, it highlights that the green expansion effect of the environmental campaign increases in Θ: the higher the average valuation for the environmental quality, the larger the number of consumers willing to buy the green good. For a given cost s, an increase in Θ improves the effectiveness of the campaign in inducing some consumers to switch from the brown to the green product, thereby reducing the polluting emissions.

More precisely, for relatively low values of Θ ( $\Theta \leq \Theta_{1}$ ), the green expansion effect is almost irrelevant, and taxing the polluting product is preferred from the social standpoint. In contrast, for high values of Θ ( $\Theta \geq \Theta _{2}$ ), such an effect becomes crucial and the campaign turns out to be more efficient than the tax, provided that its cost is not exaggerated. Finally, when $\Theta \in (\Theta_{1},\Theta_{2}) $ , the green expansion effect takes intermediate values and the comparison between the two instruments includes more elements which tend to either reinforce or stifle the relevancy of such an effect. Again, taxation prevails when s is high. On the contrary, when the campaign is relatively affordable, we find that the quality ratio q _H /q _L may compensate for Θ. In particular, when q _H /q _L is sufficiently high, i.e., the brown good is very distant from the green one in terms of the quality valued by environmentally concerned consumers, then the campaign can be welfare improving as compared to the tax instrument, especially if e exceeds a certain value.Footnote ¹⁸ The explanation relies on the fact that a relatively inexpensive campaign can reduce the consumption of a good whose (environmental) quality is very low, and this becomes even more relevant when the polluting emission that it releases is considered as extremely dangerous.

3.1. Supporting the environmental campaign

Consider first the environmental campaign. As introduced before, a new term appears in the indirect utility, namely γ>0, which multiplies the quality gap. This time, however, activating relative preferences implies a reduction in the utility from buying the high (but brown) quality good and a simultaneous increase in the utility from buying the low (but green) quality one. Hence, consumers experience a conflict between their initial valuation of quality and the relative preferences. Formally, this is represented by the following utility for a consumer of type $\theta \in [0,\Theta]$ :

$$U(\theta) = \left\{\matrix{\theta q_{H} - p_{H} - \gamma (q_{H}-q_{L}), \hfill & \hbox{if she buys the high-quality good}, \hfill \cr \theta q_{L}-p_{L}+\gamma (q_{H}-q_{L}), \hfill & \hbox{if she buys the low-quality good}, \hfill \cr 0, \hfill & \hbox{if she refrains from buying.}\hfill}\right.$$

The hedonic qualities of the two goods are indicated by q _H >q _L . Parameter θ now measures consumers’ valuation for the hedonic quality, and Θ>0 captures consumer heterogeneity as well as the average valuation of the hedonic quality in the market.

Indifferent consumers are respectively given by:

$$\theta_{L} = {p_{L} - \gamma (q_{H} - q_{L}) \over q_{L}}, \theta_{H} = {p_{H} - p_{L} + 2\gamma (q_{H} - q_{L}) \over q_{H} - q_{L}}.$$

Demands are again $x_{L} = \theta_{H} - \theta_{L}$ and $x_{H} = \Theta - \theta_{H}$ . Notice that, given prices, the market share of the green firm L increases in γ. This happens for two reasons. On the one hand, the consumer indifferent between not buying at all and buying the low quality (θ _L ) shifts leftward. On the other hand, the consumer indifferent between buying the low quality and the high quality (θ _H ) shifts rightward. In the case of hedonic qualities, the green expansion effect does not consist only of gaining market share at the expense of the brown rival (stealing effect), but it also includes a market coverage effect. This latter effect refers to the fact that some consumers who were not buying in the absence of the campaign are now willing to buy the good L. Hence, contrary to the previous scenario, the market can (hypothetically) be covered, as the consumer of type θ=0 may have a positive utility from buying good L if $\gamma (q_{H} - q_{L}) \gt p_{L}$ . However, we can show that this is not compatible with p _H >p _L .Footnote ¹⁹ We focus therefore on the uncovered market situation, although the market coverage increases in γ (θ _L moves to the left).

Producing the low-quality (green) good still requires a per-unit cost $c>0$ , while the high-quality (brown) is produced at zero cost.Footnote ²⁰ According to the previous discussion, profit functions can be expressed as $\pi _{H}=x_{H}\cdot p_{H}$ and $\pi _{L}=\lpar p_{L}-c\rpar x_{L}.$ Equilibrium prices can be easily obtained:

$$\eqalign{p_{L}^{\ast H}&= {2cq_{H}+(q_{H}-q_{L}) \lpar 2\gamma q_{H}+\Theta q_{L}\rpar \over 4q_{H}-q_{L}},\cr p_{H}^{\ast H}&= {cq_{H}+(q_{H}-q_{L}) \lsqb 2\Theta q_{H}-\gamma (3q_{H}-q_{L})\rsqb \over 4q_{H}-q_{L}},}$$

where additional superscript H indicates hedonic qualities. Let us now define:

(7) $$\eqalign{\underline{\Theta}^{H} &\equiv {c(2q_{H} - q_{L}) \over q_{L}(q_{H} - q_{L})}, \cr \overline{\gamma}^{H} &\equiv \min \left\{{\Theta (2q_{H}-q_{L}) (q_{H}-q_{L}) -cq_{H} \over (5q_{H} - q_{L}) (q_{H} - q_{L})}, {2cq_{H}+\Theta (q_{H}-q_{L}) q_{L} \over \lpar 2q_{H} - q_{L} \rpar (q_{H} - q_{L})} \right\}\!.}$$

We assume that the conditions reported in Lemma 5 hold throughout the paper. Equilibrium demands and profits are then easily found:

$$\eqalign{x_{L}^{\ast H} &= {q_{H}\lsqb (q_{H}-q_{L}) \lpar 2\gamma q_{H}-q_{L}\rpar -c\lpar 2q_{H}-q_{L}\rpar \rsqb \over q_{L}\lpar 4q_{H}-q_{L}\rpar (q_{H}-q_{L}) }, x_{H}^{\ast H} = {p_{H}^{\ast H} \over (q_{H}-q_{L})}; \cr \pi _{L}^{\ast H} &= {q_{L} \over q_{H}} (q_{H}-q_{L}) \lpar x_{L}^{\ast H}\rpar ^{2}, \pi _{H}^{\ast H}= {\lpar x_{H}^{\ast H}\rpar^{2} \over (q_{H}-q_{L})}.}$$

By construction, $\partial x_{L}^{\ast H}/\partial \gamma \gt 0$ and $\partial x_{H}^{\ast H}/\partial \gamma \lt 0$ . However, differently from the previous case, total output increases in γ, as $\partial (x_{L}^{\ast H}+x_{H}^{\ast H})/\partial \gamma \gt 0$ . This is due to a green expansion effect that combines the stealing effect with the market coverage effect, as we discussed above. In the case of hedonic qualities, consumer surplus tends to increase in γ, meaning that the environmental campaign is effective in reducing polluting emissions without jeopardizing the total amount of the good available for consumption. Hence, the campaign may contribute to navigating the tradeoff between output provision and emissions reductions that typically characterizes the taxation instrument. Remember that such a result crucially depends on the fact that the green good is emission free, as we assumed in our model. However, this would continue to hold when considering relatively low emissions coming from the green producer.

The social welfare function can be written in a compact way as:

$$SW^{\ast H}\lpar \gamma \rpar =\pi _{L}^{\ast H}+\pi _{H}^{\ast H}+CS_{L}^{\ast H}+CS_{H}^{\ast H}-e\cdot x_{H}^{\ast H}-s {\gamma ^{2} \over 2},$$

where the environmental damage is $e\cdot x_{H}^{\ast H}$ , given that firm H is now the one that pollutes.Footnote ²¹ The social welfare function is concave in γ if and only if $s \gt \underline{s}$ , where s is defined in (3). We compute the optimal γ level which maximizes social welfare:

(8) $$\eqalign{\gamma^{\ast H} = {\matrix{q_{H}\lpar cq_{H}q_{L} - 12cq_{H}^{2} - 3\Theta q_{L}^{3} + cq_{L}^{2} + 11\Theta q_{H}q_{L}^{2} - 8\Theta q_{H}^{2}q_{L}\rpar \cr + \,e\,q_{L}\lpar q_{L} - 4q_{H}\rpar \lpar q_{L} - 3q_{H} \rpar } \over s\,q_{L}\lpar q_{L} - 4q_{H}\rpar ^{2} - (q_{H} - q_{L}) \lpar 12q_{H}^{3}+2q_{L}^{3}-13q_{H} q_{L}^{2} + 19q_{H}^{2} q_{L}\rpar }.}$$

Given that $\gamma ^{\ast H}\geq 0$ and that the conditions of Lemma 5 have to be satisfied, we find:

The optimal policy is γ=0 as long as the emission level is very low, since the positive effect linked to the emission reduction does not compensate for the cost of the campaign. In contrast, for very high values of the emission, the optimal policy is $\gamma = \overline{\gamma }^{H}$ . Notice that at $\gamma = \overline{\gamma}^{H}$ the demand of the high-quality firm is still positive (and hence its profit). The previous discussion is summarized into:

3.2. Taxing the polluting good

We consider again a standard model of vertical differentiation model, where the high-quality good is now the polluting one.Footnote ²² As before, indifferent consumers are given by $\theta _{L}=p_{L}/q_{L}$ and $\theta_{H}=(p_{H}-p_{L})/q_{H}-q_{L}$ , and producing the green good requires a constant marginal cost c>0, whereas the brown quality is produced at zero cost. However, the polluting good is subject to a per-unit tax t. Profit functions are therefore given by $\pi _{L}=(p_{L}-c) x_{L}$ and $\pi _{H}=(p_{H}-t) x_{H}$ . Equilibrium prices as a function of qualities are:

$$p_{L}^{\ast \ast H}= {q_{L}\Theta (q_{H}-q_{L}) +tq_{L}+2cq_{H} \over 4q_{H}-q_{L}}, p_{H}^{\ast \ast H}= {q_{H} [2\Theta (q_{H}-q_{L}) +2t+c] \over 4q_{H}-q_{L}}.$$

Let us now define:

(9) $$\overline{t}^{H}\equiv {q_{H}[2\Theta (q_{H}-q_{L})+c] \over (2q_{H}-q_{L})};$$

Equilibrium demands/outputs are:

$$\eqalign{x_{L}^{\ast \ast H} &= {q_{H}\lsqb q_{L}\lpar t+\Theta q_{H}-\Theta q_{L}\rpar -c\lpar 2q_{H}-q_{L}\rpar \rsqb \over \lpar 4q_{H}-q_{L}\rpar (q_{H}-q_{L}) q_{L}}, \cr x_{H}^{\ast \ast H} &= {q_{H}\lsqb 2\Theta (q_{H}-q_{L})+c\rsqb -t\lpar 2q_{H}-q_{L}\rpar \over \lpar 4q_{H}-q_{L}\rpar (q_{H}-q_{L}) },}$$

and they are always positive under the conditions specified in Lemma 7. By construction, $\partial x_{H}^{\ast \ast }/\partial t \lt 0$ and $\partial x_{L}^{\ast \ast}/\partial t \gt 0$ . Moreover, $\partial (x_{H}^{\ast \ast} +x_{L}^{\ast \ast })/\partial t \lt 0$ : taxation always shrinks total output. Equilibrium profits are given by:

$$\pi_{L}^{\ast \ast H} = {q_{L} \over q_{H}}(q_{H} - q_{L}) (x_{L}^{\ast \ast H})^{2}, \pi_{H}^{\ast \ast H} = (q_{H} - q_{L}) (x_{H}^{\ast \ast H})^{2}.$$

Social welfare as a function of t is written in a compact form as:

$$SW^{\ast \ast H}(t) = \pi _{L}^{\ast \ast H} + \pi_{H}^{\ast \ast H} + CS_{L}^{\ast \ast H} + CS_{H}^{\ast \ast H} - e\cdot x_{H}^{\ast \ast H} + t\cdot x_{H}^{\ast \ast H}.$$

Algebraic calculations reveal that $SW^{\ast \ast H}\lpar t\rpar $ is concave in t. The optimal tax rate is:

(10) $$t^{\ast H} = {\matrix{e(4q_{H}-q_{L})\lpar 2q_{H}-q_{L}\rpar \cr[3pt] -\,q_{H}\lsqb \Theta \lpar 4q_{H}-3q_{L}\rpar (q_{H}-q_{L}) +2c\lpar 2q_{H}-q_{L}\rpar \rsqb } \over q_{H}\lpar 4q_{H}-3q_{L}\rpar }.$$

Taking into account that t* ^H has to be non-negative, and that the conditions appearing in Lemma 7 have to be satisfied:

When $t=\overline{t}^{H}$ , the profit of the high quality firm tends to zero. Also in this case it is relatively easy to prove that the government would prefer to leave an $\varepsilon \rightarrow 0$ to the polluting firm, instead of pushing it off the market.

3.3. Comparing the two instruments under hedonic qualities

As in the previous scenario, in order to compare taxation vs. campaign, we need to rank the threshold values of e that define the interval regions where different levels of social welfare occur. In the appendix we detail all the possible cases. The following proposition summarizes our results:

When the social welfare associated with the environmental campaign is concave ( $s \gt \underline{s}$ ), the government always prefers the taxation instrument. Consumers’ concern about the hedonic quality of goods prevails over the moral dimension that may have been activated by the campaign. A direct instrument like a tax on polluting goods proves therefore to be more efficient in terms of total welfare. This result is in accordance with Proposition 1, where we argue that the environmental campaign is more efficient than taxation only when consumers’ valuation of the environmental quality is sufficiently high.

Nonetheless, when we examined the impact of the campaign, we noticed that the green expansion effect consists of two components – a market stealing effect (some consumers switch from the brown to the green good), and a market coverage effect (some of the consumers who did not buy before now decide to buy the green good). Total output may therefore increase. then:

If the green product is emission free, the environmental campaign does not generate conflicts between competition authorities (aiming at fostering competition) and environmental authorities (aiming at reducing pollution); as γ increases, one observes the reduction of the emissions but not at the cost of milder competition. This is an important result of our analysis, especially because antitrust agencies often adopt consumer surplus as a measure of social welfare.

Notice finally that, under the assumptions of our model, taxation can completely eliminate the high-quality polluting firm H (or leave it with zero profit), while the environmental campaign entails a cost s which makes such an outcome undesirable. If the aim of the policy maker is to reduce pollution emissions as much as possible, then taxation provides the most effective tool.

5.1. Vertical vs. horizontal differentiation

The starting point of our paper is related to the existence of two vertically differentiated ‘worlds’, depending on whether consumers prefer the environmental quality or the hedonic quality of a product. We acknowledge that in most societies environmentally and non-environmentally concerned consumers coexist with one another. For instance, imagine that a fraction δ of consumers cares about the environmental quality, whereas the complementary fraction (1−δ) values the hedonic quality. We reckon that such an extension would not add much in terms of results. We conjecture that there would exist a δ-threshold such that the campaign would prove to be more efficient than the tax instrument as long as the fraction of environmentally concerned consumers is sufficiently high (and vice versa).

A unified scenario in which consumers reveal heterogeneous environmental concern is usually represented in horizontally differentiated models. Instead, we opted for vertical differentiation in order to capture the idea that all consumers, although being heterogeneous in their willingness to pay for quality, agree on the quality ranking of the two goods. Our setting is relevant in a wide range of situations in which goods are imperfect substitutes, and their qualities (either in terms of polluting emissions or in terms of pure performance) are objectively different. In particular, by adopting two alternative definitions of quality, we showed that our results crucially depended on the degree of consumer heterogeneity, which in turn was based on the specific type of quality that we considered.

A relatively simple model of horizontal differentiation would not have allowed us to obtain similar results. Consider, for instance, an extended version of the Hotelling (Reference Hotelling1929) linear city in which two firms produce a homogeneous good (homogeneous in terms of intrinsic quality) and locate in the interval [0, 1], where the location represents the environmental impact of the good. Under horizontal differentiation, at equal prices some consumers would buy the green good and others the brown good.

In section 2 of the online appendix, we develop in detail this horizontal differentiation extension. Here we only provide a brief sketch of the model and its main results in order to make a comparison with our vertical differentiation approach. Two firms, G and B, are located at the endpoints of the interval [0, 1]. Firm G is located in 0 and produces a green product (G), while firm B is located in 1 and produces a brown product (B). Let p _G and p _B denote respectively the prices of products G and B, with production being costless only for the brown producer. As for the demand side, we assume a continuum of consumers of mass 1 uniformly distributed along the interval [0, 1]. Each of them buys one unit of the good. The utility of a consumer indexed by x∈[0, 1] is:

(11) $$U(x) = \left\{\matrix{v-rx-p_{G} + \gamma (1-0) \hfill & \hbox{if he buys} G, \hfill \cr v-r(1-x) - p_{B} - \gamma (1 - 0) \hfill &\hbox{if he buys} B, \hfill}\right.$$

where v is the intrinsic quality of the goods and r represents the linear transportation cost measuring the substitutability between the two goods. In line with our model, buying the green (brown) good amplifies (reduces) the satisfaction of consumption by the term γ (1−0). This term depends on the environmental distance between the goods (1−0) as well as on the level of personal moral norms that favor pro-environmental behaviors, captured by γ≥0. As in the baseline model, γ is induced by the policy maker through the support of a costly environmental campaign. When the tax instrument is implemented, γ goes to 0. Profit functions and social welfare replicate those in the baseline model. The environmental damage derives again only from the production activity of the brown firm.

By replicating the two-stage game, we evaluate the social efficiency of the two policy instruments. We prove that taxation is more efficient than the campaign for a relatively wide interval region. The campaign prevails only when both its cost and the cost for producing the green product are sufficiently low, provided that the emissions take an intermediate value. Notice that, although it is still possible to find an interval region in which the policy maker prefers to adopt the campaign, this mainly depends upon a cost-effectiveness analysis, not upon consumers’ environmental concern. In our baseline model the impact of Θ was in a certain way ‘asymmetric’. The higher its value, the higher the consumer heterogeneity, but also the higher the average (and maximal) willingness to pay for quality. This undoubtedly favors the high-quality firm (which in our framework could be either the green or the brown firm). In the Hotelling model, parameter r could somewhat measure consumers’ heterogeneity, given that when it increases the two goods are perceived as more differentiated. However, r acts in a symmetric way, as it does not convey any particular advantage to a specific producer. For this reason, a ‘horizontal’ measure of consumer heterogeneity does not play any role in comparing the social efficiency of the two policy instruments.

Contributions that are close to the formal model presented in this section are those by Conrad (Reference Conrad2005) and Espìnola-Arredondo and Zhao (Reference Espìnola-Arredondo and Zhao2012), who extend the Hotelling duopoly model by taking into account green consumerism. Moreover, they also assume that the market is covered, thus simplifying the formal analysis.Footnote ²⁶ In terms of a comparison with our baseline model, the main drawback of considering market coverage is that total output at equilibrium is fixed. It follows that the comparison between the two instruments could be biased in favor of the taxation instrument as it no longer entails the negative effect of shrinking total output.

5.2. Effectiveness and cost of the environmental campaign

In the baseline model we restricted our attention to sufficiently low levels of γ. This ensured that both firms remained active in the market and that the initial quality ranking did not reverse. In particular, in the case of environmental qualities, if $\gamma \gt \overline{\gamma }^{E}$ the low (brown) quality firm would leave the market. In contrast, with hedonic qualities, if $\gamma \gt \overline{\gamma }^{H}$ the low (green) quality firm would charge a higher price than the rival, and eventually we would observe a quality switch. Therefore, in order to keep the initial ranking of hedonic qualities, we assume that the campaign cannot be too ‘revolutionary’, i.e., it does not induce all consumers to switch to the green good.Footnote ²⁷ However, our results are robust to this assumption. On the one hand, under environmental qualities, it does not make sense to further pursue the campaign. Once the brown firm is pushed off the market, then emissions reach their minimal level. On the other hand, under hedonic qualities, extending the analysis to higher levels of γ significantly alters the equilibrium market structure. In particular, this implies shifting first from an uncovered to a covered duopoly market (at the limit), and then to a monopoly dominated by the low green quality firm.Footnote ²⁸ Yet again, our main results hold. In the case of hedonic qualities, the tax instrument is still more efficient than the campaign. In fact, recall that pursuing high levels of the environmental campaign requires increasing costs.

Turning our attention to the cost of the campaign, we assumed that $s \gt \underline{s}$ , thus ensuring the concavity of the social welfare function. This allowed us to determine the optimal investment level in the campaign. For $s \lt \underline{s}$ , the social welfare function is convex in γ, meaning that the optimal campaign level is reached either in γ=0 or in $\gamma = \overline{\gamma}$ . Considering hedonic qualities, it is possible to demonstrate that, when $s \lt \underline{s}$ , there are conditions for which a relatively cheap campaign can be more efficient than the pollution tax. In particular, this is more likely to happen for high values of Θ, i.e., when consumers’ ex ante heterogeneity is prominent. However, as both goods are still on the market, the emission level should not be perceived as too dangerous by the policy maker; otherwise a more direct taxation instrument is to be preferred. In contrast, with environmental qualities our qualitative results do not change, the campaign being more efficient than the tax instrument in an interval region comparable to that of the baseline model.