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Optimal Sustainable Policies Under Pollution Ceiling: the Demographic Side

Published online by Cambridge University Press:  20 June 2014

R. Boucekkine*
Affiliation:
Aix-Marseille University (Aix-Marseille School of Economics), CNRS and EHESS, France
B. Martinez
Affiliation:
Department of Quantitative Economics, Universidad Complutense de Madrid, Spain
J.R. Ruiz-Tamarit
Affiliation:
Department of Economic Analysis, Universitat de València, Spain, and IRES Department of Economics, Université Catholique de Louvain, Belgium
*
Corresponding author. E-mail: raouf.boucekkine@univ-amu.fr
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Abstract

We study optimal sustainable policies in a benchmark logistic world (where both population and technological progress follow logistic laws of motion) subject to a pollution ceiling. The main policy in the hands of the benevolent planner is pollution abatement, ultimately leading to the control of a dirtiness index as in the early literature of the limits to growth literature. Besides inclusion of demographic dynamics, we also hypothesize that population size affects negatively the natural regeneration or assimilation rate, as a side product of human activities (like increasing pollution, deforestation,...). We first characterize optimal sustainable policies. Under certain conditions, the planner goes to the pollution ceiling value and stays on, involving a more stringent environmental policy and a sacrifice in terms of consumption per capita. Second, we study how the sustainable problem is altered when we depart from the logistic world by considering exponential technical progress (keeping population growth logistic). It’s shown that, as expected, introducing such an asymmetry widens the margins of optimal policies as sustainable environmental policies are clearly less stringent under exponential technical progress. Third, we connect our model to the data, using in particular UN population projections.

Type
Research Article
Copyright
© EDP Sciences, 2014

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References

J.P. Amigues, M. Moreaux. Optimal Growth under Climate Constraint. Unpublished manuscript, (2013)
J. Aznar-Márquez, J.R. Ruiz-Tamarit. Sufficient and Necessary Conditions for Non-Catastrophic Growth. IRES Discussion Paper, 2012-27, Université Catholique de Louvain, Belgium.
Barbier, E.. The Concept of Sustainable Economic Development. Environmental Conservation, 14 (1987), no. 2, 101110. CrossRefGoogle Scholar
R. Boucekkine, N. Hritonenko, Y. Yatsenko. Optimal Investment in Heterogenous Capital and Technology under Restricted Resources. Journal of Optimization Theory and Applications, (2013) forthcoming.
Boucekkine, R., Martinez, B., Ruiz-Tamarit, J.R.. Growth vs Level Effect of Population Change on Economic Development: An inspection into human-capital-related mechanisms. Journal of Mathematical Economics, 49 (2013), no. 4, 312334. CrossRefGoogle Scholar
Boucekkine, R., Pommeret, A., Prieur, F.. Optimal Regime Switching and Threshold Effects. Journal of Economic Dynamics and Control, 37 (2013a), no. 12, 29792997. CrossRefGoogle Scholar
Boucekkine, R., Pommeret, A., Prieur, F.. Technological vs Ecological Switch and the Environmental Kuznets Curve. American Journal of Agricultural Economics, 95 (2013b), no. 2, 252260. CrossRefGoogle Scholar
Bréchet, Th., Hritonenko, N., Yatsenko, Y.. Adaptation and Mitigation in Long-Term Climate Policy. Environmental and Resource Economics, 55 (2013), no. 2, 217243. CrossRefGoogle Scholar
Brida, J.A., Accinelli, E.. The Ramsey Model with Logistic Population Growth. Economic Bulletin, (2007), no. 3(15), 18. Google Scholar
Byrne, M. M.. Is Growth a Dirty Word? Pollution, Abatement and Endogenous Growth. Journal of Development Economics, 54 (1997), no. 2, 261284. CrossRefGoogle Scholar
Caballé, J., Santos, M. S.. On Endogenous Growth with Physical and Human Capital. Journal of Political Economy, 101 (1993), no. 6, 10421067. CrossRefGoogle Scholar
Chang, Y. S., Baek, S. J.. Limit to Improvement: Myth or Reality? Empirical Analysis of Historical Improvement on three Technologies Influential in the Evolution of Civilization. Technological Forecasting and Social Change, 77 (2010), no. 5, 712729. CrossRefGoogle Scholar
Chichilnisky, G.. An Axiomatic Approach to Sustainable Development. Social Choice and Welfare, 13 (1996), no. 2, 231257. CrossRefGoogle Scholar
Daly, H.. Towards some Operational Principles of Sustainable Development. Ecological Economics, 2 (1990), no. 1, 16. CrossRefGoogle Scholar
M. Ferrara, L. Guerrini. The Ramsey Model with Logistic Population Growth and Benthamithe Felicity Function. Proceeding of the 10th WSEAS International Conference on Mathematics and Computers in Business and Economics, Prague, Czech Republic, (2009), March 23-25, 17–20.
Forster, B. A.. Optimal Pollution with a non Constant Exponential Rate of Decay. Journal of Environmental Economics and Management, 2 (1975), no. 1, 16. CrossRefGoogle Scholar
Guerrini, L.. The Solow-Swan Model with a Bounded Population Growth Rate. Journal of Mathematical Economics, 42 (2006), no. 1, 1421. CrossRefGoogle Scholar
Gradus, R., Smulders, S.. The Trade-off between Environmental Care and Long-term Growth: Pollution in three Prototype Growth Models. Journal of Economics, 58 (1993), no. 1, 2551. CrossRefGoogle Scholar
Hartwick, R.. Intergenerational Equity and the Investment of Rents from Exhaustive Resources. American Economic Review, 67 (1977), no. 5, 972974. Google Scholar
Hoel, M., Karp, L.. Taxes versus Quotas for a Stock Pollutant. Resource and Energy Economics, 24 (2002), 367384. CrossRefGoogle Scholar
Huang, Ch., Cai, D.. Constant-Returns Endogenous Growth with Pollution Control. Environmental and Resource Economics, 4 (1994), no. 4, 383400. CrossRefGoogle Scholar
Michel, Ph., Rotillon, G.. Disutility of Pollution and Endogenous Growth. Environmental and Resource Economics, 6 (1995), no. 3, 279300. Google Scholar
Mohtadi, H.. Environment, Growth and Optimal Policy Design. Journal of Public Economics, 63 (1996), no. 1, 119140. CrossRefGoogle Scholar
Mulligan, C. B., Sala-i-Martin, X.. Transitional Dynamics in Two-Sector Models of Endogenous Growth. Quarterly Journal of Economics, 108 (1993), no. 3, 739773. CrossRefGoogle Scholar
Nordhaus, W.. Rolling the ‘DICE’: An Optimal Transition Path for Controlling Greenhouse Gases. Environmental and Energy Economics, 15 (1993), no. 1, 2750. Google Scholar
Pezzey, J. C. V.. Sustainability: an Interdisciplinary Guide. Environmental Values, 1 (1992), 321362. CrossRefGoogle Scholar
Prieur, F.. The Environmental Kuznets Curve in a World of Irreversibility. Economic Theory, 40 (2009), no. 1, 5790. CrossRefGoogle Scholar
Reis, A. B.. Endogenous Growth and the Possibility of Eliminating Pollution. Journal of Environmental Economics and Management, 42 (2001), no. 3, 360373. CrossRefGoogle Scholar
A. Seierstad, K. Sydsaeter. Optimal Control Theory with Economic Applications. Elsevier Science, Amsterdam, 1987.
R. Solow. Sustainability: An economist’s perspective. Lecture given at Woods Hole, Massachusetts, 1991. Reprinted in R. Dorfman & N. S. Dorfman (Eds.), Economics of the Environment, Selected Reading. New York: WWW Norton, 179-187, 1993.
Solow, R.. The Economics of Resources or the Resources of Economics. American Economic Review, Papers and Proceedings, 64 (1974), no. 2, 114. Google Scholar
Stokey, N. L.. Are there Limits to Growth? International Economic Review, 39 (1998), no. 1, 131. CrossRefGoogle Scholar
Tahvonen, O., Withagen, C.. Optimality of Irreversible Pollution Accumulation. Journal of Economic Dynamics and Control, 20 (1996), no. 9.10, 17751795. CrossRefGoogle Scholar
Tahvonen, O., Kuuluvainen, J.. Economic Growth, Pollution and Renewable Resources. Journal of Environmental Economics and Management, 24 (1993), no. 2, 101118. CrossRefGoogle Scholar
Y, Tsur, Zemel, A.. Optimal Transition to Backstop Substitutes for Nonrenewable Resources. Journal of Economic Dynamics and Control, 27 (2003), no. 4, 551572. Google Scholar
UNPD. World Population to 2300. New York: United Nations Population Division, 2004.
Weitzman, M. L.. A Review of the Stern Review on the Economics of Climate Change. Journal of Economic Literature, 45 (2007), no. 3, 703724. CrossRefGoogle Scholar
Withagen, C.. Pollution and Exhaustibility of Fossil Fuels. Resources and Energy Economics, 16 (1994), no. 3, 235242. CrossRefGoogle Scholar