Working paper

Competing Land Uses and Fossil Fuel, Optimal Energy Conversion Rates During the Transition Toward a Green Economy Under a Pollution Stock Constraint

Jean-Pierre Amigues, and Michel Moreaux

Abstract

We study the transition to a carbon-free economy in a model with a polluting non-renewable resource and a clean renewable resource. Transforming primary energy into ready-to-use energy services is costly and more efficient energy transformation rates are more costly to achieve. Renewable energy competes with food production for land and the food productivity of land can be improved at some cost. To avoid catastrophic climate damages, the pollution stock is mandated to stay below a given cap. When the economy is not constrained by the cap, the efficiency of energy transformation increases steadily until the transition toward the ultimate green economy; when renewable energy is exploited, its land use rises at the expense of food production; food productivity increases together with the land rent but food production drops; the food and energy prices increase and renewables substitute for non-renewable energy. During the constrained phase, the economy follows a constant path of prices, quantities, efficiency rates, food productivity and land rent, a phenomenon we call the ’ceiling efficiency paradox'.

JEL codes

  • Q00: General
  • Q32: Exhaustible Resources and Economic Development
  • Q43: Energy and the Macroeconomy
  • Q54: Climate • Natural Disasters • Global Warming

Replaced by

Jean-Pierre Amigues, and Michel Moreaux, Competing land uses and fossil fuel, and optimal energy conversion rates during the transition toward a green economy under a pollution stock constraint., Journal of Environmental Economics and Management, vol. 97, September 2019, pp. 92–115.

Reference

Jean-Pierre Amigues, and Michel Moreaux, Competing Land Uses and Fossil Fuel, Optimal Energy Conversion Rates During the Transition Toward a Green Economy Under a Pollution Stock Constraint, TSE Working Paper, n. 18-981, December 2018.

See also

Published in

TSE Working Paper, n. 18-981, December 2018