Browse data: PolicyIntervention
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- Application (39)
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Component: (Click arrow to add another value) Theme: Agricultural land use (Land use) (3) · Animal husbandry (Food) (1) · Aquatic biodiversity (NB) (1) · Climate mitigation (Climate) (1) · Eco goods and services (NB) (1) · Energy demand (Energy) (1) · Energy emissions (Energy) (1) · Energy system (Energy) (1) · GHG emissions (Climate) (1) · Land cover (NB) (1) · Land use system (Land use) (1) · Natural vegetation (Land use) (1) · Other climate (Climate) (1) · Other land use (Land use) (2) · Terrestrial biodiversity (NB) (1)
Showing below up to 14 results in range #1 to #14.
- Apply emission and energy intensity standards (Apply emission intensity standards for e.g. cars (gCO2/km), power plants (gCO2/kWh) or appliances (kWh/hour)., Component: Energy conversion, Energy demand)
- Carbon tax (A tax on carbon leads to higher prices for carbon intensive fuels (such as fossil fuels), making low-carbon alternatives more attractive., Component: Climate policy, Energy conversion, Energy demand)
- Change in grazing intensity (Change in grazing intensity, usually more intensive. This would require better management of grasslands, including for example the use of grass-clover mixtures and fertilisers, bringing the length of the grazing season in tune with the period of grass production, and rotations., Component: Land-use allocation)
- Change market shares of fuel types (Exogenously set the market shares of certain fuel types. This can be done for specific analyses or scenarios to explore the broader implications of increasing the use of, for instance, biofuels, electricity or hydrogen and reflects the impact of fuel targets., Component: Energy demand)
- Climate change adaptation (Adaptation to climate change reduces climate damage. The model can optimally calculate the optimal adaptation level based on marginal adaptation costs and marginal avoided damage, but an alternative adaptation level can be used as well., Component: Climate policy)
- Effort- or burden-sharing of emission reductions (Evaluation of burden-sharing or effort-sharing regimes. Which regions or countries should contribute, when and by how much to reduce global greenhouse gas emissions?, Component: Climate policy)
- Emission trading policy (Analysis of the effect of rules for trading emission credits on regional abatement costs., Component: Climate policy)
- Enlarge protected areas (Increase in areas with protected status, as well the size of the areas as the numer of parks., Component: Land-use allocation)
- Financing climate policy (Developed countries could provide financial resources to assist developing countries by implementation of mitigation and adaptation policies. To mobilise these funds, several mechanisms exist, of which the effect can be analysed, Component: Climate policy)
- Implementation of land use planning (Application of zoning laws or cadastres, assigning areas to certain land uses., Component: Land-use allocation)
- Improving energy efficiency (Exogenously set improvement in efficiency. Such improvements can be introduced for the submodels that focus on particular technologies, for example, in transport, heavy industry and households submodels., Component: Energy demand)
- Provision on improved stoves for traditional bio-energy (Increases the efficiency of bio-energy use., Component: Energy demand)
- Reduction proposals (pledges) (Evaluation of current reduction proposals by countries and policy options (for the next 10-20 years)., Component: Climate policy)
- Subsidies on modern energy (Reduces the costs of modern energy to reduce traditional energy use (can be targeted to low income groups)., Component: Energy demand)