Introducing Behavioral Change in Transportation into Energy/Economy/Environment Models

Introducing Behavioral Change in Transportation into Energy/Economy/Environment Models

Transportation is vital to economic and social development, but at the same time generates undesired consequences on local, regional, and global scales. One of the largest challenges is the mitigation of energy-related carbon dioxide emissions, to which this sector already contributes one-quarter globally and one-third in the United States. Technology measures are the prerequisite for drastically mitigating energy use and all emission species, but they are not sufficient. The resulting need for complementing technology measures with behavioral change policies contrasts sharply with the analyses carried out by virtually all energy / economy / environment (E3) models, given their focus on pure technology-based solutions. This paper addresses the challenges for E3 models to simulate behavioral changes in transportation. A survey of 13 major models concludes that especially hybrid energy models would already be capable of simulating some behavioral change policies, most notably the imposition of the full marginal societal costs of transportation. Another survey of major macroscopic transportation models finds that key specifications required for simulating behavioral change have already been implemented and tested, albeit not necessarily on a global scale. When integrating these key features into E3 models, a wide range of technology and behavioral change policies could be analyzed.

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Bibliographic Details
Main Author: Schafer, Andreas
Language:English
en_US
Published: World Bank, Washington, DC 2012-10
Subjects:ACCESSIBILITY, AIR, AIR POLLUTION, AIR POLLUTION IMPACTS, AIR QUALITY, AIR TRAFFIC, AIR TRAVEL, AIRCRAFT, ALTERNATIVE FUELS, ALTERNATIVE MODES, ALTERNATIVE TRANSPORTATION, ALTERNATIVE TRANSPORTATION MODES, ALTERNATIVES TO AUTOMOBILE TRAVEL, AUTO TRAVEL, AUTOMOBILE, AUTOMOBILE TRAVEL, AUTOMOBILE USE, AUTOMOBILES, AVERAGE SPEEDS, BUS, BUS TRAVEL, BUSES, CAR, CAR DEPENDENCE, CARBON, CARBON DIOXIDE, CARBON DIOXIDE EMISSIONS, CARBON TAX, CHOICE OF TRANSPORTATION, CLIMATE CHANGE, COMMUTERS, COST OF TRAVEL, COSTS OF TRANSPORTATION, CRASHES, DAILY TRAVEL, DAILY TRAVEL DISTANCE, DEMAND FOR MOBILITY, DEMAND FOR TRANSPORTATION, DIESEL, DRIVING, ECONOMIC DEVELOPMENT, ECONOMIC GROWTH, ELECTRIC VEHICLES, EMISSION, EMISSION REDUCTION, EMISSION REDUCTION POTENTIAL, EMISSION STANDARDS, EMISSIONS TARGETS, ENVIRONMENTAL, ENVIRONMENTAL EXTERNALITIES, ENVIRONMENTAL IMPACTS, ENVIRONMENTAL KUZNETS, EXTERNAL COSTS, EXTERNALITIES, FLIGHT TIME, FREIGHT, FREIGHT TRANSPORT, FREIGHT VEHICLES, FUEL, FUEL COSTS, FUEL EFFICIENCY, FUEL EFFICIENCY IMPROVEMENTS, FUEL PRICE, FUEL PRICE ELASTICITIES, FUEL TAX, FUEL TAXES, FUEL USE, FUEL-EFFICIENT VEHICLES, GASOLINE, GASOLINE COSTS, GREENHOUSE EFFECT, GREENHOUSE GAS, GREENHOUSE GAS EMISSIONS, HIGH-SPEED RAIL, HOUSEHOLD TRAVEL, HOUSEHOLD VEHICLES, INFRASTRUCTURE CAPACITY, INFRASTRUCTURE INVESTMENT, INFRASTRUCTURE POLICIES, INFRASTRUCTURES, INSPECTION, INTERCITY TRAVEL, INTERNATIONAL TRANSPORT, LABOR FORCE, LAND-USE PLANNING, LIGHT RAIL, LOCAL AIR POLLUTION, LOCOMOTIVE, LONG-DISTANCE, MARGINAL COSTS, MARINE TRANSPORT, MOBILITY, MODAL SPLIT, MODE SHIFT, MODE SHIFTS, MODES OF TRANSPORT, MODES OF TRAVEL, MOTOR VEHICLE, MOTOR VEHICLE ACCIDENTS, MOTORWAYS, NOISE, OIL, OZONE LAYER, PASSENGER TRANSPORT, PASSENGER TRAVEL, PERSONAL TRANSPORTATION, POPULATION DENSITIES, POPULATION DENSITY, POPULATION GROWTH, PRICE CHANGES, PRICE ELASTICITIES, PRICE ELASTICITY, PRIVATE VEHICLES, PRODUCTION FUNCTIONS, PUBLIC ROAD, PUBLIC TRANSIT, PUBLIC TRANSIT SYSTEMS, PUBLIC TRANSPORT, PUBLIC TRANSPORT MODES, PUBLIC TRANSPORTATION, QUALITY OF TRANSPORTATION, RAIL SYSTEMS, RAILWAY, RAILWAYS, RAPID TRANSIT, RAPID TRANSIT SYSTEMS, ROAD, ROAD CAPACITY, ROAD CONGESTION, ROAD INFRASTRUCTURE, ROAD PRICING, ROAD TRANSPORT, ROAD USER, ROAD USER CHARGES, ROAD VEHICLES, ROADS, SAFETY, SERVICE RELIABILITY, SPEEDS, STREETCAR LINES, STREETCARS, SUBURBS, SURFACE TRANSPORT, SUSTAINABLE DEVELOPMENT, SUSTAINABLE TRANSPORT, TECHNOLOGICAL CHANGE, TRAFFIC, TRAFFIC ACCIDENTS, TRAFFIC CONGESTION, TRAFFIC DEATHS, TRAFFIC DELAY, TRAFFIC DELAYS, TRAFFIC VOLUME, TRANSPORT, TRANSPORT COSTS, TRANSPORT DEMAND, TRANSPORT MODE, TRANSPORT MODES, TRANSPORT POLICY, TRANSPORT SECTOR, TRANSPORTATION, TRANSPORTATION ACTIVITIES, TRANSPORTATION ACTIVITY, TRANSPORTATION ALTERNATIVES, TRANSPORTATION CAPACITY, TRANSPORTATION COSTS, TRANSPORTATION DECISIONS, TRANSPORTATION DEMAND, TRANSPORTATION ECONOMICS, TRANSPORTATION FUEL, TRANSPORTATION IMPACTS, TRANSPORTATION INFRASTRUCTURE, TRANSPORTATION INVESTMENTS, TRANSPORTATION MARKET, TRANSPORTATION OPTIONS, TRANSPORTATION RESEARCH, TRANSPORTATION SERVICES, TRANSPORTATION STATISTICS, TRANSPORTATION SYSTEM, TRANSPORTATION SYSTEMS, TRAVEL ALTERNATIVES, TRAVEL BEHAVIOR, TRAVEL COSTS, TRAVEL DEMAND, TRAVEL DEMAND GROWTH, TRAVEL PATTERNS, TRAVEL SPEED, TRAVEL SPEEDS, TRAVEL TIME, TRAVEL TIME BUDGET, TRAVELERS, TRIP, TRIP MAKING, TRIP RATE, TRIPS, TRUCK TRAFFIC, TRUCKS, URBAN AIR POLLUTION, URBAN BUS, URBAN MOBILITY, URBAN MOBILITY REPORT, URBAN ROADS, URBAN SPRAWL, URBAN TRANSPORTATION, URBAN TRAVEL, VEHICLE COSTS, VEHICLE EMISSION, VEHICLE EMISSIONS, VEHICLE FLEET, VEHICLE FUEL, VEHICLE FUEL CONSUMPTION, VEHICLE MILES, VEHICLE OCCUPANCY, VEHICLE PURCHASE PRICES, VEHICLE SIZE, VEHICLE SPEED, VEHICLE SPEEDS, VEHICLE TRAFFIC, WATER POLLUTION,
Online Access:http://documents.worldbank.org/curated/en/2012/10/16835840/introducing-behavioral-change-transportation-energyeconomyenvironment-models-introducing-behavioral-change-transportation-energyeconomyenvironment-models
https://hdl.handle.net/10986/12085
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Summary:Transportation is vital to economic and social development, but at the same time generates undesired consequences on local, regional, and global scales. One of the largest challenges is the mitigation of energy-related carbon dioxide emissions, to which this sector already contributes one-quarter globally and one-third in the United States. Technology measures are the prerequisite for drastically mitigating energy use and all emission species, but they are not sufficient. The resulting need for complementing technology measures with behavioral change policies contrasts sharply with the analyses carried out by virtually all energy / economy / environment (E3) models, given their focus on pure technology-based solutions. This paper addresses the challenges for E3 models to simulate behavioral changes in transportation. A survey of 13 major models concludes that especially hybrid energy models would already be capable of simulating some behavioral change policies, most notably the imposition of the full marginal societal costs of transportation. Another survey of major macroscopic transportation models finds that key specifications required for simulating behavioral change have already been implemented and tested, albeit not necessarily on a global scale. When integrating these key features into E3 models, a wide range of technology and behavioral change policies could be analyzed.

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