Methods & Tools for LCA & LCC
Environmental Challenges Through the Life Cycle of Battery Electric Vehicles
This study provides an up-to-date expert assessment and comparison between the life cycle’s carbon footprint of battery electric and internal combustion engine passenger cars.
Audience:
Automotive Suppliers, Battery Manufacturers, Electric Vehicle Manufacturers, Environmental Advocacy Groups, Environmental Protection Agencies, European Commission, Financial Analysts, Grid Operators, International Energy Organizations, National and Local Government, Public Transportation Agencies, Recycling Industry, Renewable Energy Providers, Research Centres, Sustainability Investors, United Nations, Universities, Utility Companies, Waste Management Industry
Automotive Suppliers, Battery Manufacturers, Electric Vehicle Manufacturers, Environmental Advocacy Groups, Environmental Protection Agencies, European Commission, Financial Analysts, Grid Operators, International Energy Organizations, National and Local Government, Public Transportation Agencies, Recycling Industry, Renewable Energy Providers, Research Centres, Sustainability Investors, United Nations, Universities, Utility Companies, Waste Management Industry
Keyword:
Battery Electric Vehicles, Battery Recycling, Battery Technology, Carbon Footprint, Circular Economy, Critical Raw Materials, Decarbonisation, Electric Range, Emission Trading Scheme, End-of-Life Stage, Energy Efficiency, Environmental Impact, Greenhouse Gas Emissions, Life Cycle Assessment, Mobility-as-a-Service, Policy Framework, Policy Recommendations, Renewable Energy, Resource Efficiency, Sustainable Battery Regulation, Sustainable Mobility, Vehicle Manufacturing, Vehicle to Grid
Battery Electric Vehicles, Battery Recycling, Battery Technology, Carbon Footprint, Circular Economy, Critical Raw Materials, Decarbonisation, Electric Range, Emission Trading Scheme, End-of-Life Stage, Energy Efficiency, Environmental Impact, Greenhouse Gas Emissions, Life Cycle Assessment, Mobility-as-a-Service, Policy Framework, Policy Recommendations, Renewable Energy, Resource Efficiency, Sustainable Battery Regulation, Sustainable Mobility, Vehicle Manufacturing, Vehicle to Grid
Electric Vehicle Operations
Longevity of Electric Vehicle Operations
The article delves into the evolution of battery chemistries, energy densities, and thermal management systems, which collectively impact battery life and overall vehicle longevity.
Audience:
Battery Manufacturers and Suppliers, Electric Vehicle Manufacturers, Electric Vehicle Owners and Consumers, Government and Regulatory Bodies, Researchers
Battery Manufacturers and Suppliers, Electric Vehicle Manufacturers, Electric Vehicle Owners and Consumers, Government and Regulatory Bodies, Researchers
Link:
researchgate.net
Electric Vehicle Operations
Optimizing Electric Vehicle Operations for a Smart Environment: A Comprehensive Review
This review article examines the deterministic control model and centralized control model, the types of EV models, and their tabular comparison.
Audience:
Electric Vehicle Manufacturers, Electric Vehicle Owners and Consumers, Energy and Utility Companies, Government and Regulatory Bodies, Researchers
Electric Vehicle Manufacturers, Electric Vehicle Owners and Consumers, Energy and Utility Companies, Government and Regulatory Bodies, Researchers
Keyword:
Battery Technology, Charging Controllers, Charging Stations, Electric Vehicles, Plug-in Hybrid Electric Vehicle
Battery Technology, Charging Controllers, Charging Stations, Electric Vehicles, Plug-in Hybrid Electric Vehicle
Link:
Researchgate.net