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Health and environmental effects of battery electric cars

April 12, 2024

For a wider view, see Effects of cars and Environmental effects of transport.

Usage of electric cars damage people’s health and the environment less than similar sized internal combustion engine cars. While aspects of their production can induce similar, less or different environmental impacts, they produce little or no tailpipe emissions, and reduce dependence on petroleum, greenhouse gas emissions, and deaths from air pollution.[2] Electric motors are significantly more efficient than internal combustion engines and thus, even accounting for typical power plant efficiencies and distribution losses,[3] less energy is required to operate an electric vehicle. Manufacturing batteries for electric cars requires additional resources and energy, so they may have a larger environmental footprint in the production phase.[4][5] Electric vehicles also generate different impacts in their operation and maintenance. Electric vehicles are typically heavier and could produce more tire and road dust air pollution, but their regenerative braking could reduce such particulate pollution from brakes.[6] Electric vehicles are mechanically simpler, which reduces the use and disposal of engine oil.

The Tesla Model Y was the world's top selling electric car in 2022.[1]

Comparison with fossil-fueled cars edit

Although all cars have effects on other people, battery electric cars have major environmental benefits over conventional internal combustion engine vehicles, such as:

  • Elimination of harmful tailpipe pollutants such as various oxides of nitrogen, which kill thousands of people every year[7]
  • Less CO2 emissions than fossil-fuelled cars, thus limiting climate change[8]
  • As almost all electric cars have regenerative braking brake pads can be used less frequently than in non-electric cars, and may thus sometimes produce less particulate pollution than brakes in non-electric cars.[9][10] Also, some electric cars may have a combination of drum brakes and disc brakes, and drum brakes are known to cause less particulate emissions than disc brakes.[11] Under the provisionally agreed Euro 7 standard electric cars have a lower limit of brake particulates.[12][13]

Electric cars may have some disadvantages, such as:

  • Possible increased tire pollution compared to fossil-fueled cars. This is sometimes caused by the fact that most electric cars have a heavy battery, which means the car's tires are subjected to more wear.[14][15] Devices to capture tyre particulates are being developed,[16][17] and under Euro 7 all new cars will have to meet the same tyre particulate limit.[18]
  • If electric cars are bigger than fossil fuel cars there may be more road dust pollution. However as of 2024 more research on road dust air pollution is needed.[2]

Materials extraction impact edit

Raw materials edit

Electric cars use far less raw materials than conventional petrol/gasoline cars, according to Transport & Environment. This difference is chiefly due to fuel consumption: the petrol or diesel that is burned during the average lifetime of a car would fill a stack of oil barrels 90 metres high, and weights between 300-400 times more than the total quantity of battery metals lost with an electric car (at around 30 kilograms, these metals would fit into the size of a football).

Plug-in hybrids and electric cars run off lithium-ion batteries and rare-earth element electric motors. Electric vehicles use much more lithium carbonate equivalent in their batteries compared to the 7g (0.25 oz) for a smartphone or the 30 g (1.1 oz) used by tablets or computers. As of 2016, a hybrid electric passenger car might use 5 kg (11 lb) of lithium carbonate equivalent, while one of Tesla's high performance electric cars could use as much as 80 kg (180 lb) of lithium carbonate equivalent. [19]

Most electric vehicles use permanent magnet motors as they are more efficient than induction motors. These permanent magnets use neodymium and praseodymium which can be dirty and difficult to produce.

The demand for lithium used by the batteries and rare-earth elements (such as neodymium, boron, and cobalt[20]) used by the electric motors, is expected to grow significantly due to the future sales increase of plug-in electric vehicles.

In 2022 the Intergovernmental Panel on Climate Change said (with medium confidence) "Emerging national strategies on critical minerals and the requirements from major vehicle manufacturers are leading to new, more geographically diverse mines. The standardisation of battery modules and packaging within and across vehicle platforms, as well as increased focus on design for recyclability are important. Given the high degree of potential recyclability of lithium-ion batteries, a nearly closed-loop system in the future could mitigate concerns about critical mineral issues."[21]: 142 

Lithium edit

 
The Salar de Uyuni in Bolivia is one of the largest known lithium reserves in the world.[22][23]
See also: Lithium § Environmental_issues, and Lithium-ion_battery § Environmental_impact

The main deposits of lithium are found in China and throughout the Andes mountain chain in South America. In 2008 Chile was the leading lithium metal producer with almost 30%, followed by China, Argentina, and Australia.[24][25] Lithium recovered from brine, such as in Nevada[26][27] and Cornwall, is much more environmentally friendly.[28]

Nearly half the world's known reserves are located in Bolivia,[24][22] and according to the US Geological Survey, Bolivia's Salar de Uyuni desert has 5.4 million tons of lithium.[22][26] Other important reserves are located in Chile,[29] China, and Brazil.[24][26]

According to a 2020 study balancing lithium supply and demand for the rest of the century needs good recycling systems, vehicle-to-grid integration, and lower lithium intensity of transportation.[30]

Rare-earth elements edit

 
Evolution of global rare-earth oxides production by country (1950–2000
See also: Rare-earth element

Electric motor manufactured for plug-in electric cars and hybrid electric vehicles use rare earth elements. The demand for heavy metals, and other specific elements (such as neodymium, boron and cobalt) required for the batteries and powertrain is expected to grow significantly due to the future sales increase of plug-in electric vehicles in the mid and long term.[31][24] It is estimated that there are sufficient lithium reserves to power 4 billion electric cars.[32][33]

China has 48% of the world's reserves of rare-earth elements,[34] the United States has 13%, and Russia, Australia, and Canada have significant deposits. Until the 1980s, the U.S. led the world in rare-earth production, but since the mid-1990s China has controlled the world market for these elements. The mines in Bayan Obo near Baotou, Inner Mongolia, are currently the largest source of rare-earth metals and are 80% of China's production.[35]

Manufacturing impact edit

Electric cars also have impacts arising from the manufacturing of the vehicle.[36][37] The manufacturing of the battery results in significant environmental impact,[citation needed] as it requires copper and aluminum for its anode and cathode. Since battery packs are heavy, manufacturers work to lighten the rest of the vehicle. As a result, electric car components contain many lightweight materials that require a lot of energy to produce and process, such as aluminium and carbon-fiber-reinforced polymers.[38]

The manufacturing of electric vehicle motors also results in environmental impacts. Electric cars can utilize two types of motors: permanent magnet motors (like the one found in the Mercedes EQA), and induction motors (like the one found on the Tesla Model 3). Induction motors do not use magnets, but permanent magnet motors do. The magnets found in permanent magnet motors used in electric vehicles contain rare-earth metals to increase the power output of these motors.[39] The mining and processing of metals such as lithium, copper, and nickel requires significant  energy and can release toxic compounds into the surrounding area. Local populations may be exposed to toxic substances through air and groundwater contamination.[40]

Several reports have found that hybrid electric vehicles, plug-in hybrids and all-electric cars generate more carbon emissions during their production than current internal combustion engine vehicles but still have a lower overall carbon footprint over the full life cycle.[41] The initial higher carbon footprint is due mainly to battery production,[42] which may double the production carbon footprint as of 2023 but this varies a lot by country and is forecast to decrease rapidly during the decade.[43]

Consumer use impacts edit

Air pollution and carbon emissions edit

See also: Plug-in_hybrid § Greenhouse_gas_emissions

Compared to conventional internal combustion engine automobiles, electric cars reduce local air pollution, especially in cities,[44] as they do not emit harmful tailpipe pollutants such as particulates (soot), volatile organic compounds, hydrocarbons, carbon monoxide, ozone, lead, and various oxides of nitrogen. Some of the environmental impact may instead be shifted to the site of the generation plants, depending on the method by which the electricity used to recharge the batteries is generated. This shift of environmental impact from the vehicle itself (in the case of internal combustion engine vehicles) to the source of electricity (in the case of electric vehicles) is referred to as the long tailpipe of electric vehicles. This impact, however, is still less than that of traditional vehicles, as the large size of power plants allow them to generate less emissions per unit power than internal combustion engines, and electricity generation continues to become greener as renewables such as wind, solar and nuclear power become more widespread. By 2050, carbon emissions reduced by the use of electric cars can save over 1163 lives annually and over $12.61 billion in health benefits in many major U.S. metropolitan cities such as Los Angeles and New York City.[45]

The specific emission intensity of generating electric power varies significantly with respect to location and time, depending on current demand and availability of renewable sources (See List of renewable energy topics by country and territory). The phase-out of fossil fuels and coal and transition to renewable and low-carbon power sources will make electricity generation greener, which will reduce the impact of electric vehicles that use that electricity.

Particulates edit

See also: Mobile source air pollution

The operation of any car results in non-exhaust emissions such as brake dust, airborne road dust, and tire erosion, which contribute to particulate matter in the air.[46] Particulate matter is dangerous for respiratory health.[47][48] In the UK non-tailpipe particulate emissions from all types of vehicles (including electric vehicles) may be responsible for between 7,000 and 8,000 premature deaths a year.[46]

Lower operational impacts and maintenance needs edit

Battery electric vehicles have lower maintenance costs compared to internal combustion vehicles since electronic systems break down much less often than the mechanical systems in conventional vehicles, and the fewer mechanical systems onboard last longer due to the better use of the electric engine. Electric cars do not require oil changes and other routine maintenance checks.[49][50]

Internal combustion engines are relatively inefficient at converting on-board fuel energy to propulsion as most of the energy is wasted as heat, and the rest while the engine is idling. Electric motors, on the other hand, are more efficient at converting stored energy into driving a vehicle. Electric drive vehicles do not consume energy while at rest or coasting, and modern plug-in cars can capture and reuse as much as one fifth of the energy normally lost during braking through regenerative braking.[49][50] Typically, conventional gasoline engines effectively use only 15% of the fuel energy content to move the vehicle or to power accessories, and diesel engines can reach on-board efficiencies of 20%, while electric drive vehicles typically have on-board efficiencies of around 80%.[49]

Low repairability edit

Electric vehicle batteries are easily totalled.[51][52]

End-of-life edit

Main article: Battery recycling

Batteries edit

Lead-acid edit

Like internal combustion engine cars, most electric cars, as of 2023, contain lead–acid batteries which are used to power the vehicle's auxiliary electrical systems.[53] In some countries lead acid batteries are not recycled safely.[54][55]

Lithium-ion edit

Current retirement criteria for lithium-ion batteries in electric vehicles cite 80% capacity for end-of-first-life, and 65% capacity for end-of-second-life.[56] The first-life defines the lifespan of the battery's intended use, while the second-life defines the lifespan of the battery's subsequent use-case. Lithium-ion batteries from cars can sometimes be re-used for a second-life in factories[57] or as stationary batteries.[58] Some electric vehicle manufacturers, such as Tesla, claim that a lithium-ion battery that no longer fulfills the requirements of its intended use can be serviced by them directly, thereby lengthening its first-life.[59] Reused electric vehicle batteries can potentially supply 60-100% of the grid-scale lithium-ion energy storage by 2030.[60] The carbon footprint of an electric vehicle lithium-ion battery can be reduced by up to 17% if reused rather than immediately retired.[56] After retirement, direct recycling processes allow reuse of cathode mixtures, which removes processing steps required for manufacturing them. When this is infeasible, individual materials can be obtained through pyrometallurgy and hydrometallurgy. When lithium-ion batteries are recycled, if they are not handled properly, the harmful substances inside will cause secondary[clarification needed] pollution to the environment.[61] These same processes can also endanger workers and damage their health.[62] Lithium-ion batteries, when disposed of in household trash, can present fire hazards in transport and in landfills, resulting in trash fires that can destroy other recyclable materials and create increased carbon dioxide and particulate matter emissions.[63] Vehicle fires cause local pollution.[64]

Motors edit

Electric motors are an essential component of electric cars that convert electrical energy into mechanical energy to move the wheels, where neodymium magnets are commonly used in the manufacturing process.[65] There is currently no cost-effective way for the industry to recycle electric motors due to the complicated extraction process of these magnets.[66] Many electric motors end up in the landfill or are shredded because there is no viable recycle or disposal alternative.[66]

Two primary efforts to remedy this dilemma include the DEMETER project and a joint venture between Nissan Motors and Waseda University to lessen the environment impact of electric motors.[66][67] The DEMETER project was a research initiative between the European Union and private entities, which culminated in the development of a recyclable electric motor designed by French company Valeo.[67] Nissan and Waseda identified and refined a new process for extracting rare-earth magnets for re-use in the manufacturing of new electric vehicle motors.[67]

See also edit

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April 12, 2024
health, environmental, effects, battery, electric, cars, wider, view, effects, cars, environmental, effects, transport, usage, electric, cars, damage, people, health, environment, less, than, similar, sized, internal, combustion, engine, cars, while, aspects, . For a wider view see Effects of cars and Environmental effects of transport Usage of electric cars damage people s health and the environment less than similar sized internal combustion engine cars While aspects of their production can induce similar less or different environmental impacts they produce little or no tailpipe emissions and reduce dependence on petroleum greenhouse gas emissions and deaths from air pollution 2 Electric motors are significantly more efficient than internal combustion engines and thus even accounting for typical power plant efficiencies and distribution losses 3 less energy is required to operate an electric vehicle Manufacturing batteries for electric cars requires additional resources and energy so they may have a larger environmental footprint in the production phase 4 5 Electric vehicles also generate different impacts in their operation and maintenance Electric vehicles are typically heavier and could produce more tire and road dust air pollution but their regenerative braking could reduce such particulate pollution from brakes 6 Electric vehicles are mechanically simpler which reduces the use and disposal of engine oil The Tesla Model Y was the world s top selling electric car in 2022 1 Contents 1 Comparison with fossil fueled cars 2 Materials extraction impact 2 1 Raw materials 2 1 1 Lithium 2 1 2 Rare earth elements 3 Manufacturing impact 4 Consumer use impacts 4 1 Air pollution and carbon emissions 4 2 Particulates 4 3 Lower operational impacts and maintenance needs 4 4 Low repairability 5 End of life 5 1 Batteries 5 1 1 Lead acid 5 1 2 Lithium ion 5 2 Motors 6 See also 7 ReferencesComparison with fossil fueled cars editAlthough all cars have effects on other people battery electric cars have major environmental benefits over conventional internal combustion engine vehicles such as Elimination of harmful tailpipe pollutants such as various oxides of nitrogen which kill thousands of people every year 7 Less CO2 emissions than fossil fuelled cars thus limiting climate change 8 As almost all electric cars have regenerative braking brake pads can be used less frequently than in non electric cars and may thus sometimes produce less particulate pollution than brakes in non electric cars 9 10 Also some electric cars may have a combination of drum brakes and disc brakes and drum brakes are known to cause less particulate emissions than disc brakes 11 Under the provisionally agreed Euro 7 standard electric cars have a lower limit of brake particulates 12 13 Electric cars may have some disadvantages such as Possible increased tire pollution compared to fossil fueled cars This is sometimes caused by the fact that most electric cars have a heavy battery which means the car s tires are subjected to more wear 14 15 Devices to capture tyre particulates are being developed 16 17 and under Euro 7 all new cars will have to meet the same tyre particulate limit 18 If electric cars are bigger than fossil fuel cars there may be more road dust pollution However as of 2024 more research on road dust air pollution is needed 2 Materials extraction impact editRaw materials edit Electric cars use far less raw materials than conventional petrol gasoline cars according to Transport amp Environment This difference is chiefly due to fuel consumption the petrol or diesel that is burned during the average lifetime of a car would fill a stack of oil barrels 90 metres high and weights between 300 400 times more than the total quantity of battery metals lost with an electric car at around 30 kilograms these metals would fit into the size of a football Plug in hybrids and electric cars run off lithium ion batteries and rare earth element electric motors Electric vehicles use much more lithium carbonate equivalent in their batteries compared to the 7g 0 25 oz for a smartphone or the 30 g 1 1 oz used by tablets or computers As of 2016 a hybrid electric passenger car might use 5 kg 11 lb of lithium carbonate equivalent while one of Tesla s high performance electric cars could use as much as 80 kg 180 lb of lithium carbonate equivalent 19 Most electric vehicles use permanent magnet motors as they are more efficient than induction motors These permanent magnets use neodymium and praseodymium which can be dirty and difficult to produce The demand for lithium used by the batteries and rare earth elements such as neodymium boron and cobalt 20 used by the electric motors is expected to grow significantly due to the future sales increase of plug in electric vehicles In 2022 the Intergovernmental Panel on Climate Change said with medium confidence Emerging national strategies on critical minerals and the requirements from major vehicle manufacturers are leading to new more geographically diverse mines The standardisation of battery modules and packaging within and across vehicle platforms as well as increased focus on design for recyclability are important Given the high degree of potential recyclability of lithium ion batteries a nearly closed loop system in the future could mitigate concerns about critical mineral issues 21 142 Lithium edit nbsp The Salar de Uyuni in Bolivia is one of the largest known lithium reserves in the world 22 23 See also Lithium Environmental issues and Lithium ion battery Environmental impact The main deposits of lithium are found in China and throughout the Andes mountain chain in South America In 2008 Chile was the leading lithium metal producer with almost 30 followed by China Argentina and Australia 24 25 Lithium recovered from brine such as in Nevada 26 27 and Cornwall is much more environmentally friendly 28 Nearly half the world s known reserves are located in Bolivia 24 22 and according to the US Geological Survey Bolivia s Salar de Uyuni desert has 5 4 million tons of lithium 22 26 Other important reserves are located in Chile 29 China and Brazil 24 26 According to a 2020 study balancing lithium supply and demand for the rest of the century needs good recycling systems vehicle to grid integration and lower lithium intensity of transportation 30 Rare earth elements edit nbsp Evolution of global rare earth oxides production by country 1950 2000See also Rare earth element Electric motor manufactured for plug in electric cars and hybrid electric vehicles use rare earth elements The demand for heavy metals and other specific elements such as neodymium boron and cobalt required for the batteries and powertrain is expected to grow significantly due to the future sales increase of plug in electric vehicles in the mid and long term 31 24 It is estimated that there are sufficient lithium reserves to power 4 billion electric cars 32 33 China has 48 of the world s reserves of rare earth elements 34 the United States has 13 and Russia Australia and Canada have significant deposits Until the 1980s the U S led the world in rare earth production but since the mid 1990s China has controlled the world market for these elements The mines in Bayan Obo near Baotou Inner Mongolia are currently the largest source of rare earth metals and are 80 of China s production 35 Manufacturing impact editElectric cars also have impacts arising from the manufacturing of the vehicle 36 37 The manufacturing of the battery results in significant environmental impact citation needed as it requires copper and aluminum for its anode and cathode Since battery packs are heavy manufacturers work to lighten the rest of the vehicle As a result electric car components contain many lightweight materials that require a lot of energy to produce and process such as aluminium and carbon fiber reinforced polymers 38 The manufacturing of electric vehicle motors also results in environmental impacts Electric cars can utilize two types of motors permanent magnet motors like the one found in the Mercedes EQA and induction motors like the one found on the Tesla Model 3 Induction motors do not use magnets but permanent magnet motors do The magnets found in permanent magnet motors used in electric vehicles contain rare earth metals to increase the power output of these motors 39 The mining and processing of metals such as lithium copper and nickel requires significant energy and can release toxic compounds into the surrounding area Local populations may be exposed to toxic substances through air and groundwater contamination 40 Several reports have found that hybrid electric vehicles plug in hybrids and all electric cars generate more carbon emissions during their production than current internal combustion engine vehicles but still have a lower overall carbon footprint over the full life cycle 41 The initial higher carbon footprint is due mainly to battery production 42 which may double the production carbon footprint as of 2023 update but this varies a lot by country and is forecast to decrease rapidly during the decade 43 Consumer use impacts editAir pollution and carbon emissions edit See also Plug in hybrid Greenhouse gas emissions Compared to conventional internal combustion engine automobiles electric cars reduce local air pollution especially in cities 44 as they do not emit harmful tailpipe pollutants such as particulates soot volatile organic compounds hydrocarbons carbon monoxide ozone lead and various oxides of nitrogen Some of the environmental impact may instead be shifted to the site of the generation plants depending on the method by which the electricity used to recharge the batteries is generated This shift of environmental impact from the vehicle itself in the case of internal combustion engine vehicles to the source of electricity in the case of electric vehicles is referred to as the long tailpipe of electric vehicles This impact however is still less than that of traditional vehicles as the large size of power plants allow them to generate less emissions per unit power than internal combustion engines and electricity generation continues to become greener as renewables such as wind solar and nuclear power become more widespread By 2050 carbon emissions reduced by the use of electric cars can save over 1163 lives annually and over 12 61 billion in health benefits in many major U S metropolitan cities such as Los Angeles and New York City 45 The specific emission intensity of generating electric power varies significantly with respect to location and time depending on current demand and availability of renewable sources See List of renewable energy topics by country and territory The phase out of fossil fuels and coal and transition to renewable and low carbon power sources will make electricity generation greener which will reduce the impact of electric vehicles that use that electricity Particulates edit See also Mobile source air pollution The operation of any car results in non exhaust emissions such as brake dust airborne road dust and tire erosion which contribute to particulate matter in the air 46 Particulate matter is dangerous for respiratory health 47 48 In the UK non tailpipe particulate emissions from all types of vehicles including electric vehicles may be responsible for between 7 000 and 8 000 premature deaths a year 46 Lower operational impacts and maintenance needs edit Battery electric vehicles have lower maintenance costs compared to internal combustion vehicles since electronic systems break down much less often than the mechanical systems in conventional vehicles and the fewer mechanical systems onboard last longer due to the better use of the electric engine Electric cars do not require oil changes and other routine maintenance checks 49 50 Internal combustion engines are relatively inefficient at converting on board fuel energy to propulsion as most of the energy is wasted as heat and the rest while the engine is idling Electric motors on the other hand are more efficient at converting stored energy into driving a vehicle Electric drive vehicles do not consume energy while at rest or coasting and modern plug in cars can capture and reuse as much as one fifth of the energy normally lost during braking through regenerative braking 49 50 Typically conventional gasoline engines effectively use only 15 of the fuel energy content to move the vehicle or to power accessories and diesel engines can reach on board efficiencies of 20 while electric drive vehicles typically have on board efficiencies of around 80 49 Low repairability edit Electric vehicle batteries are easily totalled 51 52 End of life editMain article Battery recycling Batteries edit Lead acid edit Like internal combustion engine cars most electric cars as of 2023 contain lead acid batteries which are used to power the vehicle s auxiliary electrical systems 53 In some countries lead acid batteries are not recycled safely 54 55 Lithium ion edit Current retirement criteria for lithium ion batteries in electric vehicles cite 80 capacity for end of first life and 65 capacity for end of second life 56 The first life defines the lifespan of the battery s intended use while the second life defines the lifespan of the battery s subsequent use case Lithium ion batteries from cars can sometimes be re used for a second life in factories 57 or as stationary batteries 58 Some electric vehicle manufacturers such as Tesla claim that a lithium ion battery that no longer fulfills the requirements of its intended use can be serviced by them directly thereby lengthening its first life 59 Reused electric vehicle batteries can potentially supply 60 100 of the grid scale lithium ion energy storage by 2030 60 The carbon footprint of an electric vehicle lithium ion battery can be reduced by up to 17 if reused rather than immediately retired 56 After retirement direct recycling processes allow reuse of cathode mixtures which removes processing steps required for manufacturing them When this is infeasible individual materials can be obtained through pyrometallurgy and hydrometallurgy When lithium ion batteries are recycled if they are not handled properly the harmful substances inside will cause secondary clarification needed pollution to the environment 61 These same processes can also endanger workers and damage their health 62 Lithium ion batteries when disposed of in household trash can present fire hazards in transport and in landfills resulting in trash fires that can destroy other recyclable materials and create increased carbon dioxide and particulate matter emissions 63 Vehicle fires cause local pollution 64 Motors edit Electric motors are an essential component of electric cars that convert electrical energy into mechanical energy to move the wheels where neodymium magnets are commonly used in the manufacturing process 65 There is currently no cost effective way for the industry to recycle electric motors due to the complicated extraction process of these magnets 66 Many electric motors end up in the landfill or are shredded because there is no viable recycle or disposal alternative 66 Two primary efforts to remedy this dilemma include the DEMETER project and a joint venture between Nissan Motors and Waseda University to lessen the environment impact of electric motors 66 67 The DEMETER project was a research initiative between the European Union and private entities which culminated in the development of a recyclable electric motor designed by French company Valeo 67 Nissan and Waseda identified and refined a new process for extracting rare earth magnets for re use in the manufacturing of new electric vehicle motors 67 See also editAll electric mode Battery Battery fade Converting existing vehicle to electric Downcycling of end of life e automotive batteries Electric power Electric velomobiles Fuel cell car Full cost accounting Hybrid electric vehicle Induction motor Modal shift Neighborhood Electric Vehicle Phase out of fossil fuel vehicles Plug in hybrid electric car Robotic disassembly of electric car batteries Solar car Vehicles powered by advanced biofuelsReferences edit Pontes Jose 2022 03 05 Best selling Electric Cars Globally in January 2022 CleanTechnica Retrieved 2022 04 08 a b Ritchie Hannah Do electric vehicles reduce air pollution www sustainabilitybynumbers com Retrieved 2024 01 27 All Electric Vehicles www fueleconomy gov Retrieved 2019 11 08 Michalek Chester Jaramillo Samaras Shiau Lave 2011 Valuation of plug in vehicle life cycle air emissions and oil displacement benefits Proceedings of the National Academy of Sciences 108 40 16554 16558 Bibcode 2011PNAS 10816554M doi 10 1073 pnas 1104473108 PMC 3189019 PMID 21949359 S2CID 6979825 Tessum Hill Marshall 2014 Life cycle air quality impacts of conventional and alternative light duty transportation in the United States Proceedings of the National Academy of Sciences 111 52 18490 18495 Bibcode 2014PNAS 11118490T doi 10 1073 pnas 1406853111 PMC 4284558 PMID 25512510 Ben Webster 29 July 2019 Electric cars are a threat to clean air claims Chris Boardman The Times Retrieved 3 August 2019 The government s air quality expert group said this month that particles from tyres brakes and road surfaces made up about two thirds of all particulate matter from road transport and would continue to increase even as more cars were run on electric power Association New Scientist and Press Diesel fumes lead to thousands more deaths than thought New Scientist Retrieved 2020 10 12 Supporting the global shift to electric mobility UNEP UN Environment Programme 2024 01 26 Retrieved 2024 01 27 Carrington Damian August 4 2017 Electric cars are not the answer to air pollution says top UK adviser The Guardian Retrieved September 1 2019 via www theguardian com Loeb Josh March 10 2017 Particle pollution from electric cars could be worse than from diesel ones eandt theiet org Retrieved September 1 2019 Geylin Mike 2022 06 09 Corrosion Emissions and the Return of Drum Brakes The BRAKE Report Retrieved 2022 12 05 Prez Matt de EU strikes provisional deal over Euro 7 emissions limits www fleetnews co uk Euro 7 Deal on new EU rules to reduce road transport emissions News European Parliament www europarl europa eu 2023 12 18 Retrieved 2024 01 05 The deal sets brake particles emissions limits PM10 for cars and vans 3mg km for pure electric vehicles 7mg km for most internal combustion engine ICE hybrid electric and fuel cell vehicles and 11mg km for large ICE vans Electric vehicle tires a lesser known pollution headache DW 07 12 2023 dw com Hawkins Andrew J 22 May 2023 An auto CEO came very close to saying the right thing about heavy EV batteries The Verge When Driving Tires Emit Pollution And EVs Make the Problem Worse Bloomberg com 2022 09 02 Retrieved 2022 12 05 FEATURE The engineers fighting deadly air pollution with an ingenious car add on www imeche org Retrieved 2022 12 05 Fischer Lauder Hannah 2023 12 20 Euro 7 EU Agrees on New Rules to Curb Road Transport Emissions Impakter Retrieved 2024 01 27 Hiscock Geoff 2015 11 18 Electric vehicles storage units drive prices up The Nikkei Retrieved 2016 02 29 Reporters Energy transition The dark side of the electric car battery cobalt rush France 24 7 July 2023 IPCC Climate Change 2022 Mitigation of Climate Change Summary for Policymakers PDF ipecac ch Report Intergovernmental Panel on Climate Change 4 April 2022 Archived from the original PDF on 2022 08 07 Retrieved 2004 04 22 a b c Simon Romero 2009 02 02 In Bolivia Untapped Bounty Meets Nationalism New York Times Retrieved 2010 02 28 Pagina sobre el Salar Spanish Evaporiticosbolivia org Archived from the original on 2011 03 23 Retrieved 2010 11 27 a b c d Clifford Krauss 2009 03 09 The Lithium Chase The New York Times Retrieved 2010 03 10 Brendan I Koerner 2008 10 30 The Saudi Arabia of Lithium Forbes Retrieved 2011 05 12 Published on Forbes Magazine dated November 24 2008 a b c USGS Mineral Commodities Summaries 2009 PDF U S Geological Survey January 2009 Retrieved 2010 03 07 See page 95 Hammond C R 2000 The Elements in Handbook of Chemistry and Physics 81st edition CRC press ISBN 978 0 8493 0481 1 Early Catherine The new gold rush for green lithium www bbc com Retrieved 2021 01 13 Riofrancos Thea 14 June 2021 The rush to go electric comes with a hidden cost destructive lithium mining via The Guardian Greim Peter Solomon A A Breyer Christian 2020 09 11 Assessment of lithium criticality in the global energy transition and addressing policy gaps in transportation Nature Communications 11 1 4570 Bibcode 2020NatCo 11 4570G doi 10 1038 s41467 020 18402 y ISSN 2041 1723 PMC 7486911 PMID 32917866 Irving Mintzer 2009 David B Sandalow ed Chapter 6 Look Before You Leap Exploring the Implications of Advanced Vehicles for Import Dependence and Passerger Safety PDF The Brookings Institution pp 107 126 ISBN 978 0 8157 0305 1 in Plug in Electric Vehicles What Role for Washington Learn About Lithium In 10 Bullet Points ElectroVelocity 2010 12 13 Retrieved 2011 01 03 Smith Michael 2009 12 07 Lithium for 4 8 Billion Electric Cars Lets Bolivia Upset Market Bloomberg Retrieved 2011 01 03 Not So Green Technology The Complicated Legacy of Rare Earth Mining Harvard International Review 12 August 2021 Tim Folger June 2011 Rare Earth Elements The Secret Ingredients of Everything National Geographic Archived from the original on May 22 2011 Retrieved 2011 06 12 Notter Dominic A Gauch Marcel Widmer Rolf Wager Patrick Stamp Anna Zah Rainer Althaus Hans Jorg 2010 09 01 Contribution of Li Ion Batteries to the Environmental Impact of Electric Vehicles Environmental Science amp Technology 44 17 6550 6556 Bibcode 2010EnST 44 6550N doi 10 1021 es903729a ISSN 0013 936X PMID 20695466 Notter Dominic A Kouravelou Katerina Karachalios Theodoros Daletou Maria K Haberland Nara Tudela 2015 Life cycle assessment of PEM FC applications electric mobility and m CHP Energy Environ Sci 8 7 1969 1985 doi 10 1039 c5ee01082a RecycleNation Is Carbon Fiber Better for the Environment than Steel RecycleNation Retrieved 2022 04 06 Hanejko Fran Permanent Magnet vs Induction Motor Torque Losses Material www horizontechnology biz 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Habre Rima Girguis Mariam Urman Robert Fruin Scott Lurmann Fred Shafer Martin Gorski Patrick Franklin Meredith McConnell Rob Avol Ed Gilliland Frank February 2021 Contribution of tailpipe and non tailpipe traffic sources to quasi ultrafine fine and coarse particulate matter in southern California Journal of the Air amp Waste Management Association 1995 71 2 209 230 doi 10 1080 10962247 2020 1826366 ISSN 2162 2906 PMC 8112073 PMID 32990509 Non exhaust Particulate Emissions from Road Transport An Ignored Environmental Policy Challenge www oecd ilibrary org Retrieved 2022 04 06 a b c Saurin D Shah 2009 David B Sandalow ed Chapter 2 Electrification of Transport and Oil Displacement 1st ed The Brookings Institution pp 29 37 and 43 ISBN 978 0 8157 0305 1 Archived from the original on 2010 04 04 in Plug in Electric Vehicles What Role for Washington a b Sperling Daniel and Deborah Gordon 2009 Two billion cars driving toward sustainability Oxford University Press New York pp 22 26 and 114 139 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Health and environmental effects of battery electric cars amp oldid 1217693340, wikipedia, wiki, book, books, library,

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