Misplaced Pages

Electric vehicle

Article snapshot taken from Wikipedia with creative commons attribution-sharealike license. Give it a read and then ask your questions in the chat. We can research this topic together.
(Redirected from Transportation electrification) Vehicle propelled by one or more electric motors This article is about all types of electric transportation vehicles. For electric automobiles, see Electric car. For other uses of the term "EV", see EV.
This article duplicates the scope of other articles, specifically Electric car. Please discuss this issue and help introduce a summary style to the article. (March 2024)

Electric vehicles around the world (left to right, from top):

An electric vehicle (EV) is a vehicle whose propulsion is powered fully or mostly by electricity. EVs include road and rail vehicles, electric boats and underwater vessels, electric aircraft and electric spacecraft.

Early electric vehicles first came into existence in the late 19th century, when the Second Industrial Revolution brought forth electrification and mass utilization of DC and AC electric motors. Using electricity was among the preferred methods for motor vehicle propulsion as it provides a level of quietness, comfort and ease of operation that could not be achieved by the gasoline engine cars of the time, but range anxiety due to the limited energy storage offered by contemporary battery technologies hindered any mass adoption of private electric vehicles throughout the 20th century. Internal combustion engines (both gasoline and diesel engines) were the dominant propulsion mechanisms for cars and trucks for about 100 years, but electricity-powered locomotion remained commonplace in other vehicle types, such as overhead line-powered mass transit vehicles like electric trains, trams, monorails and trolley buses, as well as various small, low-speed, short-range battery-powered personal vehicles such as mobility scooters.

Hybrid electric vehicles, where electric motors are used as a supplementary propulsion to internal combustion engines, became more widespread in the late 1990s. Plug-in hybrid electric vehicles, where electric motors can be used as the predominant propulsion rather than a supplement, did not see any mass production until the late 2000s, and battery electric cars did not become practical options for the consumer market until the 2010s.

A subtopic of sustainability
Sustainable transport
Public transport, goods delivery, private transport and pedestrians in Leidsestraat, Amsterdam
Also relevant to:
Aspects of sustainable transport:
Overviews
icon Transport portal

Progress in batteries, electric motors and power electronics have made electric cars more feasible than during the 20th century. As a means of reducing tailpipe emissions of carbon dioxide and other pollutants, and to reduce use of fossil fuels, government incentives are available in many areas to promote the adoption of electric cars and trucks.

History

Main article: History of the electric vehicle

Electric motive power started in 1827 when Hungarian priest Ányos Jedlik built the first crude but viable electric motor; the next year he used it to power a small model car. In 1835, Professor Sibrandus Stratingh of the University of Groningen, in the Netherlands, built a small-scale electric car, and sometime between 1832 and 1839, Robert Anderson of Scotland invented the first crude electric carriage, powered by non-rechargeable primary cells. American blacksmith and inventor Thomas Davenport built a toy electric locomotive, powered by a primitive electric motor, in 1835. In 1838, a Scotsman named Robert Davidson built an electric locomotive that attained a speed of four miles per hour (6 km/h). In England, a patent was granted in 1840 for the use of rails as conductors of electric current, and similar American patents were issued to Lilley and Colten in 1847.

Thomas Edison and George Meister in a Studebaker electric runabout, 1909

The first mass-produced electric vehicles appeared in America in the early 1900s. In 1902, the Studebaker Automobile Company entered the automotive business with electric vehicles, though it also entered the gasoline vehicles market in 1904. However, with the advent of cheap assembly line cars by Ford Motor Company, the popularity of electric cars declined significantly.

Due to lack of electricity grids and the limitations of storage batteries at that time, electric cars did not gain much popularity; however, electric trains gained immense popularity due to their economies and achievable speeds. By the 20th century, electric rail transport became commonplace due to advances in the development of electric locomotives. Over time their general-purpose commercial use reduced to specialist roles as platform trucks, forklift trucks, ambulances, tow tractors, and urban delivery vehicles, such as the iconic British milk float. For most of the 20th century, the UK was the world's largest user of electric road vehicles.

Electrified trains were used for coal transport, as the motors did not use the valuable oxygen in the mines. Switzerland's lack of natural fossil resources forced the rapid electrification of their rail network. One of the earliest rechargeable batteries – the nickel-iron battery – was favored by Edison for use in electric cars.

EVs were among the earliest automobiles, and before the preeminence of light, powerful internal combustion engines (ICEs), electric automobiles held many vehicle land speed and distance records in the early 1900s. They were produced by Baker Electric, Columbia Electric, Detroit Electric, and others, and at one point in history outsold gasoline-powered vehicles. In 1900, 28 percent of the cars on the road in the US were electric. EVs were so popular that even President Woodrow Wilson and his secret service agents toured Washington, D.C., in their Milburn Electrics, which covered 60–70 miles (100–110 km) per charge.

A charging station in Seattle shows an AMC Gremlin, modified to take electric power; it had a range of about 50 miles (80 km) on one charge, 1973

Most producers of passenger cars opted for gasoline cars in the first decade of the 20th century, but electric trucks were an established niche well into the 1920s. A number of developments contributed to a decline in the popularity of electric cars. Improved road infrastructure required a greater range than that offered by electric cars, and the discovery of large reserves of petroleum in Texas, Oklahoma, and California led to the wide availability of affordable gasoline/petrol, making internal combustion powered cars cheaper to operate over long distances. Electric vehicles were seldom marketed as a women's luxury car, which may have been a stigma among male consumers. Also, internal combustion powered cars became ever-easier to operate thanks to the invention of the electric starter by Charles Kettering in 1912, which eliminated the need of a hand crank for starting a gasoline engine, and the noise emitted by ICE cars became more bearable thanks to the use of the muffler, which Hiram Percy Maxim had invented in 1897. As roads were improved outside urban areas, electric vehicle range could not compete with the ICE. Finally, the initiation of mass production of gasoline-powered vehicles by Henry Ford in 1913 reduced significantly the cost of gasoline cars as compared to electric cars.

In the 1930s, National City Lines, which was a partnership of General Motors, Firestone, and Standard Oil of California purchased many electric tram networks across the country to dismantle them and replace them with GM buses. The partnership was convicted of conspiring to monopolize the sale of equipment and supplies to their subsidiary companies, but was acquitted of conspiring to monopolize the provision of transportation services.

The Copenhagen Summit, which was conducted in the midst of a severe observable climate change brought on by human-made greenhouse gas emissions, was held in 2009. During the summit, more than 70 countries developed plans to eventually reach net zero. For many countries, adopting more EVs will help reduce the use of gasoline.

Experimentation

General Motors EV1 electric car (1996–1998), a subject of the film Who Killed the Electric Car?

In January 1990, General Motors President introduced its EV concept two-seater, the "Impact", at the Los Angeles Auto Show. That September, the California Air Resources Board mandated major-automaker sales of EVs, in phases starting in 1998. From 1996 to 1998 GM produced 1117 EV1s, 800 of which were made available through three-year leases.

Chrysler, Ford, GM, Honda, and Toyota also produced limited numbers of EVs for California drivers during this time period. In 2003, upon the expiration of GM's EV1 leases, GM discontinued them. The discontinuation has variously been attributed to:

  • the auto industry's successful federal court challenge to California's zero-emissions vehicle mandate,
  • a federal regulation requiring GM to produce and maintain spare parts for the few thousand EV1s and
  • the success of the oil and auto industries' media campaign to reduce public acceptance of EVs.

A movie made on the subject in 2005–2006 was titled Who Killed the Electric Car? and released theatrically by Sony Pictures Classics in 2006. The film explores the roles of automobile manufacturers, oil industry, the U.S. government, batteries, hydrogen vehicles, and the general public, and each of their roles in limiting the deployment and adoption of this technology.

Ford released a number of their Ford Ecostar delivery vans into the market. Honda, Nissan and Toyota also repossessed and crushed most of their EVs, which, like the GM EV1s, had been available only by closed-end lease. After public protests, Toyota sold 200 of its RAV4 EVs; they later sold at over their original forty-thousand-dollar price. Later, BMW of Canada sold off a number of Mini EVs when their Canadian testing ended.

The production of the Citroën Berlingo Electrique stopped in September 2005. Zenn started production in 2006 but ended by 2009.

Reintroduction

The global stock of both plug-in hybrid electric vehicles (PHEVs) and battery electric vehicles (BEVs) has grown steadily since the 2010s.Sales of passenger electric vehicles (EVs) indicate a trend away from gas-powered vehicles.

During the late 20th and early 21st century, the environmental impact of the petroleum-based transportation infrastructure, along with the fear of peak oil, led to renewed interest in electric transportation infrastructure. EVs differ from fossil fuel-powered vehicles in that the electricity they consume can be generated from a wide range of sources, including fossil fuels, nuclear power, and renewables such as solar power and wind power, or any combination of those. Recent advancements in battery technology and charging infrastructure have addressed many of the earlier barriers to EV adoption, making electric vehicles a more viable option for a wider range of consumers.

The carbon footprint and other emissions of electric vehicles vary depending on the fuel and technology used for electricity generation. The electricity may be stored in the vehicle using a battery, flywheel, or supercapacitors. Vehicles using internal combustion engines usually only derive their energy from a single or a few sources, usually non-renewable fossil fuels. A key advantage of electric vehicles is regenerative braking, which recovers kinetic energy, typically lost during friction braking as heat, as electricity restored to the on-board battery.

Electricity sources

There are many ways to generate electricity, of varying costs, efficiency and ecological desirability.

A passenger train, taking power through a third rail with return through the traction railsAn electric locomotive at Brig, SwitzerlandThe MAZ-7907 uses an on-board generator to power in-wheel electric motors.

Connection to generator plants

Onboard generators and hybrid EVs

See also: Diesel–electric transmission, Petrol–electric transmission, and Hybrid vehicle

It is also possible to have hybrid EVs that derive electricity from multiple sources, such as:

  • On-board rechargeable electricity storage system (RESS) and a direct continuous connection to land-based generation plants for purposes of on-highway recharging with unrestricted highway range
  • On-board rechargeable electricity storage system and a fueled propulsion power source (internal combustion engine): plug-in hybrid

For especially large EVs, such as submarines, the chemical energy of the diesel–electric can be replaced by a nuclear reactor. The nuclear reactor usually provides heat, which drives a steam turbine, which drives a generator, which is then fed to the propulsion. See Nuclear marine propulsion.

A few experimental vehicles, such as some cars and a handful of aircraft use solar panels for electricity.

Onboard storage

Fuel use in vehicle designs
Vehicle type Fuel used
Combustion-only vehicle
(ICE)
Exclusively uses petroleum or other fuel.
Micro hybrid electric vehicle
(μHEV)
Exclusively uses petroleum or other fuel,
but can shut off engine to consume less.
Mild hybrid electric vehicle
(MHEV, BAHV)
Exclusively uses petroleum or other fuel,
but has electric battery to consume less.
Plug-in hybrid vehicle
(PHEV)
Uses mixture of petroleum or other fuel
and electricity from power grid.
All-electric vehicle
(BEV, AEV)
Exclusively uses electricity from power grid.
Fuel cell vehicle
(FCV, FCEV)
Exclusively uses hydrogen or other fuel
to generate electricity.

These systems are powered from an external generator plant (nearly always when stationary), and then disconnected before motion occurs, and the electricity is stored in the vehicle until needed.

Batteries, electric double-layer capacitors and flywheel energy storage are forms of rechargeable on-board electricity storage systems. By avoiding an intermediate mechanical step, the energy conversion efficiency can be improved compared to hybrids by avoiding unnecessary energy conversions. Furthermore, electro-chemical batteries conversions are reversible, allowing electrical energy to be stored in chemical form.

Lithium-ion battery

Battery prices fell, given economies of scale and new cell chemistries improving energy density. However, general inflationary pressures, and rising costs of raw materials and components, inhibited price declines in the early 2020s.
Namsan E-Bus, the first commercially used battery electric bus system which is powered with lithium-ion batteries
Main article: Electric vehicle battery

Most electric vehicles use lithium-ion batteries (Li-Ions or LIBs). Lithium-ion batteries have a higher energy density, longer life span, and higher power density than most other practical batteries. Complicating factors include safety, durability, thermal breakdown, environmental impact, and cost. Li-ion batteries should be used within safe temperature and voltage ranges to operate safely and efficiently.

Increasing the battery's lifespan decreases effective costs and environmental impact. One technique is to operate a subset of the battery cells at a time and switching these subsets.

In the past, nickel–metal hydride batteries were used in some electric cars, such as those made by General Motors. These battery types are considered outdated due to their tendencies to self-discharge in the heat. Furthermore, a patent for this type of battery was held by Chevron, which created a problem for their widespread development. These factors, coupled with their high cost, has led to lithium-ion batteries leading as the predominant battery for EVs.

The prices of lithium-ion batteries have declined dramatically over the past decade, contributing to a reduction in price for electric vehicles, but an increase in the price of critical minerals such as lithium from 2021 to the end of 2022 has put pressure on historical battery price decreases.

Electric motor

Electric truck e-Force One
Main article: Traction motor

The power of a vehicle's electric motor, as in other machines, is measured in kilowatts (kW). Electric motors can deliver their maximum torque over a wide RPM range. This means that the performance of a vehicle with a 100 kW electric motor exceeds that of a vehicle with a 100 kW internal combustion engine, which can only deliver its maximum torque within a limited range of engine speed.

Efficiency of charging varies considerably depending on the type of charger, and energy is lost during the process of converting the electrical energy to mechanical energy.

Usually, direct current (DC) electricity is fed into a DC/AC inverter where it is converted to alternating current (AC) electricity and this AC electricity is connected to a 3-phase AC motor.

For electric trains, forklift trucks, and some electric cars, DC motors are often used. In some cases, universal motors are used, and then AC or DC may be employed. In recent production vehicles, various motor types have been implemented; for instance, induction motors within Tesla Motor vehicles and permanent magnet machines in the Nissan Leaf and Chevrolet Bolt.

Energy and motors

An electric powertrain used by Power Vehicle Innovation for trucks or buses

Most large electric transport systems are powered by stationary sources of electricity that are directly connected to the vehicles through wires. Electric traction allows the use of regenerative braking, in which the motors are used as brakes and become generators that transform the motion of, usually, a train into electrical power that is then fed back into the lines. This system is particularly advantageous in mountainous operations, as descending vehicles can produce a large portion of the power required for those ascending. This regenerative system is only viable if the system is large enough to use the power generated by descending vehicles.

In the systems above, motion is provided by a rotary electric motor. However, it is possible to "unroll" the motor to drive directly against a special matched track. These linear motors are used in maglev trains which float above the rails supported by magnetic levitation. This allows for almost no rolling resistance of the vehicle and no mechanical wear and tear of the train or track. In addition to the high-performance control systems needed, switching and curving of the tracks becomes difficult with linear motors, which to date has restricted their operations to high-speed point to point services.

Vehicle types

Neighborhood Electric Vehicle, Squad Solar NEV, with solar panel roof

It is generally possible to equip any kind of vehicle with an electric power-train.

Ground vehicles

Pure-electric vehicles

See also: Electric car and Battery electric vehicle

A pure-electric vehicle or all-electric vehicle is powered exclusively through electric motors. The electricity may come from a battery (battery electric vehicle), solar panel (solar vehicle) or fuel cell (fuel cell vehicle).

Hybrid EVs

This section is an excerpt from Hybrid electric vehicle.

A hybrid electric vehicle (HEV) is a type of hybrid vehicle that couples a conventional internal combustion engine (ICE) with one or more electric engines into a combined propulsion system. The presence of the electric powertrain, which has inherently better energy conversion efficiency, is intended to achieve either better fuel economy or better acceleration performance than a conventional vehicle. There is a variety of HEV types and the degree to which each functions as an electric vehicle (EV) also varies. The most common form of HEV is hybrid electric passenger cars, although hybrid electric trucks (pickups, tow trucks and tractors), buses, motorboats, and aircraft also exist.

Modern HEVs use energy recovery technologies such as motor–generator and regenerative braking to recycle the vehicle's kinetic energy to electric energy via an alternator, which is stored in a battery pack or a supercapacitor. Some varieties of HEV use an internal combustion engine to directly drive an electrical generator, which either recharges the vehicle's batteries or directly powers the electric traction motors; this combination is known as a range extender. Many HEVs reduce idle emissions by temporarily shutting down the combustion engine at idle (such as when waiting at the traffic light) and restarting it when needed; this is known as a start-stop system. A hybrid-electric system produces less tailpipe emissions than a comparably sized gasoline engine vehicle since the hybrid's gasoline engine usually has smaller displacement and thus lower fuel consumption than that of a conventional gasoline-powered vehicle. If the engine is not used to drive the car directly, it can be geared to run at maximum efficiency, further improving fuel economy.

There are different ways that a hybrid electric vehicle can combine the power from an electric motor and the internal combustion engine. The most common type is a parallel hybrid that connects the engine and the electric motor to the wheels through mechanical coupling. In this scenario, the electric motor and the engine can drive the wheels directly. Series hybrids only use the electric motor to drive the wheels and can often be referred to as extended-range electric vehicles (EREVs) or range-extended electric vehicles (REEVs). There are also series-parallel hybrids where the vehicle can be powered by the engine working alone, the electric motor on its own, or by both working together; this is designed so that the engine can run at its optimum range as often as possible.

Plug-in electric vehicle

Main article: Plug-in electric vehicle See also: Plug-in hybrid and Electric car
Togg C-SUV produced by Togg, a Turkish automotive company established in 2018 for producing EVs.

A plug-in electric vehicle (PEV) is any motor vehicle that can be recharged from any external source of electricity, such as wall sockets, and the electricity stored in the Rechargeable battery packs drives or contributes to drive the wheels. PEV is a subcategory of electric vehicles that includes battery electric vehicles (BEVs), plug-in hybrid vehicles, (PHEVs), and electric vehicle conversions of hybrid electric vehicles and conventional internal combustion engine vehicles.

Range-extended electric vehicle

See also: Range extender

A range-extended electric vehicle (REEV) is a vehicle powered by an electric motor and a plug-in battery. An auxiliary combustion engine is used only to supplement battery charging and not as the primary source of power.

On- and off-road EVs

On-road electric vehicles include electric cars, electric trolleybuses, electric buses, battery electric buses, electric trucks, electric bicycles, electric motorcycles and scooters, personal transporters, neighborhood electric vehicles, golf carts, milk floats, and forklifts. Off-road vehicles include electrified all-terrain vehicles and electric tractors.

Railborne EVs

Main article: Railway electrification system
A streetcar (or tram) in Hanover drawing current from a single overhead wire through a pantograph

The fixed nature of a rail line makes it relatively easy to power EVs through permanent overhead lines or electrified third rails, eliminating the need for heavy onboard batteries. Electric locomotives, electric multiple units, electric trams (also called streetcars or trolleys), electric light rail systems, and electric rapid transit are all in common use today, especially in Europe and Asia.

Since electric trains do not need to carry a heavy internal combustion engine or large batteries, they can have very good power-to-weight ratios. This allows high speed trains such as France's double-deck TGVs to operate at speeds of 320 km/h (200 mph) or higher, and electric locomotives to have a much higher power output than diesel locomotives. In addition, they have higher short-term surge power for fast acceleration, and using regenerative brakes can put braking power back into the electrical grid rather than wasting it.

Maglev trains are also nearly always EVs.

There are also battery electric passenger trains operating on non-electrified rail lines.

Seaborne EVs

See also: Submarine § Propulsion, Ship § Propulsion systems, and electric boat
Oceanvolt SD8.6 electric saildrive motor

Electric boats were popular around the turn of the 20th century. Interest in quiet and potentially renewable marine transportation has steadily increased since the late 20th century, as solar cells have given motorboats the infinite range of sailboats. Electric motors can and have also been used in sailboats instead of traditional diesel engines. Electric ferries operate routinely. Submarines use batteries (charged by diesel or gasoline engines at the surface), nuclear power, fuel cells or Stirling engines to run electric motor-driven propellers. Fully electric tugboats are being used in Auckland, New Zealand (June 2022), Vancouver, British Columbia (October 2023), and San Diego, California.

Airborne EVs

Mars helicopter Ingenuity
Main article: Electric aircraft

Since the beginnings of aviation, electric power for aircraft has received a great deal of experimentation. Currently, flying electric aircraft include piloted and unpiloted aerial vehicles.

Electrically powered spacecraft

Main article: Electrically powered spacecraft propulsion

Electric power has a long history of use in spacecraft. The power sources used for spacecraft are batteries, solar panels and nuclear power. Current methods of propelling a spacecraft with electricity include the arcjet rocket, the electrostatic ion thruster, the Hall-effect thruster, and Field Emission Electric Propulsion.

Space rover vehicles

Main article: Rover (space exploration)

Crewed and uncrewed vehicles have been used to explore the Moon and other planets in the Solar System. On the last three missions of the Apollo program in 1971 and 1972, astronauts drove silver-oxide battery-powered Lunar Roving Vehicles distances up to 35.7 kilometers (22.2 mi) on the lunar surface. Uncrewed, solar-powered rovers have explored the Moon and Mars.

Records

World record on an electric motorcycle by Michel von Tell on a LiveWire in 2020
  • Rimac Nevera, an electric hypercar, set 23 world speed records in one day.
  • Fastest acceleration of an electric car, 0 to 100 km/h in 1.461 seconds by university students at the University of Stuttgart.
  • Electric Land Speed Record 353 mph (568 km/h).
  • Electric Car Distance Record 1,725 miles (2,776 km) in 24 hours by Bjørn Nyland.
  • Greatest distance by electric vehicle, single charge 999.5 miles (1,608.5 km).
  • Solar-powered EV is fastest EV to go over 1,000 km without stopping to recharge, the Sunswift 7.
  • Electric Motorcycle: 1,070 miles (1,720 km) under 24 hours. Michel von Tell on a Harley LiveWire.
  • Electric flight: 439.5 miles (707.3 km) without charge.

Properties

Components

The type of battery, the type of traction motor and the motor controller design vary according to the size, power and proposed application, which can be as small as a motorized shopping cart or wheelchair, through pedelecs, electric motorcycles and scooters, neighborhood electric vehicles, industrial fork-lift trucks and including many hybrid vehicles.

Energy sources

EVs are much more efficient than fossil fuel vehicles and have few direct emissions. At the same time, they do rely on electrical energy that is generally provided by a combination of non-fossil fuel plants and fossil fuel plants. Consequently, EVs can be made less polluting overall by modifying the source of electricity. In some areas, persons can ask utilities to provide their electricity from renewable energy.

Fossil fuel vehicle efficiency and pollution standards take years to filter through a nation's fleet of vehicles. New efficiency and pollution standards rely on the purchase of new vehicles, often as the current vehicles already on the road reach their end-of-life. Only a few nations set a retirement age for old vehicles, such as Japan or Singapore, forcing periodic upgrading of all vehicles already on the road.

Batteries

Main article: Electric vehicle battery
Lithium ion battery for motorbikes or powersport vehicles

An electric-vehicle battery (EVB) in addition to the traction battery specialty systems used for industrial (or recreational) vehicles, are batteries used to power the propulsion system of a battery electric vehicle (BEVs). These batteries are usually a secondary (rechargeable) battery, and are typically lithium-ion batteries.

Traction batteries, specifically designed with a high ampere-hour capacity, are used in forklifts, electric golf carts, riding floor scrubbers, electric motorcycles, electric cars, trucks, vans, and other electric vehicles.

Charging

Grid capacity

If almost all road vehicles were electric it would increase global demand for electricity by up to 25% by 2050 compared to 2020. However, overall energy consumption and emissions would diminish because of the higher efficiency of EVs over the entire cycle, and the reduction in energy needed to refine fossil fuels.

Charging stations

This section is an excerpt from Charging station. Charging stations for electric vehicles:

A charging station, also known as a charge point, chargepoint, or electric vehicle supply equipment (EVSE), is a power supply device that supplies electrical power for recharging plug-in electric vehicles (including battery electric vehicles, electric trucks, electric buses, neighborhood electric vehicles, and plug-in hybrid vehicles).

There are two main types of EV chargers: Alternating current (AC) charging stations and direct current (DC) charging stations. Electric vehicle batteries can only be charged by direct current electricity, while most mains electricity is delivered from the power grid as alternating current. For this reason, most electric vehicles have a built-in AC-to-DC converter commonly known as the "onboard charger" (OBC). At an AC charging station, AC power from the grid is supplied to this onboard charger, which converts it into DC power to recharge the battery. DC chargers provide higher power charging (which requires much larger AC-to-DC converters) by building the converter into the charging station instead of the vehicle to avoid size and weight restrictions. The station then directly supplies DC power to the vehicle, bypassing the onboard converter. Most modern electric car models can accept both AC and DC power.

Charging stations provide connectors that conform to a variety of international standards. DC charging stations are commonly equipped with multiple connectors to charge various vehicles that use competing standards.

Battery swapping

Instead of recharging EVs from electric sockets, batteries could be mechanically replaced at special stations in a few minutes (battery swapping).

Batteries with greater energy density such as metal-air fuel cells cannot always be recharged in a purely electric way, so some form of mechanical recharge may be used instead. A zinc–air battery, technically a fuel cell, is difficult to recharge electrically so may be "refueled" by periodically replacing the anode or electrolyte instead.

Electric roads

Main article: Electric road
Three types of electric road systems. An electric bus (black) receives power from the road: (A) with three inductive pickups (red) from a strip of resonant inductive coils (blue) embedded several centimeters under the road (gray); (B) with a current collector (red) sliding over a ground-level power supply rail segment (blue) flush with the surface of the road (gray); (C) with an overhead current collector (red) sliding against a powered overhead line (blue)

An electric road system (ERS) is a road which supplies electric power to vehicles travelling on it. Common implementations are overhead power lines above the road, ground-level power supply through conductive rails, and dynamic wireless power transfer (DWPT) through resonant inductive coils or inductive rails embedded in the road. Overhead power lines are limited to commercial vehicles while ground-level rails and inductive power transfer can be used by any vehicle, which allows for public charging through a power metering and billing systems. Of the three methods, ground-level conductive rails are estimated to be the most cost-effective.

National electric road projects

Government studies and trials have been conducted in several countries seeking a national electric road network.

Korea was the first to implement an induction-based public electric road with a commercial bus line in 2013 after testing an experimental shuttle service in 2009, but it was shut down due to aging infrastructure amidst controversy over the continued public funding of the technology.

United Kingdom municipal projects in 2015 and 2021 found wireless electric roads financially unfeasible.

Sweden has been performing assessments of various electric road technologies since 2013 under the Swedish Transport Administration electric road program. After receiving electric road construction offers in excess of the project's budget in 2023, Sweden pursued cost-reduction measures for either wireless or rail electric roads. The project's final report was published in 2024, which recommended against funding a national electric road network in Sweden as it would not be cost-effective, unless the technology was adopted by its trading partners such as by France and Germany.

Germany found in 2023 that the wireless electric road system (wERS) by Electreon collects 64.3% of the transmitted energy, poses many difficulties during installation, and blocks access to other infrastructure in the road. Germany trialed overhead lines in three projects and reported they are too expensive, difficult to maintain, and pose a safety risk.

France found similar drawbacks for overhead lines as Germany did. France began several electric road pilot projects in 2023 for inductive and rail systems. Ground-level power supply systems are considered the most likely candidates.

Other in-development technologies

Main article: Electric double-layer capacitor
This section needs expansion with: up-to-date information. You can help by adding to it. (July 2021)

Conventional electric double-layer capacitors are being worked on to achieve the energy density of lithium-ion batteries, offering almost unlimited lifespans and no environmental issues. High-K electric double-layer capacitors, such as EEStor's EESU, could improve lithium ion energy density several times over if they can be produced. Lithium-sulphur batteries offer 250 Wh/kg. Sodium-ion batteries promise 400 Wh/kg with only minimal expansion/contraction during charge/discharge and a very high surface area, and rely on lower cost materials than Lithium-ion, Leading to Cheaper batteries that do not require critical minerals.

Safety

This section needs expansion with: up-to-date information. You can help by adding to it. (July 2021)

The United Nations in Geneva (UNECE) has adopted the first international regulation (Regulation 100) on safety of both fully electric and hybrid electric cars, with the intent of ensuring that cars with a high voltage electric power train, such as hybrid and fully-electric vehicles, are as safe as combustion-powered cars. The EU and Japan have already indicated that they intend to incorporate the new UNECE Regulation in their respective rules on technical standards for vehicles.

Environmental

Part of a series on
Sustainable energy
A car drives past 4 wind turbines in a field, with more on the horizon
Energy conservation
Renewable energy
Sustainable transport
See also: Environmental aspects of the electric car, Environmental impacts of lithium-ion batteries, and Environmental impact of the petroleum industry
Learning curve of lithium-ion batteries: the price of batteries declined by 97% in three decades.

EVs release no tailpipe air pollutants, and reduce respiratory illnesses such as asthma. However, EVs are charged with electricity that may be generated by means that have health and environmental impacts.

The carbon emissions from producing and operating an EV are in the majority of cases less than those of producing and operating a conventional vehicle. EVs in urban areas almost always pollute less than internal combustion vehicles.

One limitation of the environmental potential of EVs is that simply switching the existing privately owned car fleet from ICEs to EVs will not free up road space for active travel or public transport. Electric micromobility vehicles, such as e-bikes, may contribute to the decarbonisation of transport systems, especially outside of urban areas which are already well-served by public transport.

Internal combustion engined vehicles use far more raw materials over their lifetime than EVs.

Lithium-ion batteries

Since their first commercial release in 1991, lithium-ion batteries have become an important technology for achieving low-carbon transportation systems. Information regarding the sustainability of production process of batteries has become a politically charged topic.

Business processes of raw material extraction in practice raise issues of transparency and accountability of the management of extractive resources. In the complex supply chain of lithium technology, there are diverse stakeholders representing corporate interests, public interest groups and political elites that are concerned with outcomes from the technology production and use. One possibility to achieve balanced extractive processes would be the establishment of commonly agreed standards on the governance of technology worldwide.

The compliance of these standards can be assessed by the Assessment of Sustainability in Supply Chains Frameworks (ASSC). Hereby, the qualitative assessment consists of examining governance and social and environmental commitment. Indicators for the quantitative assessment are management systems and standards, compliance and social and environmental indicators.

One source estimates that over a fifth of the lithium and about 65% of the cobalt needed for electric cars will be from recycled sources by 2035. On the other hand, when counting the large quantities of fossil fuel non-electric cars consume over their lifetime, electric cars can be considered to dramatically reduce raw-material needs.

Geographical distribution of the global battery supply chain

In 2022, the manufacturing of an EV emitted on average around 50% more CO2 than an equivalent internal combustion engine vehicle, but this difference is more than offset by the much higher emissions from the oil used in driving an internal combustion engine Vehicle over its lifetime compared to those from generating the electricity used for driving the EV.

In 2023, Greenpeace issued a video criticizing the view that EVs are "silver bullet for climate", arguing that the construction phase has a high environmental impact. For example, the rise in SUV sales by Hyundai almost eliminate the climate benefits of passing to EV in this company, because even electric SUVs have a high carbon footprint as they consume much raw materials and energy during construction. Greenpeace proposes a mobility as a service concept instead, based on biking, public transport and ride sharing.

Open-pit nickel mining has led to environmental degradation and pollution in developing countries such as the Philippines and Indonesia. In 2024, nickel mining and processing was one of the main causes of deforestation in Indonesia. Open-pit cobalt mining has led to deforestation and habitat destruction in the Democratic Republic of Congo.

Socio-economic

A 2003 study in the United Kingdom found that "ollution is most concentrated in areas where young children and their parents are more likely to live and least concentrated in areas to which the elderly tend to migrate," and that "those communities that are most polluted and which also emit the least pollution tend to be amongst the poorest in Britain." A 2019 UK study found that "households in the poorest areas emit the least NOx and PM, whilst the least poor areas emitted the highest, per km, vehicle emissions per household through having higher vehicle ownership, owning more diesel vehicles and driving further."

Mechanical

Tesla Model S chassis with drive motor
Cutaway view of a Tesla Model S drive motor

Electric motors are mechanically very simple and often achieve 90% energy conversion efficiency over the full range of speeds and power output and can be precisely controlled. They can also be combined with regenerative braking systems that have the ability to convert movement energy back into stored electricity. This can be used to reduce the wear on brake systems (and consequent brake pad dust) and reduce the total energy requirement of a trip. Regenerative braking is especially effective for start-and-stop city use.

They can be finely controlled and provide high torque from stationary-to-moving, unlike internal combustion engines, and do not need multiple gears to match power curves. This removes the need for gearboxes and torque converters.

EVs provide quiet and smooth operation and consequently have less noise and vibration than internal combustion engines. While this is a desirable attribute, it has also evoked concern that the absence of the usual sounds of an approaching vehicle poses a danger to blind, elderly and very young pedestrians. To mitigate this situation, many countries mandate warning sounds when EVs are moving slowly, up to a speed when normal motion and rotation (road, suspension, electric motor, etc.) noises become audible.

Electric motors do not require oxygen, unlike internal combustion engines; this is useful for submarines and for space rovers.

Energy resilience

Electricity can be produced from a variety of sources; therefore, it gives the greatest degree of energy resilience.

Energy efficiency

EV 'tank-to-wheels' efficiency is about a factor of three higher than internal combustion engine vehicles. Energy is not consumed while the vehicle is stationary, unlike internal combustion engines which consume fuel while idling. In 2022, EVs enabled a net reduction of about 80 Mt of GHG emissions, on a well to-wheels basis, and the net GHG benefit of EVs will increase over time as the electricity sector is decarbonised.

Well-to-wheel efficiency of an EV has less to do with the vehicle itself and more to do with the method of electricity production. A particular EV would instantly become twice as efficient if electricity production were switched from fossil fuels to renewable energy, such as wind power, tidal power, solar power, and nuclear power. Thus, when "well-to-wheels" is cited, the discussion is no longer about the vehicle, but rather about the entire energy supply infrastructure – in the case of fossil fuels this should also include energy spent on exploration, mining, refining, and distribution.

The lifecycle analysis of EVs shows that even when powered by the most carbon-intensive electricity in Europe, they emit less greenhouse gases than a conventional diesel vehicle.

Total cost

As of 2021 the purchase price of an EV is often more, but the total cost of ownership of an EV varies wildly depending on location and distance travelled per year: in parts of the world where fossil fuels are subsidized, lifecycle costs of diesel or gas-powered vehicle are sometimes less than a comparable EV.

European carmakers face significant pressure from more affordable Chinese models and price cuts by US-based Tesla Motor. From 2021 to 2022, the European market share of Chinese EV manufacturers doubled to almost 9%, prompting the CEO of Stellantis to describe it as an "invasion".

Range

Main articles: All-electric range and range anxiety

Electric vehicles may have shorter range compared to vehicles with internal combustion engines, which is why the electrification of long-distance transport, such as long-distance shipping, remains challenging.

In 2022, the sales-weighted average range of small BEVs sold in the United States was nearly 350 km, while in France, Germany and the United Kingdom it was just under 300 km, compared to under 220 km in China.

Heating of EVs

Well insulated cabins can heat the vehicle using the body heat of the passengers. This is not enough, however, in colder climates as a driver delivers only about 100 W of heating power. A heat pump system, capable of cooling the cabin during summer and heating it during winter, is an efficient way of heating and cooling EVs. For vehicles which are connected to the grid, battery EVs can be preheated, or cooled, with little or no need for battery energy, especially for short trips. Most new electric cars come with heat pumps as standard.

Electric public transit efficiency

One of the few trolleybuses in Europe, this trolleybus uses two overhead wires to provide electric current supply and return to the power source, 2005

Shifts from private to public transport (train, trolleybus, personal rapid transit or tram) have the potential for large gains in efficiency in terms of an individual's distance traveled per kWh.

Research shows people prefer trams to buses, because they are quieter and more comfortable and perceived as having higher status. Therefore, it may be possible to cut liquid fossil fuel consumption in cities through the use of electric trams. Trams may be the most energy-efficient form of public transportation, with rubber-wheeled vehicles using two-thirds more energy than the equivalent tram, and run on electricity rather than fossil fuels.

In terms of net present value, they are also the cheapest – Blackpool trams are still running after 100 years, but combustion buses only last about 15 years.

Accident rate

Research published in the British Medical Journal indicates that electric cars hit pedestrians at twice the rate of petrol or diesel vehicles due to being quieter.

Government incentivization

Main article: Government incentives for plug-in electric vehicles See also: Electric car use by country

The IEA suggests that taxing inefficient internal combustion engine vehicles could encourage adoption of EVs, with taxes raised being used to fund subsidies for EVs. Government procurement is sometimes used to encourage national EV manufacturers. Many countries will ban sales of fossil fuel vehicles between 2025 and 2040.

Many governments offer incentives to promote the use of electric vehicles, with the goals of reducing air pollution and oil consumption. Some incentives intend to increase purchases of electric vehicles by offsetting the purchase price with a grant. Other incentives include lower tax rates or exemption from certain taxes, and investment in charging infrastructure.

Companies selling EVs have partnered with local electric utilities to provide large incentives on some electric vehicles.

Future

Rimac Concept One, electric supercar, since 2013. 0 to 100 km/h in 2.8 seconds, with a total output of 800 kW (1,073 hp).

Public perception

A European survey based on climate found that as of 2022, 39% of European citizens tend to prefer hybrid vehicles, 33% prefer petrol or diesel vehicles, followed by electric cars which were preferred by 28% of Europeans. 44% Chinese car buyers are the most likely to buy an electric car, while 38% of Americans would opt for a hybrid car, 33% would prefer petrol or diesel, while only 29% would go for an electric car.

In a 2023 survey concentrated specifically on electric car ownership in the US, 50% of respondents planning to purchase a future car considered themselves unlikely to seriously consider buying an EV. The survey also found that support for banning the production of non-electric vehicles in the US by 2035 has declined from 47% to 40%.

Survey results showing that for American and European respondents, price is the main barrier to buying an electric vehicle.

Environmental considerations

See also: Environmental footprint of electric cars

By reducing types of air pollution, such as nitrogen dioxide, EVs could prevent hundreds of thousands of early deaths every year, especially from trucks and traffic in cities.

The full environmental impact of electric vehicles includes the life cycle impacts of carbon and sulfur emissions, as well as toxic metals entering the environment.

Rare-earth metals (neodymium, dysprosium) and other mined metals (copper, nickel, iron) are used by EV motors, while lithium, cobalt, manganese are used by the batteries. In 2023 the US State Department said that the supply of lithium would need to increase 42-fold by 2050 globally to support a transition to clean energy. Most of the lithium-ion battery production occurs in China, where the bulk of energy used is supplied by coal burning power plants. A study of hundreds of cars on sale in 2021 concluded that the life cycle GHG emissions of full electric cars are slightly less than hybrids and that both are less than gasoline and diesel fuelled cars.

An alternative method of sourcing essential battery materials being deliberated by the International Seabed Authority is deep sea mining, however carmakers are not using this as of 2023.

Improved batteries

Advances in lithium-ion batteries, driven at first by the personal-use electronics industry, allow full-sized, highway-capable EVs to travel nearly as far on a single charge as conventional cars go on a single tank of gasoline. Lithium batteries have been made safe, can be recharged in minutes instead of hours (see recharging time), and now last longer than the typical vehicle (see lifespan). The production cost of these lighter, higher-capacity lithium-ion batteries is gradually decreasing as the technology matures and production volumes increase. Research is also underway to improve battery reuse and recycling, which would further reduce the environmental impact of batteries.

The same survey showing that if the respondents had to change cars, Chinese respondents are more likely to opt for an electric one.

Many companies and researchers are also working on newer battery technologies, including solid state batteries and alternate technologies.

Battery management and intermediate storage

Another improvement is to decouple the electric motor from the battery through electronic control, using supercapacitors to buffer large but short power demands and regenerative braking energy. The development of new cell types combined with intelligent cell management improved both weak points mentioned above. The cell management involves not only monitoring the health of the cells but also a redundant cell configuration (one more cell than needed). With sophisticated switched wiring, it is possible to condition one cell while the rest are on duty.

Electric trucks

This section is an excerpt from Electric truck.
Electric Renault Midlum used by Nestlé in 2015
Auto Electric Truck, 1907

An electric truck is a battery electric vehicle (BEV) designed to transport cargo, carry specialized payloads, or perform other utilitarian work.

Electric trucks have serviced niche applications like milk floats, pushback tugs and forklifts for over a hundred years, typically using lead-acid batteries, but the rapid development of lighter and more energy-dense battery chemistries in the twenty-first century has broadened the range of applicability of electric propulsion to trucks in many more roles.

Electric trucks reduce noise and pollution, relative to internal-combustion trucks. Due to the high efficiency and low component-counts of electric power trains, no fuel burning while idle, and silent and efficient acceleration, the costs of owning and operating electric trucks are dramatically lower than their predecessors. According to the United States Department of Energy, the average cost per kWh capacity of battery packs for trucks fell from $500 in 2013 to $200 in 2019, and still further to $137 in 2020, with some vehicles under $100 for the first time.

Long-distance freight has been the trucking segment least amenable to electrification, since the increased weight of batteries, relative to fuel, detracts from payload capacity, and the alternative, more frequent recharging, detracts from delivery time. By contrast, short-haul urban delivery has been electrified rapidly, since the clean and quiet nature of electric trucks fit well with urban planning and municipal regulation, and the capacities of reasonably sized batteries are well-suited to daily stop-and-go traffic within a metropolitan area.

In South Korea, electric trucks hold a noticeable share of the new truck market; in 2020, among trucks produced and sold domestically (which are the vast majority of new trucks sold in the country), 7.6% were all-electric vehicles.

Hydrogen trains

Particularly in Europe, fuel-cell electric trains are gaining in popularity to replace diesel-electric units. In Germany, several Länder have ordered Alstom Coradia iLINT trainsets, in service since 2018, with France also planning to order trainsets. The United Kingdom, the Netherlands, Denmark, Norway, Italy, Canada and Mexico are equally interested. In France, the SNCF plans to replace all its remaining diesel-electric trains with hydrogen trains by 2035. In the United Kingdom, Alstom announced in 2018 their plan to retrofit British Rail Class 321 trainsets with fuel cells.

Higher voltage outlets in garages of newly built homes

See also: NEMA connectors
NEMA 14-50 240v 50 amps

In New Mexico the government is looking to pass legislation mandating electrical receptacles that are higher voltage to be installed in garages of newly built homes. The NEMA 14-50 outlets provide 240 volts and 50 Amps for a total of 12.5 Kilowatts for level 2 charging of electric vehicles. Level 2 charging can add up to 30 miles of range per hour of charging compared to up to 4 miles of range per hour for level 1 charging from 120 volt outlets.

Bidirectional charging

General Motors (GM) is adding a capability called V2H, or bidirectional charging, to allow its new electric vehicles to send power from their batteries to the owner's home. GM will start with 2024 models, including the Silverado and Blazer EVs, and promises to continue the feature through to model year 2026. This could be helpful to the owner during unexpected power grid outages because an electric vehicle is a giant battery on wheels.

Infrastructure management

With the increase in number of electric vehicles, it is necessary to create an appropriate number of charging stations to supply the increasing demand, and a proper management system that coordinates the charging turn of each vehicle to avoid having some charging stations overloaded with vehicles and others empty.

Stabilization of the grid

Vehicle-to-grid (V2G) charger where energy can flow back into the grid if needed

Since EVs can be plugged into the electric grid when not in use, battery-powered vehicles could reduce the need for dispatchable generation by feeding electricity into the grid from their batteries during periods of high demand and low supply (such as just after sunset) while doing most of their charging at night or midday, when there is unused generating capacity. This vehicle-to-grid (V2G) connection has the potential to reduce the need for new power plants, as long as vehicle owners do not mind reducing the life of their batteries, by being drained by the power company during peak demand. Electric vehicle parking lots can provide demand response.

Current electricity infrastructure may need to cope with increasing shares of variable-output power sources such as wind and solar. This variability could be addressed by adjusting the speed at which EV batteries are charged, or possibly even discharged.

Some concepts see battery exchanges and battery charging stations, much like gas/petrol stations today. These will require enormous storage and charging potentials, which could be manipulated to vary the rate of charging, and to output power during shortage periods, much as diesel generators are used for short periods to stabilize some national grids.

Repair shops

The infrastructure for vehicle repairs after accidents is a concern for insurers and mechanics due to safety requirements. Batteries and other components must be carefully evaluated rather than being totally written off by insurers.

See also

Notes

References

  1. "Glossary — Global Warming of 1.5 ºC". Retrieved 4 September 2024.
  2. Guarnieri, M. (2012). "Looking back to electric cars". 2012 Third IEEE HISTory of ELectro-technology CONference (HISTELCON). pp. 1–6. doi:10.1109/HISTELCON.2012.6487583. ISBN 978-1-4673-3078-7. S2CID 37828220.
  3. Bellis, Mary (16 June 2010). "Inventors – Electric Cars (1890–1930)". Inventors.about.com. Archived from the original on 4 July 2021. Retrieved 26 December 2010.
  4. "History of Railway Electric Traction". Mikes.railhistory.railfan.net. Archived from the original on 24 August 2018. Retrieved 26 December 2010.
  5. Hendry, Maurice M. Studebaker: One can do a lot of remembering in South Bend. New Albany, Indiana: Automobile Quarterly. pp. 228–275. Vol X, 3rd Q, 1972. p231
  6. ^ Taalbi, Josef; Nielsen, Hana (2021). "The role of energy infrastructure in shaping early adoption of electric and gasoline cars". Nature Energy. 6 (10): 970–976. Bibcode:2021NatEn...6..970T. doi:10.1038/s41560-021-00898-3. ISSN 2058-7546. S2CID 242383930.
  7. pp.8–9 Batten, Chris Ambulances Osprey Publishing, 4 March 2008
  8. "Escaping Lock-in: the Case of the Electric Vehicle". Cgl.uwaterloo.ca. Archived from the original on 23 September 2015. Retrieved 26 December 2010.
  9. AAA World Magazine. Jan–Feb 2011, p. 53
  10. Kirsch, David (2000). The electric vehicle and the burden of history. Rutgers University Press.
  11. Mom, Gijs (15 February 2013). The Electric Vehicle: Technology and Expectations in the Automobile Age. JHU Press. ISBN 978-1-4214-1268-9.
  12. See Loeb, A.P., "Steam versus Electric versus Internal Combustion: Choosing the Vehicle Technology at the Start of the Automotive Age," Transportation Research Record, Journal of the Transportation Research Board of the National Academies, No. 1885, at 1.
  13. Automobile, archived from the original on 30 April 2015, retrieved 18 July 2009
  14. Scharff, Virginia (1992). Taking the Wheel: Women and the Coming of the Motor Age. Univ. New Mexico Press.
  15. Matthe, Roland; Eberle, Ulrich (1 January 2014). The Voltec System – Energy Storage and Electric Propulsion. Elsevier Science. pp. 151–176. ISBN 978-0-444-59513-3. Archived from the original on 9 October 2020. Retrieved 4 May 2014.
  16. Bellis, M. (2006), "The Early Years", The History of Electric Vehicles, About.com, archived from the original on 4 July 2021, retrieved 6 July 2006
  17. "Net Zero Coalition". United Nations. Retrieved 2 December 2022.
  18. Quiroga, Tony (August 2009). Driving the Future. Hachette Filipacchi Media U.S., Inc. p. 52.
  19. Freeman, Sunny (9 December 2009). "The end of Zenn". The Globe and Mail. Toronto. Retrieved 25 May 2022.
  20. "Global EV Outlook 2023 / Trends in electric light-duty vehicles". International Energy Agency. April 2023. Archived from the original on 12 May 2023.
  21. Data from McKerracher, Colin (12 January 2023). "Electric Vehicles Look Poised for Slower Sales Growth This Year". BloombergNEF. Archived from the original on 12 January 2023.
  22. Eberle, Ulrich; von Helmolt, Rittmar (14 May 2010). "Sustainable transportation based on EV concepts: a brief overview". Energy & Environmental Science. 3 (6): 689. doi:10.1039/c001674h. ISSN 1754-5692. Archived from the original on 21 October 2013. Retrieved 8 June 2010.
  23. Balcioglu, Yavuz Selim; Sezen, Bülent; İşler, Ali Ulvi (20 June 2024). "Evolving preferences in sustainable transportation: a comparative analysis of consumer segments for electric vehicles across Europe". Social Responsibility Journal. doi:10.1108/SRJ-12-2023-0713. ISSN 1747-1117.
  24. Notter, Dominic A.; Kouravelou, Katerina; Karachalios, Theodoros; Daletou, Maria K.; Haberland, Nara Tudela (3 July 2015). "Life cycle assessment of PEM FC applications: electric mobility and μ-CHP". Energy Environ. Sci. 8 (7): 1969–1985. doi:10.1039/C5EE01082A. ISSN 1754-5692.
  25. Notter, Dominic A.; Gauch, Marcel; Widmer, Rolf; Wäger, Patrick; Stamp, Anna; Zah, Rainer; Althaus, Hans-Jörg (1 September 2010). "Contribution of Li-Ion Batteries to the Environmental Impact of Electric Vehicles". Environmental Science & Technology. 44 (17): 6550–6556. Bibcode:2010EnST...44.6550N. doi:10.1021/es903729a. ISSN 0013-936X. PMID 20695466.
  26. "World's first electrified road for charging vehicles opens in Sweden". Guardian. 12 April 2018. Archived from the original on 1 September 2019. Retrieved 1 September 2019.
  27. Richardson, D.B. (March 2013). "Electric vehicles and the electric grid: A review of modeling approaches, Impacts, and renewable energy integration". Renewable and Sustainable Energy Reviews. 19: 247–254. doi:10.1016/j.rser.2012.11.042.
  28. Liu, Chaofeng; Neale, Zachary G.; Cao, Guozhong (1 March 2016). "Understanding electrochemical potentials of cathode materials in rechargeable batteries". Materials Today. 19 (2): 109–123. doi:10.1016/j.mattod.2015.10.009.
  29. ^ "Race to Net Zero: The Pressures of the Battery Boom in Five Charts". 21 July 2022. Archived from the original on 7 September 2023.
  30. Medimorec, Nikola (8 February 2013). "Namsan E-Bus, First Commercial Electric Bus Worldwide". Kojects.
  31. Armand, Michel; Axmann, Peter; Bresser, Dominic; Copley, Mark; Edström, Kristina; Ekberg, Christian; Guyomard, Dominique; Lestriez, Bernard; Novák, Petr; Petranikova, Martina; Porcher, Willy; Trabesinger, Sigita; Wohlfahrt-Mehrens, Margret; Zhang, Heng (15 December 2020). "Lithium-ion batteries – Current state of the art and anticipated developments". Journal of Power Sources. 479: 228708. Bibcode:2020JPS...47928708A. doi:10.1016/j.jpowsour.2020.228708. ISSN 0378-7753. S2CID 225154703.
  32. Lu, L.; Han, X.; Li, J.; Hua, J.; Ouyang, M. (2013). "A review on the key issues for lithium-ion battery management in electric vehicles". Journal of Power Sources. 226: 272–288. Bibcode:2013JPS...226..272L. doi:10.1016/j.jpowsour.2012.10.060. ISSN 0378-7753.
  33. Adany, Ron (June 2013). "Switching algorithms for extending battery life in Electric Vehicles". Journal of Power Sources. 231: 50–59. doi:10.1016/j.jpowsour.2012.12.075. ISSN 0378-7753.
  34. Mok, Brian. "Types of Batteries Used for Electric Vehicles". large.stanford.edu. Archived from the original on 19 December 2017. Retrieved 30 November 2017.
  35. "Alternative Fuels Data Center: Batteries for Hybrid and Plug-In Electric Vehicles". afdc.energy.gov. AFDC. Archived from the original on 1 December 2017. Retrieved 30 November 2017.
  36. "Chevron and EVs – GM, Chevron and CARB killed the sole NiMH EV once, will do so again". ev1.org. Archived from the original on 22 November 2017. Retrieved 30 November 2017.
  37. Aditya, Jayam; Ferdowsi, Mehdi. "Comparison of NiMH and Li-Ion Batteries in Automotive Applications". Power Electronics and Motor Drives Laboratory. Archived from the original on 1 December 2017. Retrieved 30 November 2017.
  38. "Global EV Outlook 2023 – Data product". IEA. Retrieved 30 June 2023.
  39. "Bloomberg's Latest Forecast Predicts Rapidly Falling Battery Prices". 21 June 2018. Archived from the original on 8 January 2019. Retrieved 4 January 2019.
  40. Voelcker, John (10 April 2021). "EVs Explained: Charging Losses". Car and Driver. Archived from the original on 27 July 2021. Retrieved 27 July 2021.
  41. Widmar, Martin (2015). "Electric vehicle traction motors without rare earth magnets". Sustainable Materials and Technologies. 3: 7–13. doi:10.1016/j.susmat.2015.02.001. ISSN 2214-9937.
  42. "Electric Driveline Technology – PVI, leader de la traction électrique pour véhicules industriels". Pvi.fr. Archived from the original on 25 March 2012. Retrieved 30 March 2012.
  43. Yakub, Mehanaz (25 September 2024). "Lion Electric, CAA-Quebec deploy North America's first e-tow truck". Electric Autonomy Canada. Retrieved 17 October 2024.
  44. "History of Hybrid Vehicles". HybridCars.com. 27 March 2006. Archived from the original on 8 February 2009. Retrieved 21 March 2010.
  45. "Alternative Fuels Data Center: How do Hybrid Electric Cars Work?".
  46. Spendiff-Smith, Matthew (18 March 2022). "Electric Vehicles Types – A Complete Guide to Types of EV – EVESCO". Power Sonic.
  47. ^ Dan Mihalascu (4 November 2022). "Turkey's National Carmaker Togg Starts Production Of 2023 C SUV EV". insideevs.com.
  48. "TOGG Official Website". togg.com.tr. Retrieved 3 April 2020.
  49. Jay Ramey (30 December 2019). "Turkey Bets on EVs with the Pininfarina-Designed TOGG". autoweek.com.
  50. "'A game changer': Türkiye inaugurates its first national car plant". TRT World. 30 October 2022.
  51. David B. Sandalow, ed. (2009). Plug-In Electric Vehicles: What Role for Washington? (1st. ed.). The Brookings Institution. pp. 2–5. ISBN 978-0-8157-0305-1. Archived from the original on 28 March 2019. Retrieved 7 July 2013. See definition on pp. 2.
  52. "Plug-in Electric Vehicles (PEVs)". Center for Sustainable Energy, California. Archived from the original on 20 June 2010. Retrieved 31 March 2010.
  53. "PEV Frequently Asked Questions". Duke Energy. Archived from the original on 27 March 2012. Retrieved 24 December 2010.
  54. "Electric road vehicles in the European Union" (PDF). europa.eu. Archived (PDF) from the original on 14 February 2020. Retrieved 24 October 2020.
  55. "-Maglev Technology Explained". North American Maglev Transport Institute. 1 January 2011. Archived from the original on 27 July 2011.
  56. "Oceanvolt – Complete Electric Motor Systems". Oceanvolt. Archived from the original on 24 December 2012. Retrieved 30 November 2012.
  57. Stensvold, Tore. "Lønnsomt å bytte ut 70 prosent av fergene med batteri- eller hybridferger Archived 5 January 2016 at the Wayback Machine" Teknisk Ukeblad, 14. August 2015.
  58. "S-80: A Sub, for Spain, to Sail Out on the Main". Defense Industry Daily. 15 December 2008. Archived from the original on 24 February 2010. Retrieved 17 December 2009.
  59. "Ports of Auckland Sparky: The 200 Best Inventions of 2022". Time. 10 November 2022. Retrieved 26 March 2024.
  60. Mandra, Jasmina Ovcina (27 October 2023). "Electrifying Debut: HaiSea Wamis completes its 1st tanker escort with full electric power". Offshore Energy. Retrieved 26 March 2024.
  61. "The little (electric) engine that could: The Port of San Diego unveils the nation's first all-electric tug boat". San Diego Union-Tribune. 11 March 2024. Retrieved 26 March 2024.
  62. "Contributions to Deep Space 1". 14 April 2015. Archived from the original on 10 December 2004. Retrieved 4 August 2016.
  63. Cybulski, Ronald J.; Shellhammer, Daniel M.; Lovell, Robert R.; Domino, Edward J.; Kotnik, Joseph T. (1965). "Results from SERT I Ion Rocket Flight Test" (PDF). NASA. NASA-TN-D-2718. Archived (PDF) from the original on 12 November 2020. Retrieved 12 November 2020.
  64. Lyons, Pete; "10 Best Ahead-of-Their-Time Machines", Car and Driver, Jan. 1988, p.78
  65. "Technologies of Broad Benefit: Power". Archived from the original on 18 January 2017. Retrieved 6 September 2018.
  66. "Soviet Union Lunar Rovers". Archived from the original on 2 November 2018. Retrieved 6 September 2018.
  67. Ulrich, Lawrence. "Rimac Nevera EV Sets 23 World Speed Records: Zero to 400 kilometers per hour and back again in under 30 seconds was just one of them". IEEE Spectrum.
  68. Doll, Scooter. "Rimac Nevera electric hypercar sets 23 records in single day, including fastest 0–249 mph time". Electrek.
  69. Addow, Amina. "Electric car goes from 0 to 100 km/h in 1.461 seconds". Guinness World Records.
  70. "interestingengineering.com". November 2021.
  71. Holl, Maximilian (5 July 2019). "Tesla Model 3 Breaks World EV Distance Record — 2,781 km (1,728 mi) Travelled in 24 Hours". CleanTechnica. Retrieved 15 May 2022.
  72. "Greatest distance by electric vehicle, single charge (non-solar)". Guinness World Records. 16 October 2017. Retrieved 15 May 2022.
  73. Jamieson, Craig. "This solar-powered EV is a world-record-breaking speed machine*". BBC Top Gear. BBC Studios.
  74. "Harley-Davidson's LiveWire EV | GreenCars". www.greencars.com. Retrieved 15 May 2022.
  75. Toll, Micah (29 August 2020). "Believe it or not, this electric plane is set to break 7 world records in one trip". Electrek. Retrieved 15 May 2022.
  76. Seitz, C.W. (May 1994). "Industrial battery technologies and markets". IEEE Aerospace and Electronic Systems Magazine. 9 (5): 10–15. doi:10.1109/62.282509. ISSN 0885-8985. Retrieved 3 September 2022.
  77. Tofield, Bruce C. (1985). "Future Prospects for All-Solid-State Batteries". Solid State Batteries. Springer Netherlands. p. 424. doi:10.1007/978-94-009-5167-9_29. ISBN 978-94-010-8786-5. Retrieved 3 September 2022.
  78. "EVO Report 2021 | BloombergNEF | Bloomberg Finance LP". BloombergNEF. Archived from the original on 27 July 2021. Retrieved 27 July 2021.
  79. Dobley, Arthur (2013). "1: Catalytic Batteries". In Suib, Steven (ed.). New and Future Developments in Catalysis: Batteries, Hydrogen Storage and Fuel Cells. Elsevier. p. 13. ISBN 9780444538819. Retrieved 29 October 2022.
  80. Francisco J. Márquez-Fernández (20 May 2019), Power conversion challenges with an all-electric land transport system (PDF), Swedish Electromobility Centre
  81. D Bateman; et al. (8 October 2018), Electric Road Systems: a solution for the future (PDF), TRL, archived from the original (PDF) on 3 August 2020, retrieved 19 November 2019
  82. Kwak Yeon-soo (24 March 2019). "ICT minister nominee accused of wasting research money". The Korea Times.
  83. Ed Targett (20 September 2016), Who Killed the Electric Highway?
  84. Steven Pinkerton-Clark (22 June 2022), DynaCoV - Dynamic Charging of Vehicles - Project closedown report (PDF)
  85. Björn Hasselgren (9 October 2019), Swedish ERS - program background, current analysis phase and plans ahead (PDF), Swedish Transport Administration
  86. "Vi avbryter upphandlingen för Sverige första permanenta elväg", Trafikverket, 28 August 2023
  87. Trafikverket (2 December 2024), Arbetet med Sveriges första permanenta elväg pausas
  88. Kenneth Natanaelsson (29 November 2024), Planeringsunderlag elväg (PDF), Trafikverket
  89. A. Wendt et al., "Wireless Electric Road Systems – Technology Readiness and Recent Developments," 2024 IEEE Wireless Power Technology Conference and Expo (WPTCE), Kyoto, Japan, 2024, pp. 177-182, doi: 10.1109/WPTCE59894.2024.10557264.
  90. Bilanz E-Highway: Lastwagen können Hälfte an CO2 sparen, DPA, 1 March 2024
  91. Adrian Mahler (12 April 2024), "Verlängerung der Laufzeit wird das eWayBW-Pilotprojekt nicht retten", BNN.DE
  92. Adrian Mahler (18 March 2024), "Kritik der FDP: eWayBW-Oberleitung verhindert Landung von Rettungshelikopter auf B462", BNN.DE
  93. Marc Fressoz (9 May 2024), "Les autoroutiers divisés sur les solutions à mettre en place pour faire rouler des camions électriques", L'USINENOUVELLE.com
  94. Laurent Miguet (28 April 2022), "Sur les routes de la mobilité électrique", Le Moniteur
  95. Choi, Yun Seok; Kim, Seok; Choi, Soo Seok; Han, Ji Sung; Kim, Jan Dee; Jeon, Sang Eun; Jung, Bok Hwan (30 November 2004). "Electrochimica Acta : Effect of cathode component on the energy density of lithium–sulfur battery". Electrochimica Acta. 50 (2–3): 833–835. doi:10.1016/j.electacta.2004.05.048.
  96. ^ "Global EV Outlook 2023 – Analysis". IEA. 26 April 2023. Retrieved 5 July 2023.
  97. "EUROPA Press Releases – Car safety: European Commission welcomes international agreement on electric and hybrid cars". Europa (web portal). 10 March 2010. Archived from the original on 16 April 2010. Retrieved 26 June 2010.
  98. Ziegler, Micah S.; Trancik, Jessika E. (2021). "Re-examining rates of lithium-ion battery technology improvement and cost decline". Energy & Environmental Science. 14 (4): 1635–1651. arXiv:2007.13920. doi:10.1039/D0EE02681F. ISSN 1754-5692. S2CID 220830992.
  99. "The price of batteries has declined by 97% in the last three decades". Our World in Data. Retrieved 26 April 2022.
  100. Garcia, Erika; Johnston, Jill; McConnell, Rob; Palinkas, Lawrence; Eckel, Sandrah P. (1 April 2023). "California's early transition to electric vehicles: Observed health and air quality co-benefits". Science of the Total Environment. 867: 161761. Bibcode:2023ScTEn.867p1761G. doi:10.1016/j.scitotenv.2023.161761. ISSN 0048-9697. PMC 10465173. PMID 36739036. S2CID 256572849.
  101. 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.
  102. 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.
  103. "A global comparison of the life-cycle greenhouse gas emissions of combustion engine and electric passenger cars | International Council on Clean Transportation". theicct.org. Archived from the original on 9 November 2021. Retrieved 29 July 2021.
  104. Choma, Ernani F.; Evans, John S.; Hammitt, James K.; Gómez-Ibáñez, José A.; Spengler, John D. (1 November 2020). "Assessing the health impacts of electric vehicles through air pollution in the United States". Environment International. 144: 106015. Bibcode:2020EnInt.14406015C. doi:10.1016/j.envint.2020.106015. ISSN 0160-4120. PMID 32858467.
  105. Gössling, Stefan (3 July 2020). "Why cities need to take road space from cars – and how this could be done". Journal of Urban Design. 25 (4): 443–448. doi:10.1080/13574809.2020.1727318. ISSN 1357-4809.
  106. "e-bike carbon savings – how much and where? – CREDS". 18 May 2020. Archived from the original on 13 April 2021. Retrieved 13 April 2021.
  107. "Electric Cars Need Way Less Raw Materials Than ICE Vehicles". InsideEVs. Archived from the original on 28 July 2021. Retrieved 28 July 2021.
  108. ^ Agusdinata, Datu Buyung; Liu, Wenjuan; Eakin, Hallie; Romero, Hugo (27 November 2018). "Socio-environmental impacts of lithium mineral extraction: towards a research agenda". Environmental Research Letters. 13 (12): 123001. Bibcode:2018ERL....13l3001B. doi:10.1088/1748-9326/aae9b1. ISSN 1748-9326.
  109. Schöggl, Josef-Peter; Fritz, Morgane M.C.; Baumgartner, Rupert J. (September 2016). "Toward supply chain-wide sustainability assessment: a conceptual framework and an aggregation method to assess supply chain performance". Journal of Cleaner Production. 131: 822–835. doi:10.1016/j.jclepro.2016.04.035. ISSN 0959-6526.
  110. ^ "Electric car batteries need far less raw materials than fossil-fuel cars – study Archived 2 November 2021 at the Wayback Machine". transportenvironment.org. Retrieved 1 November 2021.
  111. "Batteries and secure energy transitions". Paris: IEA. 2024.
  112. "Energy Technology Perspectives 2023 – Analysis". IEA. 12 January 2023. Retrieved 30 June 2023.
  113. "Myths Shattered: The Truth About Electric Cars in Today's Auto Industry". Greenpeace international. Retrieved 21 November 2023.
  114. Rick, Mills (4 March 2024). "Indonesia and China killed the nickel market". MINING.COM.
  115. "Land grabs and vanishing forests: Are 'clean' electric vehicles to blame?". Al Jazeera. 14 March 2024.
  116. "Indonesia's massive metals build-out is felling the forest for batteries". AP News. 15 July 2024.
  117. "EU faces green dilemma in Indonesian nickel". Deutsche Welle. 16 July 2024.
  118. "How 'modern-day slavery' in the Congo powers the rechargeable battery economy". NPR. 1 February 2023.
  119. Mitchell G, Dorling D. An Environmental Justice Analysis of British Air Quality. Environment and Planning A: Economy and Space. 2003;35(5):909–929. doi:10.1068/a35240
  120. Barnes, Joanna H.; Chatterton, Tim J.; Longhurst, James W.S. (August 2019). "Emissions vs exposure: Increasing injustice from road traffic-related air pollution in the United Kingdom". Transportation Research Part D: Transport and Environment. 73: 56–66. doi:10.1016/j.trd.2019.05.012. S2CID 197455092.
  121. "Better Place" (PDF).
  122. ^ "Transport: Electric vehicles". European Commission. Archived from the original on 19 March 2011. Retrieved 19 September 2009.
  123. "Nissan Adds 'Beautiful' Noise to Make Silent Electric Cars Safe". Bloomberg L.P. 18 September 2009. Retrieved 12 February 2010.
  124. "Our Electric Future – The American, A Magazine of Ideas". American.com. Archived from the original on 25 August 2014. Retrieved 26 December 2010.
  125. Lepetit, Yoann (October 2017). "Electric vehicle life cycle analysis and raw material availability" (PDF). Transport & Environment. Archived (PDF) from the original on 23 February 2018. Retrieved 22 February 2018.
  126. "2020 European total cost of ownership for electric vehicles vs internal combustion engine vehicles | Nickel Institute". nickelinstitute.org. Archived from the original on 26 July 2021. Retrieved 26 July 2021.
  127. "Electric cars already cheapest option today for many consumers, new study finds | www.beuc.eu". www.beuc.eu. Archived from the original on 26 July 2021. Retrieved 26 July 2021.
  128. "Trends and developments in electric vehicle markets – Global EV Outlook 2021 – Analysis". IEA. Archived from the original on 26 July 2021. Retrieved 26 July 2021.
  129. Guillaume, Gilles; Piovaccari, Giulio (27 July 2023). "Western car makers look to slash EV costs to fight Chinese 'invasion'". Reuters.
  130. "Explaining Electric & Plug-In Hybrid Electric Vehicles | US EPA". US EPA. 17 August 2015. Archived from the original on 12 June 2018. Retrieved 8 June 2018.
  131. "Electric vehicle price is rising, but cost-per-mile is falling". Ars Technica. Archived from the original on 4 June 2018. Retrieved 8 June 2018.
  132. Beedham, Matthew (3 February 2021). "What's a heat pump and why do EVs use them?". TNW | Shift. Archived from the original on 28 July 2021. Retrieved 28 July 2021.
  133. "Heat pumps in electric vehicles: What are they for? | Inquieto". 26 July 2023. Retrieved 5 November 2023.
  134. "Trams, energy saving, private cars, trolley buses, diesel buses | Claverton Group". Claverton-energy.com. 28 May 2009. Archived from the original on 19 September 2009. Retrieved 19 September 2009.
  135. Lesley, Lewis (October 2008). "Sustainable light rail". Claverton Group. Archived from the original on 16 September 2009. Retrieved 19 September 2009.
  136. "Blackpool Trams – Then and Now". Live Blackpool. 9 September 2020. Archived from the original on 30 October 2020. Retrieved 26 November 2020.
  137. Searles, Michael (22 May 2024). "Electric cars 'hit pedestrians at twice the rate of petrol or diesel vehicles'". The Telegraph. ISSN 0307-1235. Archived from the original on 14 June 2024. Retrieved 13 June 2024.
  138. "EESL to procure 10,000 Electric Vehicles from TATA Motors". Press Information Bureau. 29 September 2017. Archived from the original on 8 February 2018. Retrieved 7 February 2018.
  139. Balachandran, Manu (6 October 2017). "As India revs up its grand electric vehicles plan, Tata and Mahindra are in the driver's seat". Quartz. Archived from the original on 8 February 2018. Retrieved 7 February 2018.
  140. Azeez, Walé (12 May 2021). "5 things to know about the future of electric vehicles". World Economic Forum. Archived from the original on 16 June 2021. Retrieved 7 June 2021.
  141. "Accelerating the Transition to Electric School Buses". U.S. PIRG Education Fund. 1 February 2021. Archived from the original on 29 July 2021. Retrieved 29 July 2021.
  142. ^ "2021–2022 EIB Climate Survey, part 2 of 3: Shopping for a new car? Most Europeans say they will opt for hybrid or electric". European Investment Bank. Retrieved 4 April 2022.
  143. Spencer, Alison; Ross, Stephanie; Tyson, Alec. "How Americans view electric vehicles". Pew Research Center. Retrieved 9 December 2023.
  144. ^ Bank, European Investment (5 June 2023). The EIB Climate Survey: Government action, personal choices and the green transition. European Investment Bank. ISBN 978-92-861-5535-2.
  145. "Zeroing in on Healthy Air". American Lung Association. 2022.
  146. Xiong, Ying; Partha, Debatosh; Prime, Noah; Smith, Steven J; Mariscal, Noribeth; Salah, Halima; Huang, Yaoxian (1 October 2022). "Long-term trends of impacts of global gasoline and diesel emissions on ambient PM 2.5 and O 3 pollution and the related health burden for 2000–2015". Environmental Research Letters. 17 (10): 104042. Bibcode:2022ERL....17j4042X. doi:10.1088/1748-9326/ac9422. ISSN 1748-9326. S2CID 252471791.
  147. Carey, John (17 January 2023). "The other benefit of electric vehicles". Proceedings of the National Academy of Sciences. 120 (3): e2220923120. Bibcode:2023PNAS..12020923C. doi:10.1073/pnas.2220923120. ISSN 0027-8424. PMC 9934249. PMID 36630449.
  148. Månberger, André; Stenqvist, Björn (August 2018). "Global metal flows in the renewable energy transition: Exploring the effects of substitutes, technological mix and development". Energy Policy. 119: 226–241. Bibcode:2018EnPol.119..226M. doi:10.1016/j.enpol.2018.04.056. S2CID 52227957.
  149. "Move to net zero 'inevitably means more mining'". BBC News. 24 May 2021. Archived from the original on 4 June 2021. Retrieved 4 June 2021.
  150. Ewing, Jack; Krauss, Clifford (20 March 2023). "Falling Lithium Prices Are Making Electric Cars More Affordable". The New York Times. ISSN 0362-4331. Retrieved 12 April 2023.
  151. Buberger, Johannes; Kersten, Anton; Kuder, Manuel; Eckerle, Richard; Weyh, Thomas; Thiringer, Torbjörn (1 May 2022). "Total CO2-equivalent life-cycle emissions from commercially available passenger cars". Renewable and Sustainable Energy Reviews. 159: 112158. doi:10.1016/j.rser.2022.112158. ISSN 1364-0321. S2CID 246758071.
  152. Halper, Evan (5 April 2023). "Unleash the deep-sea robots? A quandary as EV makers hunt for metals". Washington Post. ISSN 0190-8286. Retrieved 9 April 2023.
  153. Korosec, Kirsten. "Panasonic boosts energy density, trims cobalt in new 2170 battery cell for Tesla" Archived 29 August 2020 at the Wayback Machine, July 30, 2020
  154. "Daimler deepens CATL alliance to build long-range, fast-charging EV batteries" Archived 23 August 2020 at the Wayback Machine, Reuters, August 5, 2020; and "Porsche: The perfect cell" Archived 25 November 2020 at the Wayback Machine, Automotive World, August 28, 2020
  155. Baum, Zachary J.; Bird, Robert; Yu, Xiang; Ma, Jia (14 October 2022). "Correction to "Lithium-Ion Battery Recycling─Overview of Techniques and Trends"". ACS Energy Letters. 7 (10): 3268–3269. doi:10.1021/acsenergylett.2c01888. ISSN 2380-8195.
  156. Martinez-Laserna, E.; Gandiaga, I.; Sarasketa-Zabala, E.; Badeda, J.; Stroe, D. -I.; Swierczynski, M.; Goikoetxea, A. (1 October 2018). "Battery second life: Hype, hope or reality? A critical review of the state of the art". Renewable and Sustainable Energy Reviews. 93: 701–718. doi:10.1016/j.rser.2018.04.035. ISSN 1364-0321. S2CID 115675123.
  157. Patel, Prachi. "Ion Storage Systems Says Its Ceramic Electrolyte Could Be a Gamechanger for Solid-State Batteries", IEEE.org, February 21, 2020
  158. Lambert, Fred. "Tesla researchers show path to next-gen battery cell with breakthrough energy density" Archived 24 August 2020 at the Wayback Machine, Electrek, August 12, 2020
  159. Horn, Michael; MacLeod, Jennifer; Liu, Meinan; Webb, Jeremy; Motta, Nunzio (March 2019). "Supercapacitors: A new source of power for electric cars?" (PDF). Economic Analysis and Policy. 61: 93–103. doi:10.1016/j.eap.2018.08.003. S2CID 187458469.
  160. "Calculating the total cost of ownership for electric trucks". Transport Dive. Retrieved 27 February 2021.
  161. "Electric trucking offers fleets ergonomic efficiency potential | Automotive World". www.automotiveworld.com. 11 January 2021. Retrieved 27 February 2021.
  162. Adler, Alan (8 March 2019). "2019 Work Truck Show: Adoption of Electrification Won't be Fast". Trucks.com. Retrieved 4 April 2019.
  163. Edelstein, Stephen (17 December 2020). "EV battery pack prices fell 13% in 2020, some are already below $100/kwh". Green Car Reports. Retrieved 13 June 2021. Electric-car battery-pack prices have fallen 13% in 2020, in some cases reaching a crucial milestone for affordability, according to an annual report released Wednesday by Bloomberg New Energy Finance. Average prices have dropped from $1,100 per kilowatt-hour to $137 per kwh, decrease of 89% over the past decade, according to the analysis. At this time last year, BNEF reported an average price of $156 per kwh—itself a 13% decrease from 2018. Battery-pack prices of less than $100 per kwh were also reported for the first time, albeit only for electric buses in China, according to BNEF. The $100-per-kwh threshold is often touted by analysts as the point where electric vehicles will achieve true affordability. Batteries also achieved $100 per kwh on a per-cell basis, while packs actually came in at $126 per kwh on a volume-weighted average, BNEF noted.
  164. Domonoske, Camila (17 March 2021). "From Amazon To FedEx, The Delivery Truck Is Going Electric". National Public Radio. Retrieved 13 June 2021. All major delivery companies are starting to replace their gas-powered fleets with electric or low-emission vehicles, a switch that companies say will boost their bottom lines, while also fighting climate change and urban pollution. UPS has placed an order for 10,000 electric delivery vehicles. Amazon is buying 100,000 from the start-up Rivian. DHL says zero-emission vehicles make up a fifth of its fleet, with more to come. And FedEx just pledged to replace 100% of its pickup and delivery fleet with battery-powered vehicles.
  165. Joselow, Maxine (11 January 2020). "Delivery Vehicles Increasingly Choke Cities with Pollution". Scientific American. Retrieved 13 June 2021. Electric vehicles, delivery drones and rules on when delivery trucks can operate are some solutions proposed in a new report. The report provides 24 recommendations for policymakers and the private sector, including mandating that delivery vehicles are electric. The report notes that if policymakers care about sustainability, they may want to impose aggressive new electric vehicle regulations.
  166. Gies, Erica (18 December 2017). "Electric Trucks Begin Reporting for Duty, Quietly and Without All the Fumes". Inside Climate News. Retrieved 13 June 2021. Replacing fleets of medium- and heavy-duty trucks can help cut greenhouse gas emissions and make cities quieter and cleaner. Because trucks need so much hauling power, they have eluded electrification until recently; a battery that could pull significant weight would itself be too hefty and too expensive. But now, improvements in battery technology are paying off, bringing down both size and cost. The number of hybrid-electric and electric trucks is set to grow almost 25 percent annually, from 1 percent of the market in 2017 to 7 percent in 2027, a jump from about 40,000 electric trucks worldwide this year to 371,000.
  167. Hyundai Porter/Porter II Electric: 9037. Kia Bongo EV: 5357. Domestically produced trucks sold in the country: 188222. mk.co.kr autoview.co.kr zdnet.co.kr
  168. ^ "Germany launches world's first hydrogen-powered train". The Guardian. Agence France-Presse. 17 September 2018. Archived from the original on 17 September 2018. Retrieved 29 November 2018.
  169. "L'Occitanie, première région à commander des trains à hydrogène à Alstom". France 3 Occitanie (in French). Archived from the original on 29 November 2018. Retrieved 29 November 2018.
  170. "La constructora Alstom quiere ir por el 'tramo ecológico' del Tren Maya". El Financiero (in Spanish). Archived from the original on 29 November 2018. Retrieved 29 November 2018.
  171. "SNCF : Pépy envisage la fin des trains diesel et l'arrivée de l'hydrogène en 2035". La Tribune (in French). Archived from the original on 29 November 2018. Retrieved 29 November 2018.
  172. "SNCF : Pépy envisage la fin des trains diesel et l'arrivée de l'hydrogène en 2035". La Tribune (in French). Archived from the original on 29 November 2018. Retrieved 29 November 2018.
  173. "New Mexico law seeks solar on every roof, and an EV charger in every garage". pv magazine USA. 25 January 2023.
  174. "Buy Nema 14–50 EV Charger – Lectron". Lectron EV.
  175. "NeoCharge".
  176. General Motors will add bidirectional charging to its Ultium-based EVs by Jonathan M. Gitlin, on Ars Technica, 8/8/2023.
  177. Barbecho Bautista, Pablo; Lemus Cárdenas, Leticia; Urquiza Aguiar, Luis; Aguilar Igartua, Mónica (2019). "A traffic-aware electric vehicle charging management system for smart cities". Vehicular Communications. 20: 100188. doi:10.1016/j.vehcom.2019.100188. hdl:2117/172770. S2CID 204080912.
  178. Fernandez Pallarés, Victor; Cebollada, Juan Carlos Guerri; Martínez, Alicia Roca (2019). "Interoperability network model for traffic forecast and full electric vehicles power supply management within the smart city". Ad Hoc Networks. 93: 101929. doi:10.1016/j.adhoc.2019.101929. S2CID 196184613.
  179. Liasi, Sahand Ghaseminejad; Golkar, Masoud Aliakbar (2017). "Electric vehicles connection to microgrid effects on peak demand with and without demand response". 2017 Iranian Conference on Electrical Engineering (ICEE). pp. 1272–1277. doi:10.1109/IranianCEE.2017.7985237. ISBN 978-1-5090-5963-8. S2CID 22071272.
  180. "It's not just cars driving the EV revolution in emerging markets". www.schroders.com. Retrieved 12 April 2023. Beyond grid stabilisation benefits, smart charging of EVs, using differentiated electricity tariffs in off-peak hours, may also mitigate the pressure on electricity demand. That's because vehicles can be charged during the day, when demand is lower and renewables generation is available.
  181. Shafie-khah, Miadreza; Heydarian-Forushani, Ehsan; Osorio, Gerardo J.; Gil, Fabio A. S.; Aghaei, Jamshid; Barani, Mostafa; Catalao, Joao P. S. (November 2016). "Optimal Behavior of Electric Vehicle Parking Lots as Demand Response Aggregation Agents". IEEE Transactions on Smart Grid. 7 (6): 2654–2665. doi:10.1109/TSG.2015.2496796. ISSN 1949-3053. S2CID 715959.
  182. "It's not just cars driving the EV revolution in emerging markets". www.schroders.com. Retrieved 12 April 2023. Intermittency from solar or wind technologies can put creating voltage and frequency variations. Batteries can charge and discharge to stabilise the grid in such instances. The batteries of electric vehicles, e-buses or electric two-wheelers, while connected to the grid, could therefore play a role in protecting a grid's stability.
  183. "Engines and Gas Turbines | Claverton Group". Claverton-energy.com. 18 November 2008. Archived from the original on 6 September 2009. Retrieved 19 September 2009.
  184. National Grid's use of Emergency. Diesel Standby Generator's in dealing with grid intermittency and variability. Potential Contribution in assisting renewables Archived 17 February 2010 at the Wayback Machine, David Andrews, Senior Technical Consultant, Biwater Energy, A talk originally given by as the Energy Manager at Wessex Water at an Open University Conference on Intermittency, 24 January 2006
  185. Nick Carey; Josie Kao and Louise Heavens. (5 July 2023). "EV batteries remain major challenge for insurers – UK's Thatcham". Reuters website Retrieved 5 July 2023.
  186. Nick Carey. (27 June 2023). "UK firm Metis touts battery sensor that could ease EV scrappage problem". Reuters website Retrieved 5 July 2023.

Further reading

External links

Media related to Electrically powered vehicles at Wikimedia Commons

Motor fuels
Fuel types
Fuel additives
Fluids
Retail
Car design
Classification
By size
Custom
Luxury
Minivan / MPV
SUV
Sports
Other
EU
Body styles
Specialized
vehicles
Propulsion
Drive wheels
Engine position
Layout
(engine / drive)
Engine configuration
(internal combustion)
Alternative fuel vehicles
Fuel cell
Human power
Solar power
Compressed-air
engine
Electric battery
and motor
Biofuel ICE
Hydrogen
Others
Multiple-fuel
Documentaries
See also
Powertrain
Part of the Automobile series
Automotive engine
Transmission
Wheels and tires
Hybrid
Electric vehicles
Vehicle
Type
Charging
Connectors
AC
DC
AC/DC
Standards
WEVA
Environmental technology
General
Pollution
Sustainable energy
Conservation
Categories: