Energy storage is the capture of energy produced at one time for use at a later time to reduce imbalances between energy demand and energy production. A device that stores energy is generally called an accumulator or battery. Energy comes in multiple forms including radiation, chemical, gravitational potential, electrical potential, electricity, elevated temperature, latent heat and kinetic. Energy storage involves converting energy from forms that are difficult to store to more conveniently or economically storable forms.
Some technologies provide short-term energy storage, while others can endure for much longer. Bulk energy storage is currently dominated by hydroelectric dams, both conventional as well as pumped. Grid energy storage is a collection of methods used for energy storage on a large scale within an electrical power grid.
Common examples of energy storage are the rechargeable battery, which stores chemical energy readily convertible to electricity to operate a mobile phone; the hydroelectric dam, which stores energy in a reservoir as gravitational potential energy; and ice storage tanks, which store ice frozen by cheaper energy at night to meet peak daytime demand for cooling. Fossil fuels such as coal and gasoline store ancient energy derived from sunlight by organisms that later died, became buried and over time were then converted into these fuels. Food (which is made by the same process as fossil fuels) is a form of energy stored in chemical form.
In the 20th century grid, electrical power was largely generated by burning fossil fuel. When less power was required, less fuel was burned. Hydropower, a mechanical energy storage method, is the most widely adopted mechanical energy storage, and has been in use for centuries. Large hydropower dams have been energy storage sites for more than one hundred years. Concerns with air pollution, energy imports, and global warming have spawned the growth of renewable energy such as solar and wind power. Wind power is uncontrolled and may be generating at a time when no additional power is needed. Solar power varies with cloud cover and at best is only available during daylight hours, while demand often peaks after sunset (see duck curve). Interest in storing power from these intermittent sources grows as the renewable energy industry begins to generate a larger fraction of overall energy consumption.
Off grid electrical use was a niche market in the 20th century, but in the 21st century, it has expanded. Portable devices are in use all over the world. Solar panels are now common in the rural settings worldwide. Access to electricity is now a question of economics and financial viability, and not solely on technical aspects. Electric vehicles are gradually replacing combustion-engine vehicles. However, powering long-distance transportation without burning fuel remains in development.
The following list includes a variety of types of energy storage:
- Fossil fuel storage
- Electrical, electromagnetic
- Electrochemical (Battery Energy Storage System, BESS)
Energy can be stored in water pumped to a higher elevation using pumped storage methods or by moving solid matter to higher locations (gravity batteries). Other commercial mechanical methods include compressing air and flywheels that convert electric energy into internal energy or kinetic energy and then back again when electrical demand peaks.
Hydroelectric dams with reservoirs can be operated to provide electricity at times of peak demand. Water is stored in the reservoir during periods of low demand and released when demand is high. The net effect is similar to pumped storage, but without the pumping loss.
While a hydroelectric dam does not directly store energy from other generating units, it behaves equivalently by lowering output in periods of excess electricity from other sources. In this mode, dams are one of the most efficient forms of energy storage, because only the timing of its generation changes. Hydroelectric turbines have a start-up time on the order of a few minutes.
Worldwide, pumped-storage hydroelectricity (PSH) is the largest-capacity form of active grid energy storage available, and, as of March 2012, the Electric Power Research Institute (EPRI) reports that PSH accounts for more than 99% of bulk storage capacity worldwide, representing around 127,000 MW. PSH energy efficiency varies in practice between 70% and 80%, with claims of up to 87%.
At times of low electrical demand, excess generation capacity is used to pump water from a lower source into a higher reservoir. When demand grows, water is released back into a lower reservoir (or waterway or body of water) through a turbine, generating electricity. Reversible turbine-generator assemblies act as both a pump and turbine (usually a Francis turbine design). Nearly all facilities use the height difference between two water bodies. Pure pumped-storage plants shift the water between reservoirs, while the "pump-back" approach is a combination of pumped storage and conventional hydroelectric plants that use natural stream-flow.
Compressed air energy storage (CAES) uses surplus energy to compress air for subsequent electricity generation. Small-scale systems have long been used in such applications as propulsion of mine locomotives. The compressed air is stored in an underground reservoir, such as a salt dome.
Compressed-air energy storage (CAES) plants can bridge the gap between production volatility and load. CAES storage addresses the energy needs of consumers by effectively providing readily available energy to meet demand. Renewable energy sources like wind and solar energy vary. So at times when they provide little power, they need to be supplemented with other forms of energy to meet energy demand. Compressed-air energy storage plants can take in the surplus energy output of renewable energy sources during times of energy over-production. This stored energy can be used at a later time when demand for electricity increases or energy resource availability decreases.
Compression of air creates heat; the air is warmer after compression. Expansion requires heat. If no extra heat is added, the air will be much colder after expansion. If the heat generated during compression can be stored and used during expansion, efficiency improves considerably. A CAES system can deal with the heat in three ways. Air storage can be adiabatic, diabatic, or isothermal. Another approach uses compressed air to power vehicles.
Flywheel energy storage (FES) works by accelerating a rotor (a flywheel) to a very high speed, holding energy as rotational energy. When energy is added the rotational speed of the flywheel increases, and when energy is extracted, the speed declines, due to conservation of energy.
Most FES systems use electricity to accelerate and decelerate the flywheel, but devices that directly use mechanical energy are under consideration.
FES systems have rotors made of high strength carbon-fiber composites, suspended by magnetic bearings and spinning at speeds from 20,000 to over 50,000 revolutions per minute (rpm) in a vacuum enclosure. Such flywheels can reach maximum speed ("charge") in a matter of minutes. The flywheel system is connected to a combination electric motor/generator.
FES systems have relatively long lifetimes (lasting decades with little or no maintenance; full-cycle lifetimes quoted for flywheels range from in excess of 105, up to 107, cycles of use), high specific energy (100–130 W·h/kg, or 360–500 kJ/kg) and power density.
Solid mass gravitational Edit
Changing the altitude of solid masses can store or release energy via an elevating system driven by an electric motor/generator. Studies suggest energy can begin to be released with as little as 1 second warning, making the method a useful supplemental feed into an electricity grid to balance load surges.
Efficiencies can be as high as 85% recovery of stored energy.
This can be achieved by siting the masses inside old vertical mine shafts or in specially constructed towers where the heavy weights are winched up to store energy and allowed a controlled descent to release it. At 2020 a prototype vertical store is being built in Edinburgh, Scotland 
Potential energy storage or gravity energy storage was under active development in 2013 in association with the California Independent System Operator. It examined the movement of earth-filled hopper rail cars driven by electric locomotives from lower to higher elevations.
Other proposed methods include:-
- using rails and cranes to move concrete weights up and down;
- using high-altitude solar-powered balloon platforms supporting winches to raise and lower solid masses slung underneath them,
- using winches supported by an ocean barge to take advantage of a 4 km (13,000 ft) elevation difference between the sea surface and the seabed,
Thermal energy storage (TES) is the temporary storage or removal of heat.
Sensible heat thermalEdit
Seasonal thermal energy storage (STES) allows heat or cold to be used months after it was collected from waste energy or natural sources. The material can be stored in contained aquifers, clusters of boreholes in geological substrates such as sand or crystalline bedrock, in lined pits filled with gravel and water, or water-filled mines. Seasonal thermal energy storage (STES) projects often have paybacks in four to six years. An example is Drake Landing Solar Community in Canada, for which 97% of the year-round heat is provided by solar-thermal collectors on the garage roofs, with a borehole thermal energy store (BTES) being the enabling technology. In Braedstrup, Denmark, the community's solar district heating system also uses STES, at a temperature of 65 °C (149 °F). A heat pump, which is run only when there is surplus wind power available on the national grid, is used to raise the temperature to 80 °C (176 °F) for distribution. When surplus wind generated electricity is not available, a gas-fired boiler is used. Twenty percent of Braedstrup's heat is solar.
Latent heat thermal (LHTES)Edit
Latent heat thermal energy storage systems work by transferring heat to or from a material to change its phase. A phase-change is the melting, solidifying, vaporizing or liquifying. Such a material is called a phase change material (PCM). Materials used in LHTESs often have a high latent heat so that at their specific temperature, the phase change absorbs a large amount of energy, much more than sensible heat.
A steam accumulator is a type of LHTES where the phase change is between liquid and gas and uses the latent heat of vaporization of water. Ice storage air conditioning systems use off-peak electricity to store cold by freezing water into ice. The stored cold in ice releases during melting process and can be used for cooling at peak hours.
Cryogenic thermal energy storageEdit
See main article Cryogenic energy storage
Air can be liquefied by cooling using electricity and stored as a cryogen with existing technologies. The liquid air can then be expanded through a turbine and the energy recovered as electricity. The system was demonstrated at a pilot plant in the UK in 2012. In 2019, Highview announced plans to build a 50 MW in the North of England and northern Vermont, with the proposed facility able to store five to eight hours of energy, for a 250-400 MWh storage capacity.
See main article Carnot battery
Electrical energy can be stored in heat storage by resistive heating or heat pumps, and the stored heat can be converted back to electricity via Rankine cycle or Brayton cycle. This technology has been studied to retrofit existing coal-fired power plants into fossil-fuel free generation systems. Coal-fired boilers are replaced by high-temperature heat storage which is charged by excess electricity from variable renewable energy sources. In 2020, German Aerospace Center starts to construct the world's first large-scale Carnot battery system, which has 1,000 MWh storage capacity.
A rechargeable battery comprises one or more electrochemical cells. It is known as a 'secondary cell' because its electrochemical reactions are electrically reversible. Rechargeable batteries come in many shapes and sizes, ranging from button cells to megawatt grid systems.
Rechargeable batteries have lower total cost of use and environmental impact than non-rechargeable (disposable) batteries. Some rechargeable battery types are available in the same form factors as disposables. Rechargeable batteries have higher initial cost but can be recharged very cheaply and used many times.
Common rechargeable battery chemistries include:
- Lead–acid battery: Lead acid batteries hold the largest market share of electric storage products. A single cell produces about 2V when charged. In the charged state the metallic lead negative electrode and the lead sulfate positive electrode are immersed in a dilute sulfuric acid (H2SO4) electrolyte. In the discharge process electrons are pushed out of the cell as lead sulfate is formed at the negative electrode while the electrolyte is reduced to water.
- Lead-acid battery technology has been developed extensively. Upkeep requires minimal labor and its cost is low. The battery's available energy capacity is subject to a quick discharge resulting in a low life span and low energy density.
- Nickel–cadmium battery (NiCd): Uses nickel oxide hydroxide and metallic cadmium as electrodes. Cadmium is a toxic element, and was banned for most uses by the European Union in 2004. Nickel–cadmium batteries have been almost completely replaced by nickel–metal hydride (NiMH) batteries.
- Nickel–metal hydride battery (NiMH): First commercial types were available in 1989. These are now a common consumer and industrial type. The battery has a hydrogen-absorbing alloy for the negative electrode instead of cadmium.
- Lithium-ion battery: The choice in many consumer electronics and have one of the best energy-to-mass ratios and a very slow self-discharge when not in use.
- Lithium-ion polymer battery: These batteries are light in weight and can be made in any shape desired.
A flow battery works by passing a solution over a membrane where ions are exchanged to charge or discharge the cell. Cell voltage is chemically determined by the Nernst equation and ranges, in practical applications, from 1.0 V to 2.2 V. Storage capacity depends on the volume of solution. A flow battery is technically akin both to a fuel cell and an electrochemical accumulator cell. Commercial applications are for long half-cycle storage such as backup grid power.
Supercapacitors, also called electric double-layer capacitors (EDLC) or ultracapacitors, are a family of electrochemical capacitors that do not have conventional solid dielectrics. Capacitance is determined by two storage principles, double-layer capacitance and pseudocapacitance.
Supercapacitors bridge the gap between conventional capacitors and rechargeable batteries. They store the most energy per unit volume or mass (energy density) among capacitors. They support up to 10,000 farads/1.2 Volt, up to 10,000 times that of electrolytic capacitors, but deliver or accept less than half as much power per unit time (power density).
While supercapacitors have specific energy and energy densities that are approximately 10% of batteries, their power density is generally 10 to 100 times greater. This results in much shorter charge/discharge cycles. Also, they tolerate many more charge-discharge cycles than batteries.
Supercapacitors have many applications, including:
- Low supply current for memory backup in static random-access memory (SRAM)
- Power for cars, buses, trains, cranes and elevators, including energy recovery from braking, short-term energy storage and burst-mode power delivery
Power to gasEdit
Power to gas is the conversion of electricity to a gaseous fuel such as hydrogen or methane. The three commercial methods use electricity to reduce water into hydrogen and oxygen by means of electrolysis.
In the first method, hydrogen is injected into the natural gas grid or is used for transportation. The second method is to combine the hydrogen with carbon dioxide to produce methane using a methanation reaction such as the Sabatier reaction, or biological methanation, resulting in an extra energy conversion loss of 8%. The methane may then be fed into the natural gas grid. The third method uses the output gas of a wood gas generator or a biogas plant, after the biogas upgrader is mixed with the hydrogen from the electrolyzer, to upgrade the quality of the biogas.
At penetrations below 20% of the grid demand, renewables do not severely change the economics; but beyond about 20% of the total demand, external storage becomes important. If these sources are used to make ionic hydrogen, they can be freely expanded. A 5-year community-based pilot program using wind turbines and hydrogen generators began in 2007 in the remote community of Ramea, Newfoundland and Labrador. A similar project began in 2004 on Utsira, a small Norwegian island.
About 50 kW·h (180 MJ) of solar energy is required to produce a kilogram of hydrogen, so the cost of the electricity is crucial. At $0.03/kWh, a common off-peak high-voltage line rate in the United States, hydrogen costs $1.50 per kilogram for the electricity, equivalent to $1.50/gallon for gasoline. Other costs include the electrolyzer plant, hydrogen compressors or liquefaction, storage and transportation.
Hydrogen can also be produced from aluminum and water by stripping aluminum's naturally-occurring aluminum oxide barrier and introducing it to water. This method is beneficial because recycled aluminum cans can be used to generate hydrogen, however systems to harness this option have not been commercially developed and are much more complex than electrolysis systems. Common methods to strip the oxide layer include caustic catalysts such as sodium hydroxide and alloys with gallium, mercury and other metals.
Underground hydrogen storage is the practice of hydrogen storage in caverns, salt domes and depleted oil and gas fields. Large quantities of gaseous hydrogen have been stored in caverns by Imperial Chemical Industries for many years without any difficulties. The European Hyunder project indicated in 2013 that storage of wind and solar energy using underground hydrogen would require 85 caverns.
Powerpaste is a magnesium and hydrogen -based fluid gel that releases hydrogen when reacting with water. It was invented, patented and is being developed by the Fraunhofer Institute for Manufacturing Technology and Advanced Materials (IFAM) of the Fraunhofer-Gesellschaft. Powerpaste is made by combining magnesium powder with hydrogen to form magnesium hydride in a process conducted at 350 °C and five to six times atmospheric pressure. An ester and a metal salt are then added to make the finished product. Fraunhofer states that they are building a production plant slated to start production in 2021, which will produce 4 tons of Powerpaste annually. Fraunhofer has patented their invention in the United States and EU. Fraunhofer claims that Powerpaste is able to store hydrogen energy at 10 times the energy density of a lithium battery of a similar dimension and is safe and convenient for automotive situations.
Methane is the simplest hydrocarbon with the molecular formula CH4. Methane is more easily stored and transported than hydrogen. Storage and combustion infrastructure (pipelines, gasometers, power plants) are mature.
Synthetic natural gas (syngas or SNG) can be created in a multi-step process, starting with hydrogen and oxygen. Hydrogen is then reacted with carbon dioxide in a Sabatier process, producing methane and water. Methane can be stored and later used to produce electricity. The resulting water is recycled, reducing the need for water. In the electrolysis stage, oxygen is stored for methane combustion in a pure oxygen environment at an adjacent power plant, eliminating nitrogen oxides.
Methane combustion produces carbon dioxide (CO2) and water. The carbon dioxide can be recycled to boost the Sabatier process and water can be recycled for further electrolysis. Methane production, storage and combustion recycles the reaction products.
The CO2 has economic value as a component of an energy storage vector, not a cost as in carbon capture and storage.
Power to liquidEdit
Power to liquid is similar to power to gas except that the hydrogen is converted into liquids such as methanol or ammonia. These are easier to handle than gases, and requires fewer safety precautions than hydrogen. They can be used for transportation, including aircraft, but also for industrial purposes or in the power sector.
Various biofuels such as biodiesel, vegetable oil, alcohol fuels, or biomass can replace fossil fuels. Various chemical processes can convert the carbon and hydrogen in coal, natural gas, plant and animal biomass and organic wastes into short hydrocarbons suitable as replacements for existing hydrocarbon fuels. Examples are Fischer–Tropsch diesel, methanol, dimethyl ether and syngas. This diesel source was used extensively in World War II in Germany, which faced limited access to crude oil supplies. South Africa produces most of the country's diesel from coal for similar reasons. A long term oil price above US$35/bbl may make such large scale synthetic liquid fuels economical.
Aluminum has been proposed as an energy store by a number of researchers. Its electrochemical equivalent (8.04 Ah/cm3) is nearly four times greater than that of lithium (2.06 Ah/cm3). Energy can be extracted from aluminum by reacting it with water to generate hydrogen. However, it must first be stripped of its natural oxide layer, a process which requires pulverization, chemical reactions with caustic substances, or alloys. The byproduct of the reaction to create hydrogen is aluminum oxide, which can be recycled into aluminum with the Hall–Héroult process, making the reaction theoretically renewable. If the Hall-Heroult Process is run using solar or wind power, aluminum could be used to store the energy produced at higher efficiency than direct solar electrolysis.
Boron, silicon, and zincEdit
The organic compound norbornadiene converts to quadricyclane upon exposure to light, storing solar energy as the energy of chemical bonds. A working system has been developed in Sweden as a molecular solar thermal system.
A capacitor (originally known as a 'condenser') is a passive two-terminal electrical component used to store energy electrostatically. Practical capacitors vary widely, but all contain at least two electrical conductors (plates) separated by a dielectric (i.e., insulator). A capacitor can store electric energy when disconnected from its charging circuit, so it can be used like a temporary battery, or like other types of rechargeable energy storage system. Capacitors are commonly used in electronic devices to maintain power supply while batteries change. (This prevents loss of information in volatile memory.) Conventional capacitors provide less than 360 joules per kilogram, while a conventional alkaline battery has a density of 590 kJ/kg.
Capacitors store energy in an electrostatic field between their plates. Given a potential difference across the conductors (e.g., when a capacitor is attached across a battery), an electric field develops across the dielectric, causing positive charge (+Q) to collect on one plate and negative charge (-Q) to collect on the other plate. If a battery is attached to a capacitor for a sufficient amount of time, no current can flow through the capacitor. However, if an accelerating or alternating voltage is applied across the leads of the capacitor, a displacement current can flow. Besides capacitor plates, charge can also be stored in a dielectric layer.
Capacitance is greater given a narrower separation between conductors and when the conductors have a larger surface area. In practice, the dielectric between the plates emits a small amount of leakage current and has an electric field strength limit, known as the breakdown voltage. However, the effect of recovery of a dielectric after a high-voltage breakdown holds promise for a new generation of self-healing capacitors. The conductors and leads introduce undesired inductance and resistance.
Superconducting magnetic energy storage (SMES) systems store energy in a magnetic field created by the flow of direct current in a superconducting coil that has been cooled to a temperature below its superconducting critical temperature. A typical SMES system includes a superconducting coil, power conditioning system and refrigerator. Once the superconducting coil is charged, the current does not decay and the magnetic energy can be stored indefinitely.
The stored energy can be released to the network by discharging the coil. The associated inverter/rectifier accounts for about 2–3% energy loss in each direction. SMES loses the least amount of electricity in the energy storage process compared to other methods of storing energy. SMES systems offer round-trip efficiency greater than 95%.
Due to the energy requirements of refrigeration and the cost of superconducting wire, SMES is used for short duration storage such as improving power quality. It also has applications in grid balancing.
The classic application before the industrial revolution was the control of waterways to drive water mills for processing grain or powering machinery. Complex systems of reservoirs and dams were constructed to store and release water (and the potential energy it contained) when required.
Home energy storage is expected to become increasingly common given the growing importance of distributed generation of renewable energies (especially photovoltaics) and the important share of energy consumption in buildings. To exceed a self-sufficiency of 40% in a household equipped with photovoltaics, energy storage is needed. Multiple manufacturers produce rechargeable battery systems for storing energy, generally to hold surplus energy from home solar or wind generation. Today, for home energy storage, Li-ion batteries are preferable to lead-acid ones given their similar cost but much better performance.
Tesla Motors produces two models of the Tesla Powerwall. One is a 10 kWh weekly cycle version for backup applications and the other is a 7 kWh version for daily cycle applications. In 2016, a limited version of the Tesla Powerpack 2 cost $398(US)/kWh to store electricity worth 12.5 cents/kWh (US average grid price) making a positive return on investment doubtful unless electricity prices are higher than 30 cents/kWh.
RoseWater Energy produces two models of the "Energy & Storage System", the HUB 120 and SB20. Both versions provide 28.8 kWh of output, enabling it to run larger houses or light commercial premises, and protecting custom installations. The system provides five key elements into one system, including providing a clean 60 Hz Sine wave, zero transfer time, industrial-grade surge protection, renewable energy grid sell-back (optional), and battery backup.
Storing wind or solar energy using thermal energy storage though less flexible, is considerably cheaper than batteries. A simple 52-gallon electric water heater can store roughly 12 kWh of energy for supplementing hot water or space heating.
Grid electricity and power stationsEdit
The largest source and the greatest store of renewable energy is provided by hydroelectric dams. A large reservoir behind a dam can store enough water to average the annual flow of a river between dry and wet seasons. A very large reservoir can store enough water to average the flow of a river between dry and wet years. While a hydroelectric dam does not directly store energy from intermittent sources, it does balance the grid by lowering its output and retaining its water when power is generated by solar or wind. If wind or solar generation exceeds the region's hydroelectric capacity, then some additional source of energy is needed.
Many renewable energy sources (notably solar and wind) produce variable power. Storage systems can level out the imbalances between supply and demand that this causes. Electricity must be used as it is generated or converted immediately into storable forms.
The main method of electrical grid storage is pumped-storage hydroelectricity. Areas of the world such as Norway, Wales, Japan and the US have used elevated geographic features for reservoirs, using electrically powered pumps to fill them. When needed, the water passes through generators and converts the gravitational potential of the falling water into electricity. Pumped storage in Norway, which gets almost all its electricity from hydro, has currently a capacity of 1.4 GW but since the total installed capacity is nearly 32 GW and 75% of that is regulable, it can be expanded significantly.
Some forms of storage that produce electricity include pumped-storage hydroelectric dams, rechargeable batteries, thermal storage including molten salts which can efficiently store and release very large quantities of heat energy, and compressed air energy storage, flywheels, cryogenic systems and superconducting magnetic coils.
In 2011, the Bonneville Power Administration in Northwestern United States created an experimental program to absorb excess wind and hydro power generated at night or during stormy periods that are accompanied by high winds. Under central control, home appliances absorb surplus energy by heating ceramic bricks in special space heaters to hundreds of degrees and by boosting the temperature of modified hot water heater tanks. After charging, the appliances provide home heating and hot water as needed. The experimental system was created as a result of a severe 2010 storm that overproduced renewable energy to the extent that all conventional power sources were shut down, or in the case of a nuclear power plant, reduced to its lowest possible operating level, leaving a large area running almost completely on renewable energy.
Another advanced method used at the former Solar Two project in the United States and the Solar Tres Power Tower in Spain uses molten salt to store thermal energy captured from the sun and then convert it and dispatch it as electrical power. The system pumps molten salt through a tower or other special conduits to be heated by the sun. Insulated tanks store the solution. Electricity is produced by turning water to steam that is fed to turbines.
In vehicle-to-grid storage, electric vehicles that are plugged into the energy grid can deliver stored electrical energy from their batteries into the grid when needed.
Thermal energy storage (TES) can be used for air conditioning. It is most widely used for cooling single large buildings and/or groups of smaller buildings. Commercial air conditioning systems are the biggest contributors to peak electrical loads. In 2009, thermal storage was used in over 3,300 buildings in over 35 countries. It works by chilling material at night and using the chilled material for cooling during the hotter daytime periods.
The most popular technique is ice storage, which requires less space than water and is cheaper than fuel cells or flywheels. In this application, a standard chiller runs at night to produce an ice pile. Water circulates through the pile during the day to chill water that would normally be the chiller's daytime output.
A partial storage system minimizes capital investment by running the chillers nearly 24 hours a day. At night, they produce ice for storage and during the day they chill water. Water circulating through the melting ice augments the production of chilled water. Such a system makes ice for 16 to 18 hours a day and melts ice for six hours a day. Capital expenditures are reduced because the chillers can be just 40% - 50% of the size needed for a conventional, no-storage design. Storage sufficient to store half a day's available heat is usually adequate.
A full storage system shuts off the chillers during peak load hours. Capital costs are higher, as such a system requires larger chillers and a larger ice storage system.
This ice is produced when electrical utility rates are lower. Off-peak cooling systems can lower energy costs. The U.S. Green Building Council has developed the Leadership in Energy and Environmental Design (LEED) program to encourage the design of reduced-environmental impact buildings. Off-peak cooling may help toward LEED Certification.
Thermal storage for heating is less common than for cooling. An example of thermal storage is storing solar heat to be used for heating at night.
Latent heat can also be stored in technical phase change materials (PCMs). These can be encapsulated in wall and ceiling panels, to moderate room temperatures.
Liquid hydrocarbon fuels are the most commonly used forms of energy storage for use in transportation, followed by a growing use of Battery Electric Vehicles and Hybrid Electric Vehicles. Other energy carriers such as hydrogen can be used to avoid producing greenhouse gases.
Public transport systems like trams and trolleybuses require electricity, but due to their variability in movement, a steady supply of electricity via renewable energy is challenging. Photovoltaic systems installed on the roofs of buildings can be used to power public transportation systems during periods in which there is increased demand for electricity and access to other forms of energy are not readily available. Upcoming transitions in the transportation system also include e.g. ferries and airplanes, where electric power supply is investigated as an interesting alternative.
Capacitors are widely used in electronic circuits for blocking direct current while allowing alternating current to pass. In analog filter networks, they smooth the output of power supplies. In resonant circuits they tune radios to particular frequencies. In electric power transmission systems they stabilize voltage and power flow.
The United States Department of Energy International Energy Storage Database (IESDB), is a free-access database of energy storage projects and policies funded by the United States Department of Energy Office of Electricity and Sandia National Labs.
Storage capacity is the amount of energy extracted from an energy storage device or system; usually measured in joules or kilowatt-hours and their multiples, it may be given in number of hours of electricity production at power plant nameplate capacity; when storage is of primary type (i.e., thermal or pumped-water), output is sourced only with the power plant embedded storage system.
The economics of energy storage strictly depends on the reserve service requested, and several uncertainty factors affect the profitability of energy storage. Therefore, not every storage method is technically and economically suitable for the storage of several MWh, and the optimal size of the energy storage is market and location dependent.
Moreover, ESS are affected by several risks, e.g.:
- Techno-economic risks, which are related to the specific technology;
- Market risks, which are the factors that affect the electricity supply system;
- Regulation and policy risks.
Therefore, traditional techniques based on deterministic Discounted Cash Flow (DCF) for the investment appraisal are not fully adequate to evaluate these risks and uncertainties and the investor's flexibility to deal with them. Hence, the literature recommends to assess the value of risks and uncertainties through the Real Option Analysis (ROA), which is a valuable method in uncertain contexts.
The economic valuation of large-scale applications (including pumped hydro storage and compressed air) considers benefits including: curtailment avoidance, grid congestion avoidance, price arbitrage and carbon-free energy delivery. In one technical assessment by the Carnegie Mellon Electricity Industry Centre, economic goals could be met using batteries if their capital cost was $30 to $50 per kilowatt-hour.
A metric of energy efficiency of storage is energy storage on energy invested (ESOI), which is the amount of energy that can be stored by a technology, divided by the amount of energy required to build that technology. The higher the ESOI, the better the storage technology is energetically. For lithium-ion batteries this is around 10, and for lead acid batteries it is about 2. Other forms of storage such as pumped hydroelectric storage generally have higher ESOI, such as 210.
Pumped-storage hydroelectricity is by far the largest storage technology used globally but has limited growth potential in most countries due to very high land use for relatively small power. High costs and limited life still make batteries a "weak substitute" for dispatchable power sources, and are unable to cover for variable renewable power gaps lasting for days, weeks or months. In grid models with high VRE share, the excessive cost of storage tends to dominate the costs of the whole grid — for example, in California alone 80% share of VRE would require 9.6 TWh of storage but 100% would require 36.3 TWh. As of 2018 the state only had 150 GWh of storage, primarily in pumped storage and a small fraction in batteries. According to another study, supplying 80% of US demand from VRE would require a smart grid covering the whole country or battery storage capable to supply the whole system for 12 hours, both at cost estimated at $2.5 trillion.
In 2013, the German Federal government allocated €200M (approximately US$270M) for research, and another €50M to subsidize battery storage in residential rooftop solar panels, according to a representative of the German Energy Storage Association.
Siemens AG commissioned a production-research plant to open in 2015 at the Zentrum für Sonnenenergie und Wasserstoff (ZSW, the German Center for Solar Energy and Hydrogen Research in the State of Baden-Württemberg), a university/industry collaboration in Stuttgart, Ulm and Widderstall, staffed by approximately 350 scientists, researchers, engineers, and technicians. The plant develops new near-production manufacturing materials and processes (NPMM&P) using a computerized Supervisory Control and Data Acquisition (SCADA) system. It aims to enable the expansion of rechargeable battery production with increased quality and lower cost.
In 2014, research and test centers opened to evaluate energy storage technologies. Among them was the Advanced Systems Test Laboratory at the University of Wisconsin at Madison in Wisconsin State, which partnered with battery manufacturer Johnson Controls. The laboratory was created as part of the university's newly opened Wisconsin Energy Institute. Their goals include the evaluation of state-of-the-art and next generation electric vehicle batteries, including their use as grid supplements.
The State of New York unveiled its New York Battery and Energy Storage Technology (NY-BEST) Test and Commercialization Center at Eastman Business Park in Rochester, New York, at a cost of $23 million for its almost 1,700 m2 laboratory. The center includes the Center for Future Energy Systems, a collaboration between Cornell University of Ithaca, New York and the Rensselaer Polytechnic Institute in Troy, New York. NY-BEST tests, validates and independently certifies diverse forms of energy storage intended for commercial use.
On September 27, 2017, Senators Al Franken of Minnesota and Martin Heinrich of New Mexico introduced Advancing Grid Storage Act (AGSA), which would devote more than $1 billion in research, technical assistance and grants to encourage energy storage in the United States.
In grid models with high VRE share, the excessive cost of storage tends to dominate the costs of the whole grid — for example, in California alone 80% share of VRE would require 9.6 TWh of storage but 100% would require 36.3 TWh. According to another study, supplying 80% of US demand from VRE would require a smart grid covering the whole country or battery storage capable to supply the whole system for 12 hours, both at cost estimated at $2.5 trillion.
In the United Kingdom, some 14 industry and government agencies allied with seven British universities in May 2014 to create the SUPERGEN Energy Storage Hub in order to assist in the coordination of energy storage technology research and development.
- Clarke, Energy. "Energy Storage". Clarke Energy. Archived from the original on July 28, 2020. Retrieved June 5, 2020.
- Liasi, Sahand Ghaseminejad; Bathaee, Seyed Mohammad Taghi (July 30, 2019). "Optimizing microgrid using demand response and electric vehicles connection to microgrid". 2017 Smart Grid Conference (SGC). pp. 1–7. doi:10.1109/SGC.2017.8308873. ISBN 978-1-5386-4279-5. S2CID 3817521.
- Hittinger, Eric; Ciez, Rebecca E. (October 17, 2020). "Modeling Costs and Benefits of Energy Storage Systems". Annual Review of Environment and Resources. 45 (1): 445–469. doi:10.1146/annurev-environ-012320-082101. ISSN 1543-5938. Archived from the original on April 14, 2021. Retrieved April 14, 2021.
- Bailera, Manuel; Lisbona, Pilar; Romeo, Luis M.; Espatolero, Sergio (March 1, 2017). "Power to Gas projects review: Lab, pilot and demo plants for storing renewable energy and CO2". Renewable and Sustainable Energy Reviews. 69: 292–312. doi:10.1016/j.rser.2016.11.130. ISSN 1364-0321. Archived from the original on March 10, 2020.
- Huggins, Robert A (September 1, 2010). Energy Storage. Springer. p. 60. ISBN 978-1-4419-1023-3.
- "Energy storage - Packing some power". The Economist. March 3, 2011. Archived from the original on March 6, 2020. Retrieved March 11, 2012.
- Jacob, Thierry.Pumped storage in Switzerland - an outlook beyond 2000 Archived July 7, 2011, at the Wayback Machine Stucky. Accessed: February 13, 2012.
- Levine, Jonah G. Pumped Hydroelectric Energy Storage and Spatial Diversity of Wind Resources as Methods of Improving Utilization of Renewable Energy Sources Archived August 1, 2014, at the Wayback Machine page 6, University of Colorado, December 2007. Accessed: February 12, 2012.
- Yang, Chi-Jen. Pumped Hydroelectric Storage Archived September 5, 2012, at the Wayback Machine Duke University. Accessed: February 12, 2012.
- Energy Storage Archived April 7, 2014, at the Wayback Machine Hawaiian Electric Company. Accessed: February 13, 2012.
- Wild, Matthew, L. Wind Drives Growing Use of Batteries Archived December 5, 2019, at the Wayback Machine, The New York Times, July 28, 2010, pp. B1.
- Keles, Dogan; Hartel, Rupert; Möst, Dominik; Fichtner, Wolf (Spring 2012). "Compressed-air energy storage power plant investments under uncertain electricity prices: an evaluation of compressed-air energy storage plants in liberalized energy markets". The Journal of Energy Markets. 5 (1): 54. doi:10.21314/JEM.2012.070. ProQuest 1037988494.
- Gies, Erica. Global Clean Energy: A Storage Solution Is in the Air Archived May 8, 2019, at the Wayback Machine, International Herald Tribune online website, October 1, 2012, and in print on October 2, 2012, in The International Herald Tribune. Retrieved from NYTimes.com website, March 19, 2013.
- Diem, William. Experimental car is powered by air: French developer works on making it practical for real-world driving, Auto.com, March 18, 2004. Retrieved from Archive.org on March 19, 2013.
- Slashdot: Car Powered by Compressed Air Archived July 28, 2020, at the Wayback Machine, Freep.com website, 2004.03.18
- Torotrak Toroidal variable drive CVT Archived May 16, 2011, at the Wayback Machine, retrieved June 7, 2007.
- Castelvecchi, Davide (May 19, 2007). "Spinning into control: High-tech reincarnations of an ancient way of storing energy". Science News. 171 (20): 312–313. doi:10.1002/scin.2007.5591712010. Archived from the original on June 6, 2014. Retrieved May 8, 2014.
- "Storage Technology Report, ST6 Flywheel" (PDF). Archived from the original (PDF) on January 14, 2013. Retrieved May 8, 2014.
- "Next-gen Of Flywheel Energy Storage". Product Design & Development. Archived from the original on July 10, 2010. Retrieved May 21, 2009.
- Fraser, Douglas. "Edinburgh company generates electricity from gravity". BBC News. BBC. Archived from the original on July 28, 2020. Retrieved January 14, 2020.
- Akshat Rathi (August 18, 2018). "Stacking concrete blocks is a surprisingly efficient way to store energy". Quartz. Archived from the original on December 3, 2020. Retrieved August 20, 2018.
- Gourley, Perry (August 31, 2020). "Edinburgh firm behind incredible gravity energy storage project hails milestone". www.edinburghnews.scotsman.com. Archived from the original on September 2, 2020. Retrieved September 1, 2020.
- Packing Some Power: Energy Technology: Better ways of storing energy are needed if electricity systems are to become cleaner and more efficient Archived July 7, 2014, at the Wayback Machine, The Economist, March 3, 2012
- Downing, Louise. Ski Lifts Help Open $25 Billion Market for Storing Power Archived September 17, 2016, at the Wayback Machine, Bloomberg News online, September 6, 2012
- Kernan, Aedan. Storing Energy on Rail Tracks Archived April 12, 2014, at the Wayback Machine, Leonardo-Energy.org website, October 30, 2013
- Massey, Nathanael and ClimateWire. Energy Storage Hits the Rails Out West: In California and Nevada, projects store electricity in the form of heavy rail cars pulled up a hill Archived April 30, 2014, at the Wayback Machine, ScientificAmerican.com website, March 25, 2014. Retrieved March 28, 2014.
- David Z. Morris (May 22, 2016). "Energy-Storing Train Gets Nevada Approval". Fortune. Archived from the original on August 20, 2018. Retrieved August 20, 2018.
- "StratoSolar gravity energy storage". Archived from the original on August 20, 2018. Retrieved August 20, 2018.
- Choi, Annette (May 24, 2017). "Simple Physics Solutions to Storing Renewable Energy". NOVA. PBS. Archived from the original on August 29, 2019. Retrieved August 29, 2019.
- Layered Materials for Energy Storage and Conversion, Editors: Dongsheng Geng, Yuan Cheng, Gang Zhang , Royal Society of Chemistry, Cambridge 2019,
- "Evidence Gathering: Thermal Energy Storage (TES) Technologies" (PDF). Department for Business, Energy & Industrial Strategy. Archived (PDF) from the original on October 31, 2020. Retrieved October 24, 2020.
- Hellström, G. (May 19, 2008), Large-Scale Applications of Ground-Source Heat Pumps in Sweden, IEA Heat Pump Annex 29 Workshop, Zurich.
- Wong, B. (2013). Integrating solar & heat pumps. Archived June 10, 2016, at the Wayback Machine.
- Wong, B. (2011). Drake Landing Solar Community. Archived March 4, 2016, at the Wayback Machine
- Canadian Solar Community Sets New World Record for Energy Efficiency and Innovation Archived April 30, 2013, at the Wayback Machine, Natural Resources Canada, October 5, 2012.
- Solar District Heating (SDH). 2012. Braedstrup Solar Park in Denmark Is Now a Reality! Archived January 26, 2013, at the Wayback Machine Newsletter. October 25, 2012. SDH is a European Union-wide program.
- Sekhara Reddy, M.C.; T., R.L.; K., D.R; Ramaiah, P.V (2015). "Enhancement of thermal energy storage system using sensible heat and latent heat storage materials". I-Manager's Journal on Mechanical Engineering. 5: 36. ProQuest 1718068707.
- "Electricity Storage" (PDF). Institute of Mechanical Engineers. May 2012. Archived (PDF) from the original on January 10, 2020. Retrieved October 31, 2020.
- Danigelis, Alyssa (December 19, 2019). "First Long-Duration Liquid Air Energy Storage System Planned for the US". Environment + Energy Leader. Archived from the original on November 4, 2020. Retrieved December 20, 2019.
- Dumont, Olivier; Frate, Guido Francesco; Pillai, Aditya; Lecompte, Steven; De paepe, Michel; Lemort, Vincent (2020). "Carnot battery technology: A state-of-the-art review". Journal of Energy Storage. 32: 101756. doi:10.1016/j.est.2020.101756. ISSN 2352-152X.
- Susan Kraemer (April 16, 2019). "Make Carnot Batteries with Molten Salt Thermal Energy Storage in ex-Coal Plants". SolarPACES. Archived from the original on October 30, 2020. Retrieved October 31, 2020.
- "World's first Carnot battery stores electricity in heat". German Energy Solutions Initiative. September 20, 2020. Archived from the original on October 23, 2020. Retrieved October 29, 2020.
- Yao, L.; Yang, B.; Cui, H.; Zhuang, J.; Ye, J.; Xue, J. (2016). "Challenges and progresses of energy storage technology and its application in power systems". Journal of Modern Power Systems and Clean Energy. 4 (4): 520–521. doi:10.1007/s40565-016-0248-x.
- Aifantis, Katerina E.; Hackney, Stephen A.; Kumar, R. Vasant (March 30, 2010). High Energy Density Lithium Batteries: Materials, Engineering, Applications. John Wiley & Sons. ISBN 978-3-527-63002-8.
- B. E. Conway (1999). Electrochemical Supercapacitors: Scientific Fundamentals and Technological Applications. Berlin: Springer. ISBN 978-0306457364. Retrieved May 2, 2013.
- Marin S. Halper, James C. Ellenbogen (March 2006). Supercapacitors: A Brief Overview (PDF) (Technical report). MITRE Nanosystems Group. Archived from the original (PDF) on February 1, 2014. Retrieved January 20, 2014.
- Frackowiak, Elzbieta; Béguin, François (2001). "Carbon materials for the electrochemical storage of energy in Capacitors". Carbon. 39 (6): 937–950. doi:10.1016/S0008-6223(00)00183-4.
- "Capacitor cells - ELTON". Elton-cap.com. Archived from the original on June 23, 2013. Retrieved May 29, 2013.
- Zerrahn, Alexander; Schill, Wolf-Peter; Kemfert, Claudia (2018). "On the economics of electrical storage for variable renewable energy sources". European Economic Review. 108: 259–279. doi:10.1016/j.euroecorev.2018.07.004. ISSN 0014-2921. S2CID 3484041.
- Oprisan, Morel. Introduction of Hydrogen Technologies to Ramea Island Archived July 30, 2016, at the Wayback Machine, CANMET Technology Innovation Centre, Natural Resources Canada, April 2007.
- Zyga, Lisa (December 11, 2006). "Why A Hydrogen Economy Doesn't Make Sense". Physorg.com web site. Physorg.com. pp. 15–44. Archived from the original on April 1, 2012. Retrieved November 17, 2007.
- "Safe, efficient way to produce hydrogen from aluminum particles and water for in-flight aircraft energy". Archived from the original on July 9, 2018. Retrieved July 9, 2018.
- "New process generates hydrogen from aluminum alloy to run engines, fuel cells". Archived from the original on December 13, 2020. Retrieved July 9, 2018.
- Eberle, Ulrich and Rittmar von Helmolt. "Sustainable transportation based on electric vehicle concepts: a brief overview" Archived October 21, 2013, at the Wayback Machine. Energy & Environmental Science, Royal Society of Chemistry, May 14, 2010, accessed August 2, 2011.
- "Benchmarking of selected storage options" (PDF).
- "HyWeb - The LBST Information Portal on Hydrogen and Fuel Cells". www.hyweb.de. Archived from the original on January 2, 2004. Retrieved September 28, 2008.
- "Storing renewable energy: Is hydrogen a viable solution?" (PDF).
- "Hydrogen-powered drives for e-scooters" (Press release). Fraunhofer Society. February 1, 2021. Archived from the original on February 3, 2021. Retrieved February 22, 2021.
- Röntzsch, Lars; Vogt, Marcus (February 2019). White paper - PowerPaste for off-grid power supply (Technical report). Fraunhofer Society. Archived from the original on February 7, 2021. Retrieved February 22, 2021.
- Varone, Alberto; Ferrari, Michele (2015). "Power to liquid and power to gas: An option for the German Energiewende". Renewable and Sustainable Energy Reviews. 45: 207–218. doi:10.1016/j.rser.2015.01.049.
- Clean Alternative Fuels: Fischer-Tropsch Archived July 10, 2007, at the Wayback Machine, Transportation and Air Quality, Transportation and Regional Programs Division, United States Environmental Protection Agency, March 2002.
- "Overview of Lithium-Ion Batteries" (PDF). Panasonic. Archived (PDF) from the original on September 21, 2018. Retrieved July 9, 2018.
- White Paper: A Novel Method For Grid Energy Storage Using Aluminum Fuel Archived May 31, 2013, at the Wayback Machine, Alchemy Research, April 2012.
- "Army discovery may offer new energy source | U.S. Army Research Laboratory". arl.army.mil. Archived from the original on July 9, 2018. Retrieved July 9, 2018.
- "Current Efficiency, Specific Energy Consumption, Net Carbon Consumption - The Aluminum Smelting Process". aluminum-production.com. Archived from the original on July 9, 2018. Retrieved July 9, 2018.
- Cowan, Graham R.L. Boron: A Better Energy Carrier than Hydrogen? Archived July 5, 2007, at the Wayback Machine, June 12, 2007
- Auner, Norbert. Silicon as an intermediary between renewable energy and hydrogen Archived July 29, 2013, at the Wayback Machine, Frankfurt, Germany: Institute of Inorganic Chemistry, Johann Wolfgang Goethe University Frankfurt, Leibniz-Informationszentrum Wirtschaft, May 5, 2004, No. 11.
- Engineer-Poet. Ergosphere Blog, Zinc: Miracle metal? Archived August 14, 2007, at the Wayback Machine, June 29, 2005.
- "Liquid storage of solar energy: More effective than ever before". sciencedaily.com. Archived from the original on March 20, 2017. Retrieved March 21, 2017.
- Miller, Charles. Illustrated Guide to the National Electrical Code Archived August 19, 2020, at the Wayback Machine, p. 445 (Cengage Learning 2011).
- Bezryadin, A.; et., al. (2017). "Large energy storage efficiency of the dielectric layer of graphene nanocapacitors". Nanotechnology. 28 (49): 495401. arXiv:2011.11867. Bibcode:2017Nanot..28W5401B. doi:10.1088/1361-6528/aa935c. PMID 29027908. S2CID 44693636.
- Belkin, Andrey; et., al. (2017). "Recovery of Alumina Nanocapacitors after High Voltage Breakdown". Sci. Rep. 7 (1): 932. Bibcode:2017NatSR...7..932B. doi:10.1038/s41598-017-01007-9. PMC 5430567. PMID 28428625.
- Chen, Y.; et., al. (2012). "Study on self-healing and lifetime characteristics of metallized-film capacitor under high electric field". IEEE Transactions on Plasma Science. 40 (8): 2014–2019. Bibcode:2012ITPS...40.2014C. doi:10.1109/TPS.2012.2200699. S2CID 8722419.
- Hubler, A.; Osuagwu, O. (2010). "Digital quantum batteries: Energy and information storage in nanovacuum tube arrays". Complexity. 15: NA. doi:10.1002/cplx.20306.
- Talbot, David (December 21, 2009). "A Quantum Leap in Battery Design". Technology Review. MIT. Retrieved June 9, 2011.
- Hubler, Alfred W. (January–February 2009). "Digital Batteries". Complexity. 14 (3): 7–8. Bibcode:2009Cmplx..14c...7H. doi:10.1002/cplx.20275.
- Hassenzahl, W.V., "Applied Superconductivity: Superconductivity, An Enabling Technology For 21st Century Power Systems?", IEEE Transactions on Magnetics, pp. 1447–1453, Vol. 11, Iss. 1, March 2001.
- Cheung K.Y.C; Cheung S.T.H.; Navin De Silvia; Juvonen; Singh; Woo J.J. Large-Scale Energy Storage Systems, Imperial College London: ISE2, 2002/2003.
- Encyclopedia of technology and applied sciences. 10. New York: Marshall Cavendish. 2000. p. 1401. ISBN 076147126X. Retrieved December 31, 2020.
Simple waterwheels were used in the Balkans of Europe in 100 B.C.E for powering flour mills. Elaborate Irrigation systems had been built In Egypt and Mesopotamia a thousand years before that, and it is very likely that these systems contained simple waterwheels. Waterwheels powered by a stream running underneath were common in the Roman Empire during the third and fourth centuries C.E. After the fall of the Western Roman Empire, water technology advanced further in the Middle East than in Europe, but waterwheels were commonly used to harness water as a source of power in Europe during the Middle Ages. The Doomsday Book of 1086 C.E. lists 5624 water powered mills in the southern half of England. The designs of more efficient waterwheels were brought back to Europe from the Middle East by the Crusaders and were used for grinding grain and for powering furnace bellows.
- Guilherme de Oliveira e Silva; Patrick Hendrick (September 15, 2016). "Lead-acid batteries coupled with photovoltaics for increased electricity self-sufficiency in households". Applied Energy. 178: 856–867. doi:10.1016/j.apenergy.2016.06.003.
- de Oliveira e Silva, Guilherme; Hendrick, Patrick (June 1, 2017). "Photovoltaic self-sufficiency of Belgian households using lithium-ion batteries, and its impact on the grid" (PDF). Applied Energy. 195: 786–799. doi:10.1016/j.apenergy.2017.03.112.[permanent dead link]
- Debord, Matthew (May 1, 2015). "Elon Musk's big announcement: it's called 'Tesla Energy'". Business Insider. Archived from the original on May 5, 2015. Retrieved June 11, 2015.
- "Tesla slashes price of the Powerpack system by another 10% with new generation". Electrek. May 15, 2017. Archived from the original on November 14, 2016. Retrieved November 14, 2016.
- "RoseWater Energy Group to Debut HUB 120 at CEDIA 2017". August 29, 2017. Archived from the original on June 5, 2019. Retrieved June 5, 2019.
- "Rosewater Energy - Products". Archived from the original on June 5, 2019. Retrieved June 5, 2019.
- "RoseWater Energy: The Cleanest, Greenest $60K Power Supply Ever". Commercial Integrator. October 19, 2015. Archived from the original on June 5, 2019. Retrieved June 5, 2019.
- "How RoseWater's Giant Home Battery is Different from Tesla's". CEPRO. October 19, 2015. Archived from the original on July 12, 2021. Retrieved July 12, 2021.
- Delacey, Lynda (October 29, 2015). "Enphase plug-and-play solar energy storage system to begin pilot program". www.gizmag.com. Archived from the original on December 22, 2015. Retrieved December 20, 2015.
- "Your Water Heater Can Become A High-Power Home Battery". popsci.com. Archived from the original on May 5, 2017. Retrieved May 16, 2017.
- Wright, matthew; Hearps, Patrick; et al. Australian Sustainable Energy: Zero Carbon Australia Stationary Energy Plan Archived November 24, 2015, at the Wayback Machine, Energy Research Institute, University of Melbourne, October 2010, p. 33. Retrieved from BeyondZeroEmissions.org website.
- Innovation in Concentrating Thermal Solar Power (CSP) Archived September 24, 2015, at the Wayback Machine, RenewableEnergyFocus.com website.
- Ray Stern. "Solana: 10 Facts You Didn't Know About the Concentrated Solar Power Plant Near Gila Bend". Phoenix New Times. Archived from the original on October 11, 2013. Retrieved December 6, 2015.
- Edwin Cartlidge (November 18, 2011). "Saving for a rainy day". Science (Vol 334). pp. 922–924. Missing or empty
- Wald, Matthew, L. Wind Drives Growing Use of Batteries Archived December 5, 2019, at the Wayback Machine, The New York Times, July 28, 2010, p. B1.
- Erik Ingebretsen; Tor Haakon Glimsdal Johansen (July 16, 2013). "The Potential of Pumped Hydro Storage in Norway (abstract)" (PDF). Retrieved February 16, 2014. Cite journal requires
|journal=(help)[permanent dead link]
- "Norway statistics - International Hydropower Association" Archived September 14, 2018, at the Wayback Machine. Retrieved on September 13, 2018.
- Wald, Matthew L. Ice or Molten Salt, Not Batteries, to Store Energy Archived November 12, 2020, at the Wayback Machine, The New York Times website, April 21, 2014, and in print on April 22, 2014, p. F7 of the New York edition. Retrieved May 29, 2014.
- Schmid, Jürgen. Renewable Energies and Energy Efficiency: Bioenergy and renewable power methane in integrated 100% renewable energy system Archived December 2, 2011, at the Wayback Machine (thesis), Universität Kassel/Kassel University Press, September 23, 2009.
- "Association négaWatt - Scénario négaWatt 2011". Archived from the original on January 5, 2012. Retrieved October 19, 2011.
- Wald, Matthew L. Taming Unruly Wind Power Archived December 2, 2012, at the Wayback Machine, The New York Times, November 4, 2011, and in print on November 5, 2011, p. B1 of the New York edition.
- Wald, Matthew, L. Sudden Surplus Calls for Quick Thinking Archived June 6, 2014, at the Wayback Machine, The New York Times online website, July 7, 2010.
- Thermal Energy Storage Myths Archived March 26, 2010, at the Wayback Machine, Calmac.com website.
- Fire and Ice based storage Archived August 25, 2009, at the Wayback Machine, DistributedEnergy.com website, April 2009.
- Air-Conditioning, Heating and Refrigeration Institute, Fundamentals of HVAC/R, Page 1263
- Bartłomiejczyk, Mikołaj (2018). "Potential Application of Solar Energy Systems for Electrified Urban Transportation Systems". Energies. 11 (4): 1. doi:10.3390/en11040954.
- Brelje, Benjamin J.; Martins, Joaquim R.R.A. (January 2019). "Electric, hybrid, and turboelectric fixed-wing aircraft: A review of concepts, models, and design approaches". Progress in Aerospace Sciences. 104: 1–19. doi:10.1016/j.paerosci.2018.06.004.
- Bird, John (2010). Electrical and Electronic Principles and Technology. Routledge. pp. 63–76. ISBN 9780080890562. Retrieved March 17, 2013.
- DOE Global Energy Storage Database Archived November 13, 2013, at the Wayback Machine, United States Department of Energy, Office of Electricity and Sandia National Labs.
- Herrman, Ulf; Nava, Paul (February 13, 2016). "Thermal Storage Concept for a 50 MW Trough Power Plant in Spain" (PDF). www.nrel.gov. NREL. Archived from the original (PDF) on April 2, 2016. Retrieved February 13, 2017.
- Doetsch, Christian (November 6, 2014). "Electric Storage Devices – "Definition" of Storage Capacity, Power, Efficiency" (PDF). www.iea-eces.org. Archived from the original (PDF) on February 13, 2017. Retrieved February 13, 2017.
- Locatelli, Giorgio; Palerma, Emanuele; Mancini, Mauro (April 1, 2015). "Assessing the economics of large Energy Storage Plants with an optimisation methodology". Energy. 83: 15–28. doi:10.1016/j.energy.2015.01.050.
- Locatelli, Giorgio; Invernizzi, Diletta Colette; Mancini, Mauro (June 1, 2016). "Investment and risk appraisal in energy storage systems: A real options approach" (PDF). Energy. 104: 114–131. doi:10.1016/j.energy.2016.03.098. Archived (PDF) from the original on July 19, 2018. Retrieved July 5, 2019.
- Loisel, Rodica; Mercier, Arnaud; Gatzen, Christoph; Elms, Nick; Petric, Hrvoje (2010). "Valuation framework for large scale electricity storage in a case with wind curtailment". Energy Policy. 38 (11): 7323–7337. doi:10.1016/j.enpol.2010.08.007.
- Wald, Matthew. Green Blog: The Convoluted Economics of Storing Energy Archived April 2, 2013, at the Wayback Machine, The New York Times, January 3, 2012.
- "Stanford scientists calculate the carbon footprint of grid-scale battery technologies". Stanford University. March 5, 2013. Archived from the original on December 2, 2015. Retrieved November 13, 2015.
- Perishable. "Global Energy Storage Database | Energy Storage Systems". Archived from the original on July 9, 2021. Retrieved July 9, 2021.
- "Hydropower Special Market Report – Analysis". IEA. Archived from the original on July 9, 2021. Retrieved July 9, 2021.
- "The $2.5 trillion reason we can't rely on batteries to clean up the grid". MIT Technology Review. Archived from the original on August 24, 2021. Retrieved July 9, 2021.
- "Relying on renewables alone significantly inflates the cost of overhauling energy". MIT Technology Review. Archived from the original on August 13, 2021. Retrieved July 9, 2021.
- Galbraith, Kate. Filling the Gaps in the Flow of Renewable Energy Archived April 10, 2017, at the Wayback Machine, The New York Times, October 22, 2013.
- Aschenbrenner, Norbert. Test Plant For Automated Battery Production Archived May 8, 2014, at the Wayback Machine, Physics.org website, May 6, 2014. Retrieved May 8, 2014.
- Produktionsforschung | Prozessentwicklung und Produktionstechnik für große Lithium-Ionen-Zellen Archived May 12, 2014, at the Wayback Machine, Zentrum für Sonnenenergie- und Wasserstoff-Forschung Baden-Württemberg website, 2011. (in German)
- Content, Thomas. Johnson Controls, UW Open Energy Storage Systems Test Lab In Madison Archived May 8, 2014, at the Wayback Machine, Milwaukee, Wisconsin: Milwaukee Journal Sentinel, May 5, 2014.
- Loudon, Bennett J. NY-BEST Opens $23M Energy Storage Center Archived July 28, 2020, at the Wayback Machine, Rochester, New York: Democrat and Chronicle, April 30, 2014.
- "Senators want more than $1 billion to promote energy storage answers". pv magazine USA. Archived from the original on September 28, 2017. Retrieved September 28, 2017.
- SUPERGEN hub to set the direction of the UK's energy storage Archived May 9, 2014, at the Wayback Machine, HVNPlus.co.uk website, May 6, 2014. Retrieved May 8, 2014.
- New SUPERGEN Hub to set UK's energy storage course Archived May 8, 2014, at the Wayback Machine, ECNMag.com website, May 2, 2014.
Journals and papers
- Chen, Haisheng; Thang Ngoc Cong; Wei Yang; Chunqing Tan; Yongliang Li; Yulong Ding. Progress in electrical energy storage system: A critical review, Progress in Natural Science, accepted July 2, 2008, published in Vol. 19, 2009, pp. 291–312, doi: 10.1016/j.pnsc.2008.07.014. Sourced from the National Natural Science Foundation of China and the Chinese Academy of Sciences. Published by Elsevier and Science in China Press. Synopsis: a review of electrical energy storage technologies for stationary applications. Retrieved from ac.els-cdn.com on May 13, 2014. (PDF)
- Corum, Lyn. The New Core Technology: Energy storage is part of the smart grid evolution, The Journal of Energy Efficiency and Reliability, December 31, 2009. Discusses: Anaheim Public Utilities Department, lithium ion energy storage, iCel Systems, Beacon Power, Electric Power Research Institute (EPRI), ICEL, Self Generation Incentive Program, ICE Energy, vanadium redox flow, lithium Ion, regenerative fuel cell, ZBB, VRB, lead acid, CAES, and Thermal Energy Storage. (PDF)
- de Oliveira e Silva, G.; Hendrick, P. (2016). "Lead-acid batteries coupled with photovoltaics for increased electricity self-sufficiency in households". Applied Energy. 178: 856–867. doi:10.1016/j.apenergy.2016.06.003.
- Whittingham, M. Stanley. History, Evolution, and Future Status of Energy Storage, Proceedings of the IEEE, manuscript accepted February 20, 2012, date of publication April 16, 2012; date of current version May 10, 2012, published in Proceedings of the IEEE, Vol. 100, May 13, 2012, 0018–9219, pp. 1518–1534, doi: 10.1109/JPROC.2012.219017. Retrieved from ieeexplore.ieee.org May 13, 2014. Synopsis: A discussion of the important aspects of energy storage including emerging battery technologies and the importance of storage systems in key application areas, including electronic devices, transportation, and the utility grid. (PDF)
- GA Mansoori, N Enayati, LB Agyarko (2016), Energy: Sources, Utilization, Legislation, Sustainability, Illinois as Model State, World Sci. Pub. Co., ISBN 978-981-4704-00-7
- Díaz-González, Franscisco (2016). Energy storage in power systems. United Kingdom: John Wiley & Sons. ISBN 9781118971321.
|Wikimedia Commons has media related to Energy storage.|
|Wikiversity has learning resources about Energy storage|
- U.S. Dept of Energy - Energy Storage Systems Government research center on energy storage technology.
- U.S. Dept of Energy - International Energy Storage Database Archived November 13, 2013, at the Wayback Machine The DOE International Energy Storage Database provides free, up-to-date information on grid-connected energy storage projects and relevant state and federal policies.
- IEEE Special Issue on Massive Energy Storage
- IEA-ECES - International Energy Agency - Energy Conservation through Energy Conservation programme.
- Energy Information Administration Glossary