The kinds of thermal energy storage can be divided into three separate categories: sensible heat, latent heat, and thermo-chemical heat storage. Each of these has different advantages and disadvantages that determine their applications.
Sensible heat storage Sensible heat storage (SHS) is the most straightforward method. It simply means the temperature of some medium is either increased or decreased. This type of storage is the most commercially available out of the three; other techniques are less developed. The materials are generally inexpensive and safe. One of the cheapest, most commonly used options is a water tank, but materials such as molten salts or metals can be heated to higher temperatures and therefore offer a higher storage capacity. Energy can also be stored underground (UTES), either in an underground tank or in some kind of heat-transfer fluid (HTF) flowing through a system of pipes, either placed vertically in U-shapes (boreholes) or horizontally in trenches. Yet another system is known as a packed-bed (or pebble-bed) storage unit, in which some fluid, usually air, flows through a bed of loosely packed material (usually rock, pebbles or ceramic brick) to add or extract heat. A disadvantage of SHS is its dependence on the properties of the storage medium. Storage capacities are limited by the
specific heat capacity of the storage material, and the system needs to be properly designed to ensure energy extraction at a constant temperature. Sensible heat storages normally have a low energy density, which means that they require large volumes and space for storage tanks and a slow loss of thermal energy over time even with the installations alongside the sensible heat storage.
Heat storage in tanks, ponds or rock caverns A steam accumulator consists of an insulated steel pressure tank containing hot water and steam under pressure. As a heat storage device, it is used to mediate heat production by a variable or steady source from a variable demand for heat. Steam accumulators may take on a significance for energy storage in
solar thermal energy projects. Heat storage tanks are being used globally, primarily in regions with established district heating networks and in sunny areas for a use of concentrated solar power. These tanks serve in residential, commercial, and industrial purposes, ranging from seasonal heating to balancing renewable energy grids. This is an example of a sensible heat storage device that has both its benefits and disadvantages. Intersessional storage in caverns has been investigated and appears to be economical and plays a significant role in
heating in Finland. Energy producer
Helen Oy estimates an 11.6 GWh capacity and 120 MW thermal output for its water cistern under
Mustikkamaa (fully charged or discharged in 4 days at capacity), operating from 2021 to offset days of peak production/demand; while the rock caverns under sea level in
Kruunuvuorenranta (near
Laajasalo) were designated in 2018 to store heat in summer from warm seawater and release it in winter for
district heating. In 2024, it was announced that the municipal energy supplier of
Vantaa had commissioned an underground heat storage facility of over in size and 90 GWh in capacity to be built, expected to be operational in 2028.
Molten salt technology The sensible heat of
molten salt is also used for storing solar energy at a high temperature, termed molten-salt technology or molten salt energy storage (MSES). Molten salts can be employed as a thermal energy storage method to retain thermal energy. Presently, this is a commercially used technology to store the heat collected by
concentrated solar power (e.g., from a
solar power tower or
solar trough). The heat can later be converted into superheated steam to power conventional steam turbines and generate electricity at a later time. It was demonstrated in the
Solar Two project from 1995 to 1999. Estimates in 2006 predicted an annual efficiency of 99%, a reference to the energy retained by storing heat before turning it into electricity, versus converting heat directly into electricity. Various
eutectic mixtures of different salts are used (e.g.,
sodium nitrate,
potassium nitrate and
calcium nitrate). Experience with such systems exists in non-solar applications in the chemical and metals industries as a heat-transport fluid. The salt melts at . It is kept liquid at in an insulated "cold" storage tank. The liquid salt is pumped through panels in a solar collector where the focused sun heats it to . It is then sent to a hot storage tank. With proper
insulation of the tank the thermal energy can be usefully stored for up to a week. When electricity is needed, the hot molten salt is pumped to a conventional
steam-generator to produce
superheated steam for driving a conventional turbine/generator set as used in a coal, oil, or nuclear power plant. A 100-megawatt turbine would need a tank of about tall and in diameter to drive it for four hours by this design.A single tank with a divider plate to separate cold and hot molten salt is under development. It is more economical by achieving 100% more heat storage per unit volume over the dual tanks system as the molten-salt storage tank is costly due to its complicated construction.
Phase-change materials (PCMs) are also used in molten-salt energy storage, while research on obtaining shape-stabilized PCMs using high porosity matrices is ongoing. Most
solar thermal power plants use this thermal energy storage concept. The
Solana Generating Station in the U.S. can store 6 hours worth of generating capacity in molten salt. During the summer of 2013 the
Gemasolar Thermosolar solar power-tower/molten-salt plant in Spain achieved a first by continuously producing electricity 24 hours per day for 36 days. The
Cerro Dominador Solar Thermal Plant, inaugurated in June 2021, has 17.5 hours of heat storage.
Silicon Solid or molten
silicon offers much higher storage temperatures than salts with consequent greater capacity and efficiency. It is being researched as a possible more energy efficient storage technology. Silicon is able to store more than 1 MWh of energy per cubic meter at 1400 °C. An additional advantage is the relative abundance of silicon when compared to the salts used for the same purpose. Hot silicon thermal energy storing technology would be able to store significant thermal energy at extremely high temperatures (around 1400-2000 °C). This would be utilized by using the white hot molten silicon to store excess electricity generated from surrounding renewable sources like solar energy and wind power. This system would enable efficient, lower costing, and a longer duration of energy storage compared to other sensible heat storage options.
Aluminum Another medium that can store thermal energy is molten (recycled) aluminum. This technology was developed by the Swedish company Azelio. The material is heated to 600 °C. When needed, the energy is transported to a
Stirling engine using a heat-transfer fluid. Molten aluminum is not widely used for energy storage due to some disadvantages that have yet to be overcome. This includes molten aluminum's reactivity and the challenges that come along with handling the solidification of the aluminum. However, research is being continued on how aluminum thermal storage could be used due to its high energy density. These aluminum based storage technologies have the potential to grow and to integrate renewable energy sources like solar and wind into the grid. These energy storage technologies are promising candidates for long term storage with minimal loss. A similar system was scheduled for
Sorø, Denmark, with 41–58% of the stored 18 MWh heat returned for the town's district heating, and 30–41% returned as electricity, but not retained. Disadvantages to the use of hot rocks and concrete involve both of their heat capacity compared to water (about one third) meaning that much larger volumes of solid materials are required to store the same amount of energy, making it less suitable for storage areas with limited amount of space. Their challenges also relate to their implementations and maintenance. Over time with these materials heat loss is inevitable, the degradation of the materials, and their high initial costs all bring up contemplation of use. Relating to the integration difficulties, they require a challenging design to connect the storage and heat source to a distribution system. Polar Night Energy installed a thermal battery in Finland that stores heat in a mass of sand. It was expected to reduce carbon emissions from the local heating network by as much as 70%. It is about 42 ft (13 m) tall and 50 ft (15 m) wide. It can store 100 MWh, with a round trip efficiency of 90%. Temperatures reach 1,112 °F (600 °C). The heat transfer medium is air, which can reach temperatures of 752 °F (400 °C) – can produce steam for industrial processes, or it can supply district heating using a
heat exchanger. Research is evaluating sintered bauxite proppants as the thermal store, heating them up to 1000 °C. This material was tested against plasma-sprayed alumina and mullite, alumina fiber reinforced/alumina matrix and mullite fiber reinforced/mullite ceramic matrix composites. These four materials were considered because of their usefulness as solar receivers, transport tubes and storage tanks.
Latent heat storage Because
latent heat storage (LHS) is associated with a
phase transition, the general term for the associated media is phase-change material (PCM). During these transitions, heat can be added or extracted without affecting the material's temperature, giving it an advantage over SHS-technologies. Storage capacities are often higher as well. There are a multitude of PCMs available, including but not limited to salts, polymers, gels, paraffin waxes, metal alloys and semiconductor-metal alloys, each with different properties. This allows for a more target-oriented system design. As the process is
isothermal at the PCM's melting point, the material can be picked to have the desired temperature range. Desirable qualities include high latent heat and thermal conductivity. Furthermore, the storage unit can be more compact if volume changes during the phase transition are small. PCMs are further subdivided into organic, inorganic and eutectic materials. Compared to organic PCMs, inorganic materials are less flammable, cheaper and more widely available. They also have higher storage capacity and thermal conductivity. Organic PCMs, on the other hand, are less corrosive and not as prone to phase-separation.
Eutectic materials, as they are mixtures, are more easily adjusted to obtain specific properties, but have low latent and specific heat capacities. Another important factor in LHS is the encapsulation of the PCM. Some materials are more prone to erosion and leakage than others. The system must be carefully designed in order to avoid unnecessary loss of heat. rely on the
phase change of a metallic material (see:
latent heat) to store thermal energy. Rather than pumping the liquid metal between tanks as in a molten-salt system, the metal is encapsulated in another metallic material that it cannot alloy with (
immiscible). Depending on the two materials selected (the phase changing material and the encapsulating material) storage densities can be between 0.2 and 2 MJ/L. A working fluid, typically water or steam, is used to transfer the heat into and out of the system.
Thermal conductivity of miscibility gap alloys is often higher (up to 400 W/(m⋅K)) than competing technologies which means quicker "charge" and "discharge" of the thermal storage is possible. The technology has not yet been implemented on a large scale. However, The miscibility Gap Alloy technology is being primarily implemented in Australia, this is where it was developed by the University of Newcastle researchers and is being brought to the market by the company MGA thermal. Applications of this are slowly popping up around other parts of the world such as a planned demonstration plant in Europe with a Swiss commercial partner to store renewable energy and provide clean power.
Ice-based technology Several applications are being developed where ice is produced during off-peak periods and used for cooling at a later time. For example, air conditioning can be provided more economically by using low-cost electricity at night to freeze water into ice, then using the
cooling capacity of ice in the afternoon to reduce the electricity needed to handle air conditioning demands. Thermal energy storage using ice makes use of the large
heat of fusion of water. Historically, ice was transported from mountains to cities for use as a coolant. One
metric ton of water (= one cubic meter) can store 334 million
joules (MJ) or 317,000
BTUs (93 kWh). A relatively small storage facility can hold enough ice to cool a large building for a day or a week. Currently, ice storage air conditioning is being used globally with there being significant use in the United States in mostly hotels, commercial buildings and universities. Its other place of use is in China, specifically in public utilities in Shenzhen. Other places where it is being used but less notable would be in Japan, Turkey, and Malaysia (Song et al.). This technology is effective in areas with high cooling demand and areas with a distinguishable time of lower electricity rates, this is what the lower pricing is reliant upon. This allows for the storage of cold energy to be mainly produced during low-cost hours for use during high demand periods. Disadvantages that this form of cold energy storing technology come with include high initial costs and the need for significant physical space of the large storage tanks. There may also be lower energy efficiency due to the chillers performing at lower temperatures in order to make ice. Cryogenic Energy storage is a good option for energy use since it is able to be location independent. As long as there is the space needed for the storage of these containers, it would be possible to build. This energy storage is also known to have the ability for long storage duration, although it does have high costs for standalone systems. This makes sense because there is an essential high energy input needed for the liquefaction process of non-toxic materials.
Thermo-chemical heat storage Thermo-chemical heat storage (TCS) involves some kind of reversible
exotherm/
endotherm chemical reaction with thermo-chemical materials (TCM) . Depending on the reactants, this method can allow for an even higher storage capacity than LHS. In one type of TCS, heat is applied to decompose certain molecules. The reaction products are then separated, and mixed again when required, resulting in a release of energy. Some examples are the decomposition of
potassium oxide (over a range of 300–800 °C, with a heat decomposition of 2.1 MJ/kg),
lead oxide (300–350 °C, 0.26 MJ/kg) and
calcium hydroxide (above 450 °C, where the reaction rates can be increased by adding zinc or aluminum). The photochemical decomposition of
nitrosyl chloride can also be used and, since it needs photons to occur, works especially well when paired with solar energy. Advantages over molten salts and other high temperature TES include that (1) the temperature required is only the stagnation temperature typical of a solar flat plate thermal collector, and (2) as long as the zeolite is kept dry, the energy is stored indefinitely. Because of the low temperature, and because the energy is stored as latent heat of adsorption, thus eliminating the insulation requirements of a molten salt storage system, costs are significantly lower. Disadvantages of solar heating and storage include their lower energy density compared to other thermal energy systems and also how relatively slow the energy transfer process is in the system known as the absorption bed. In addition, in order to keep maximum performance up, the system requires tedious maintenance of the controls. These controls manage factors such as humidity, temperature, and airflow which can alter operating conditions. In 2013 the Dutch technology developer TNO presented the results of the MERITS project to store heat in a salt container. The heat, which can be derived from a solar collector on a rooftop, expels the water contained in the salt. When the water is added again, the heat is released, with almost no energy losses. A container with a few cubic meters of salt could store enough of this thermochemical energy to heat a house throughout the winter. In a temperate climate like that of the Netherlands, an average low-energy household requires about 6.7 GJ/winter. To store this energy in water (at a temperature difference of 70 °C), 23 m3 insulated water storage would be needed, exceeding the storage abilities of most households. Using salt hydrate technology with a storage density of about 1 GJ/m3, 4–8 m3 could be sufficient. As of 2016, researchers in several countries are conducting experiments to determine the best type of salt, or salt mixture. Low pressure within the container seems favorable for the energy transport. Especially promising are organic salts, so called
ionic liquids. Compared to lithium halide-based sorbents they are less problematic in terms of limited global resources and compared to most other halides and sodium hydroxide (NaOH) they are less corrosive and not negatively affected by CO2 contaminations. Even though salts have several benefits, salt hydrate technology also has many downsides. This is because even though the use of organic salts and ionic liquids show potential in long term stability and cost effectiveness in large scale applications, the corrosive nature of the salts used, like potassium chloride, demand the use of specific and costly corrosion resistant materials. Salts also crystallize during the hydration and dehydration phases, which reduces their reactivity and eventually the entire system, this is yet another disadvantage of theirs. This technology is still undergoing further evaluation in order to be used more widely.
Molecular bonds Storing energy in molecular bonds is being investigated. Energy densities equivalent to
lithium-ion batteries have been achieved. This has been done by a DSPEC (dys-sensitized photoelectrosythesis cell). This is a cell that can store energy that has been acquired by solar panels during the day for night-time (or even later) use. It is designed by taking an indication from, well known, natural photosynthesis. The DSPEC generates hydrogen fuel by making use of the acquired solar energy to split water molecules into its elements. As the result of this split, the hydrogen is isolated and the oxygen is released into the air. This sounds easier than it actually is. Four electrons of the water molecules need to be separated and transported elsewhere. Another difficult part is the process of merging the two separate hydrogen molecules. The DSPEC consists of two components: a molecule and a
nanoparticle. The molecule is called a chromophore-catalyst assembly which absorbs sunlight and kick starts the catalyst. This catalyst separates the electrons and the water molecules. The nanoparticles are assembled into a thin layer and a single nanoparticle has many chromophore-catalyst on it. The function of this thin layer of nanoparticles is to transfer away the electrons which are separated from the water. This thin layer of nanoparticles is coated by a layer of titanium dioxide. With this coating, the electrons that come free can be transferred more quickly so that hydrogen could be made. This coating is, again, coated with a protective coating that strengthens the connection between the chromophore-catalyst and the nanoparticle. Using this method, the solar energy acquired from the solar panels is converted into fuel (hydrogen) without releasing the so-called greenhouse gasses. This fuel can be stored into a fuel cell and, at a later time, used to generate electricity.
Molecular Solar Thermal System Another promising way to store solar energy for electricity and heat production is molecular solar thermal (MOST). This approach converts molecules by
photoisomerization into a higher-energy
isomer. Light (sunlight) converts one isomer into another. This second isomer stores the solar energy until the energy is released by a heat trigger or catalyst (converting the isomer into its original isomer). One promising candidate for MOST is
norbornadiene (NBD). This is because NBD exhibits a high energy difference between its typical form and its
quadricyclane (QC) photoisomer, approximately 96 kJ/mol. For such systems, the donor-acceptor substitutions provide an effective means for red shifting the longest-wavelength absorption. This improves the match to the
solar spectrum. One challenge for a useful MOST system is to acquire sufficient energy storage density (higher than 300 kJ/kg). Another challenge is that light can be harvested in the visible region. The functionalization of the NBD with the donor and acceptor units is used to adjust this absorption maxima. However, this positive effect on absorption is offset by a higher molecular weight, reducing energy density. This positive effect on the solar absorption reduces the energy storage time when the absorption is redshifted. A possible solution is to couple one
chromophore unit to several photo switches. In this case, it is advantageous to form
dimers or trimers. The NBD share a common donor or acceptor. One study tried to improve the stability of the high energy photoisomer by using two electronically coupled photo switches with separate barriers for thermal conversion. This caused a blue shift after the first isomerization (NBD-NBD to QC-NBD). This led to a higher energy of isomerization of the second switching event (QC-NBD to QC-QC). Another advantage of sharing a donor, is that the molecular weight per NBD unit is reduced, increasing energy density. Eventually, this system could reach a
quantum yield of photoconversion up 94%. Quantum yield is a measure of the efficiency of photon emission. With this system energy densities reached up to 559 kJ/kg. In 2026, researchers reported that a
pyrimidone-based MOST system using a Dewar pyrimidone could provide multi-year storage at an
energy density of 1.6 MJ/kg (444 Wh/kg). == Thermal battery ==