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Magnetic refrigeration

October 27, 2023

Magnetic refrigeration is a cooling technology based on the magnetocaloric effect. This technique can be used to attain extremely low temperatures, as well as the ranges used in common refrigerators.[1][2][3][4]

Gadolinium alloy heats up inside the magnetic field and loses thermal energy to the environment, so it exits the field and becomes cooler than when it entered.

A magnetocaloric material warms up when a magnetic field is applied. The warming is due to changes in the internal state of the material releasing heat. When the magnetic field is removed, the material returns to its original state, reabsorbing the heat, and returning to original temperature. To achieve refrigeration, the material is allowed to radiate away its heat while in the magnetized hot state. Removing the magnetism, the material then cools to below its original temperature.

The effect was first observed in 1881 by a German physicist Emil Warburg, followed by French physicist P. Weiss and Swiss physicist A. Piccard in 1917.[5] The fundamental principle was suggested by P. Debye (1926) and W. Giauque (1927).[6] The first working magnetic refrigerators were constructed by several groups beginning in 1933. Magnetic refrigeration was the first method developed for cooling below about 0.3 K (a temperature attainable by pumping on 3
He vapors).

Magnetocaloric effect edit

The magnetocaloric effect (MCE, from magnet and calorie) is a magneto-thermodynamic phenomenon in which a temperature change of a suitable material is caused by exposing the material to a changing magnetic field. This is also known by low temperature physicists as adiabatic demagnetization. In that part of the refrigeration process, a decrease in the strength of an externally applied magnetic field allows the magnetic domains of a magnetocaloric material to become disoriented from the magnetic field by the agitating action of the thermal energy (phonons) present in the material. If the material is isolated so that no energy is allowed to (re)migrate into the material during this time, (i.e., an adiabatic process) the temperature drops as the domains absorb the thermal energy to perform their reorientation. The randomization of the domains occurs in a similar fashion to the randomization at the curie temperature of a ferromagnetic material, except that magnetic dipoles overcome a decreasing external magnetic field while energy remains constant, instead of magnetic domains being disrupted from internal ferromagnetism as energy is added.

One of the most notable examples of the magnetocaloric effect is in the chemical element gadolinium and some of its alloys. Gadolinium's temperature increases when it enters certain magnetic fields. When it leaves the magnetic field, the temperature drops. The effect is considerably stronger for the gadolinium alloy Gd
5(Si
2Ge
2).[7] Praseodymium alloyed with nickel (PrNi
5) has such a strong magnetocaloric effect that it has allowed scientists to approach to within one millikelvin, one thousandth of a degree of absolute zero.[8]

Equation edit

The magnetocaloric effect can be quantified with the following equation:

 

where   is the adiabatic change in temperature of the magnetic system around temperature T, H is the applied external magnetic field, C is the heat capacity of the working magnet (refrigerant) and M is the magnetization of the refrigerant.

From the equation we can see that the magnetocaloric effect can be enhanced by:

  • a large field variation
  • a magnet material with a small heat capacity
  • a magnet with large changes in net magnetization vs. temperature, at constant magnetic field

The adiabatic change in temperature,  , can be seen to be related to the magnet's change in magnetic entropy ( ) since[9]

 

This implies that the absolute change in the magnet's entropy determines the possible magnitude of the adiabatic temperature change under a thermodynamic cycle of magnetic field variation. T

Thermodynamic cycle edit

 
Analogy between magnetic refrigeration and vapor cycle or conventional refrigeration. H = externally applied magnetic field; Q = heat quantity; P = pressure; ΔTad = adiabatic temperature variation

The cycle is performed as a refrigeration cycle that is analogous to the Carnot refrigeration cycle, but with increases and decreases in magnetic field strength instead of increases and decreases in pressure. It can be described at a starting point whereby the chosen working substance is introduced into a magnetic field, i.e., the magnetic flux density is increased. The working material is the refrigerant, and starts in thermal equilibrium with the refrigerated environment.

  • Adiabatic magnetization: A magnetocaloric substance is placed in an insulated environment. The increasing external magnetic field (+H) causes the magnetic dipoles of the atoms to align, thereby decreasing the material's magnetic entropy and heat capacity. Since overall energy is not lost (yet) and therefore total entropy is not reduced (according to thermodynamic laws), the net result is that the substance is heated (T + ΔTad).
  • Isomagnetic enthalpic transfer: This added heat can then be removed (-Q) by a fluid or gas — gaseous or liquid helium, for example. The magnetic field is held constant to prevent the dipoles from reabsorbing the heat. Once sufficiently cooled, the magnetocaloric substance and the coolant are separated (H=0).
  • Adiabatic demagnetization: The substance is returned to another adiabatic (insulated) condition so the total entropy remains constant. However, this time the magnetic field is decreased, the thermal energy causes the magnetic moments to overcome the field, and thus the sample cools, i.e., an adiabatic temperature change. Energy (and entropy) transfers from thermal entropy to magnetic entropy, measuring the disorder of the magnetic dipoles.[10]
  • Isomagnetic entropic transfer: The magnetic field is held constant to prevent the material from reheating. The material is placed in thermal contact with the environment to be refrigerated. Because the working material is cooler than the refrigerated environment (by design), heat energy migrates into the working material (+Q).

Once the refrigerant and refrigerated environment are in thermal equilibrium, the cycle can restart.

Applied technique edit

The basic operating principle of an adiabatic demagnetization refrigerator (ADR) is the use of a strong magnetic field to control the entropy of a sample of material, often called the "refrigerant". Magnetic field constrains the orientation of magnetic dipoles in the refrigerant. The stronger the magnetic field, the more aligned the dipoles are, corresponding to lower entropy and heat capacity because the material has (effectively) lost some of its internal degrees of freedom. If the refrigerant is kept at a constant temperature through thermal contact with a heat sink (usually liquid helium) while the magnetic field is switched on, the refrigerant must lose some energy because it is equilibrated with the heat sink. When the magnetic field is subsequently switched off, the heat capacity of the refrigerant rises again because the degrees of freedom associated with orientation of the dipoles are once again liberated, pulling their share of equipartitioned energy from the motion of the molecules, thereby lowering the overall temperature of a system with decreased energy. Since the system is now insulated when the magnetic field is switched off, the process is adiabatic, i.e., the system can no longer exchange energy with its surroundings (the heat sink), and its temperature decreases below its initial value, that of the heat sink.

The operation of a standard ADR proceeds roughly as follows. First, a strong magnetic field is applied to the refrigerant, forcing its various magnetic dipoles to align and putting these degrees of freedom of the refrigerant into a state of lowered entropy. The heat sink then absorbs the heat released by the refrigerant due to its loss of entropy. Thermal contact with the heat sink is then broken so that the system is insulated, and the magnetic field is switched off, increasing the heat capacity of the refrigerant, thus decreasing its temperature below the temperature of the heat sink. In practice, the magnetic field is decreased slowly in order to provide continuous cooling and keep the sample at an approximately constant low temperature. Once the field falls to zero or to some low limiting value determined by the properties of the refrigerant, the cooling power of the ADR vanishes, and heat leaks will cause the refrigerant to warm up.

Working materials edit

The magnetocaloric effect (MCE) is an intrinsic property of a magnetic solid. This thermal response of a solid to the application or removal of magnetic fields is maximized when the solid is near its magnetic ordering temperature. Thus, the materials considered for magnetic refrigeration devices should be magnetic materials with a magnetic phase transition temperature near the temperature region of interest.[11] For refrigerators that could be used in the home, this temperature is room temperature. The temperature change can be further increased when the order-parameter of the phase transition changes strongly within the temperature range of interest.[2]

The magnitudes of the magnetic entropy and the adiabatic temperature changes are strongly dependent upon the magnetic ordering process. The magnitude is generally small in antiferromagnets, ferrimagnets and spin glass systems but can be much larger for ferromagnets that undergo a magnetic phase transition. First order phase transitions are characterized by a discontinuity in the magnetization changes with temperature, resulting in a latent heat.[11] Second order phase transitions do not have this latent heat associated with the phase transition.[11]

In the late 1990s Pecharksy and Gschneidner reported a magnetic entropy change in Gd
5(Si
2Ge
2) that was about 50% larger than that reported for Gd metal, which had the largest known magnetic entropy change at the time.[12] This giant magnetocaloric effect (GMCE) occurred at 270 K, which is lower than that of Gd (294 K).[4] Since the MCE occurs below room temperature these materials would not be suitable for refrigerators operating at room temperature.[13] Since then other alloys have also demonstrated the giant magnetocaloric effect. These include Gd
5(Si
xGe
1−x)
4, La(Fe
xSi
1−x)
13H
x and MnFeP
1−xAs
x alloys.[11][13] Gadolinium and its alloys undergo second-order phase transitions that have no magnetic or thermal hysteresis.[14] However, the use of rare earth elements makes these materials very expensive.

Current research has been used to describe alloys with a significant magnetocaloric effect in terms of a thermodynamic system. Literature says that Gd5(Si2Ge2) for example may be described as a thermodynamic system provided it satisfies the condition of being “a quantity of matter or region in space chosen for study”.[15] Such systems have become relevant to modern research in thermodynamics because they serve as plausible materials for the creation of high performance thermoelectric materials.

Ni
2Mn-X (X = Ga, Co, In, Al, Sb) Heusler alloys are also promising candidates for magnetic cooling applications because they have Curie temperatures near room temperature and, depending on composition, can have martensitic phase transformations near room temperature.[3] These materials exhibit the magnetic shape memory effect and can also be used as actuators, energy harvesting devices, and sensors.[16] When the martensitic transformation temperature and the Curie temperature are the same (based on composition) the magnitude of the magnetic entropy change is the largest.[2] In February 2014, GE announced the development of a functional Ni-Mn-based magnetic refrigerator.[17][18]

The development of this technology is very material-dependent and will likely not replace vapor-compression refrigeration without significantly improved materials that are cheap, abundant, and exhibit much larger magnetocaloric effects over a larger range of temperatures. Such materials need to show significant temperature changes under a field of two tesla or less, so that permanent magnets can be used for the production of the magnetic field.[19][20]

Paramagnetic salts edit

The original proposed refrigerant was a paramagnetic salt, such as cerium magnesium nitrate. The active magnetic dipoles in this case are those of the electron shells of the paramagnetic atoms.

In a paramagnetic salt ADR, the heat sink is usually provided by a pumped 4
He (about 1.2 K) or 3
He (about 0.3 K) cryostat. An easily attainable 1 T magnetic field is generally required for initial magnetization. The minimum temperature attainable is determined by the self-magnetization tendencies of the refrigerant salt, but temperatures from 1 to 100 mK are accessible. Dilution refrigerators had for many years supplanted paramagnetic salt ADRs, but interest in space-based and simple to use lab-ADRs has remained, due to the complexity and unreliability of the dilution refrigerator.

At a low enough temperature, paramagnetic salts become either diamagnetic or ferromagnetic, limiting the lowest temperature that can be reached using this method.[citation needed]

Nuclear demagnetization edit

One variant of adiabatic demagnetization that continues to find substantial research application is nuclear demagnetization refrigeration (NDR). NDR follows the same principles, but in this case the cooling power arises from the magnetic dipoles of the nuclei of the refrigerant atoms, rather than their electron configurations. Since these dipoles are of much smaller magnitude, they are less prone to self-alignment and have lower intrinsic minimum fields. This allows NDR to cool the nuclear spin system to very low temperatures, often 1 µK or below. Unfortunately, the small magnitudes of nuclear magnetic dipoles also makes them less inclined to align to external fields. Magnetic fields of 3 teslas or greater are often needed for the initial magnetization step of NDR.

In NDR systems, the initial heat sink must sit at very low temperatures (10–100 mK). This precooling is often provided by the mixing chamber of a dilution refrigerator[21] or a paramagnetic salt.

Commercial development edit

Research and a demonstration proof of concept device in 2001 succeeded in applying commercial-grade materials and permanent magnets at room temperatures to construct a magnetocaloric refrigerator.[22]

On August 20, 2007, the Risø National Laboratory (Denmark) at the Technical University of Denmark, claimed to have reached a milestone in their magnetic cooling research when they reported a temperature span of 8.7 K.[23] They hoped to introduce the first commercial applications of the technology by 2010.

As of 2013 this technology had proven commercially viable only for ultra-low temperature cryogenic applications available for decades. Magnetocaloric refrigeration systems are composed of pumps, motors, secondary fluids, heat exchangers of different types, magnets and magnetic materials. These processes are greatly affected by irreversibilities and should be adequately considered. At year-end, Cooltech Applications[24] announced that its first commercial refrigeration equipment would enter the market in 2014. Cooltech Applications launched their first commercially available magnetic refrigeration system on 20 June 2016. At the 2015 Consumer Electronics Show in Las Vegas, a consortium of Haier, Astronautics Corporation of America and BASF presented the first cooling appliance.[25] BASF claim of their technology a 35% improvement over using compressors.[26]

In November 2015, at the Medica 2015 fair,[27] Cooltech Applications presented, in collaboration with Kirsch medical GmbH, the world's first magnetocaloric medical cabinet.[28] One year later, in September 2016, at the 7th International Conference on Magnetic Refrigeration at Room Temperature (Thermag VII)] held in Torino, Italy, Cooltech Applications presented the world's first magnetocaloric frozen heat exchanger.[29]

In 2017, Cooltech Applications presented a fully functional 500 liters' magnetocaloric cooled cabinet with a 30 kg load and an air temperature inside the cabinet of +2 °C. That proved that magnetic refrigeration is a mature technology, capable of replacing the classic refrigeration solutions.[30]

One year later, in September 2018, at the 8th International Conference on Magnetic Refrigeration at Room Temperature (Thermag VIII]), Cooltech Applications presented a paper on a magnetocaloric prototype designed as a 15 kW proof-of-concept unit.[31] This has been considered by the community as the largest magnetocaloric prototype ever created.[32]

At the same conference, it has been announced that, due to financial issues, Cooltech Applications declared bankruptcy.[33] Later on, in 2019 Ubiblue company, today named Magnoric, is formed by some of the old Cooltech Application's team members. The entire patent portfolio form Cooltech Applications was taken over by Magnoric since then, while publishing additional patents at the same time.

In 2019, at the 5th Delft Days Conference on Magnetocalorics Ubiblue presented their last prototype.[34] Later, the magnetocaloric community acknowledged that Ubiblue had the most developed magnetocalorics prototypes.[35]

Thermal and magnetic hysteresis problems remain to be solved for first-order phase transition materials that exhibit the GMCE.[19]

One potential application is in spacecraft.

Vapor-compression refrigeration units typically achieve performance coefficients of 60% of that of a theoretical ideal Carnot cycle, much higher than current MR technology. Small domestic refrigerators are however much less efficient.[36]

In 2014 giant anisotropic behaviour of the magnetocaloric effect was found in HoMn
2O
5 at 10 K. The anisotropy of the magnetic entropy change gives rise to a large rotating MCE offering the possibility to build simplified, compact, and efficient magnetic cooling systems by rotating it in a constant magnetic field.[37]

In 2015 Aprea et al.[38] presented a new refrigeration concept, GeoThermag, which is a combination of magnetic refrigeration technology with that of low-temperature geothermal energy. To demonstrate the applicability of the GeoThermag technology, they developed a pilot system that consists of a 100-m deep geothermal probe; inside the probe, water flows and is used directly as a regenerating fluid for a magnetic refrigerator operating with gadolinium. The GeoThermag system showed the ability to produce cold water even at 281.8 K in the presence of a heat load of 60 W. In addition, the system has shown the existence of an optimal frequency f AMR, 0.26 Hz, for which it was possible to produce cold water at 287.9 K with a thermal load equal to 190 W with a COP of 2.20. Observing the temperature of the cold water that was obtained in the tests, the GeoThermag system showed a good ability to feed the cooling radiant floors and a reduced capacity for feeding the fan coil systems.

History edit

The effect was discovered first observed by German physicist Emil Warburg in 1881[39] Subsequently by French physicist Pierre Weiss and Swiss physicist Auguste Piccard in 1917.[5]

Major advances first appeared in the late 1920s when cooling via adiabatic demagnetization was independently proposed by Peter Debye in 1926 and chemistry Nobel Laureate William F. Giauque in 1927.

It was first demonstrated experimentally by Giauque and his colleague D. P. MacDougall in 1933 for cryogenic purposes when they reached 0.25 K.[40] Between 1933 and 1997, advances in MCE cooling occurred.[41]

In 1997, the first near room-temperature proof of concept magnetic refrigerator was demonstrated by Karl A. Gschneidner, Jr. by the Iowa State University at Ames Laboratory. This event attracted interest from scientists and companies worldwide who started developing new kinds of room temperature materials and magnetic refrigerator designs.[7]

A major breakthrough came 2002 when a group at the University of Amsterdam demonstrated the giant magnetocaloric effect in MnFe(P,As) alloys that are based on abundant materials.[42]

Refrigerators based on the magnetocaloric effect have been demonstrated in laboratories, using magnetic fields starting at 0.6 T up to 10 T. Magnetic fields above 2 T are difficult to produce with permanent magnets and are produced by a superconducting magnet (1 T is about 20.000 times the Earth's magnetic field).

Room temperature devices edit

Recent research has focused on near room temperature. Constructed examples of room temperature magnetic refrigerators include:

Room temperature magnetic refrigerators
Sponsor Location Announcement date Type Max. cooling power (W)[1] Max ΔT (K)[2] Magnetic field (T) Solid refrigerant Quantity (kg) COP (-)[3]
Ames Laboratory/Astronautics[43] Ames, Iowa/Madison, Wisconsin, US February 20, 1997 Reciprocating 600 10 5 (S) Gd spheres
Mater. Science Institute Barcelona[44][45] Barcelona, Spain May 2000 Rotary ? 5 0.95 (P) Gd foil
Chubu Electric/Toshiba[46] Yokohama, Japan Summer 2000 Reciprocating 100 21 4 (S) Gd spheres
University of Victoria[47][48] Victoria, British Columbia Canada July 2001 Reciprocating 2 14 2 (S) Gd & Gd
1−xTb
x L.B.
Astronautics[49] Madison, Wisconsin, US September 18, 2001 Rotary 95 25 1.5 (P) Gd spheres
Sichuan Inst. Tech./Nanjing University[50] Nanjing, China 23 April 2002 Reciprocating ? 23 1.4 (P) Gd spheres and Gd5Si1.985Ge1.985Ga0.03 powder
Chubu Electric/Toshiba[51] Yokohama, Japan October 5, 2002 Reciprocating 40 27 0.6 (P) Gd
1−xDy
x L.B.
Chubu Electric/Toshiba[51] Yokohama, Japan March 4, 2003 Rotary 60 10 0.76 (P) Gd
1−xDy
x L.B.		 1
Lab. d’Electrotechnique Grenoble[52] Grenoble, France April 2003 Reciprocating 8.8 4 0.8 (P) Gd foil
George Washington University[53] US July 2004 Reciprocating ? 5 2 (P) Gd foil
Astronautics[54] Madison, Wisconsin, US 2004 Rotary 95 25 1.5 (P) Gd and GdEr spheres / La(Fe
0.88Si130−
0.12H
1.0
University of Victoria[55] Victoria, British Columbia Canada 2006 Reciprocating 15 50 2 (S) Gd, Gd
0.74Tb
0.26 and Gd
0.85Er
0.15 pucks		 0.12
University of Salerno[56] Salerno, Italy 2016 Rotary 250 12 1.2 (P) Gd 0.600 mm spherical particles 1.20 0.5 - 2.5
MISiS[57] Tver and Moscow, Russia 2019 High speed rotary ? ? ? Gd bricks of two types, cascaded
1maximum cooling power at zero temperature difference (ΔT=0); 2maximum temperature span at zero cooling capacity (W=0); L.B. = layered bed; P = permanent magnet; S = superconducting magnet; 3 COP values under different operating conditions

In one example, Prof. Karl A. Gschneidner, Jr. unveiled a proof of concept magnetic refrigerator near room temperature on February 20, 1997. He also announced the discovery of the GMCE in Gd
5Si
2Ge
2 on June 9, 1997.[12] Since then, hundreds of peer-reviewed articles have been written describing materials exhibiting magnetocaloric effects.

See also edit

References edit

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Further reading edit

  • Lounasmaa, Experimental Principles and Methods Below 1 K, Academic Press (1974).
  • Richardson and Smith, Experimental Techniques in Condensed Matter Physics at Low Temperatures, Addison Wesley (1988).
  • Lucia, U (2008). "General approach to obtain the magnetic refrigeration ideal Coefficient of Performance COP". Physica A: Statistical Mechanics and Its Applications. 387 (14): 3477–3479. arXiv:1011.1684. Bibcode:2008PhyA..387.3477L. doi:10.1016/j.physa.2008.02.026.
  • Bouhani, H (2020). "Engineering the magnetocaloric properties of PrVO3 epitaxial oxide thin films by strain effects". Applied Physics Letters. 117 (7): 072402. arXiv:2008.09193. Bibcode:2020ApPhL.117g2402B. doi:10.1063/5.0021031. S2CID 225378969.
  • de Souza, M. (2021). "Elastocaloric-effect-induced adiabatic magnetization in paramagnetic salts due to the mutual interactions". Scientific Reports. 11 (9461): 9431. Bibcode:2021NatSR..11.9431S. doi:10.1038/s41598-021-88778-4. PMC 8093207. PMID 33941810.

External links edit

  • Cooling by adiabatic demagnetization - The Feynman Lectures on Physics
  • What is magnetocaloric effect and what materials exhibit this effect the most?
  • .
  • Terry Heppenstall's notes, University of Newcastle upon Tyne (November 2000)
  • Executive Summary: A Continuous Adiabatic Demagnetization Refrigerator (.doc format) (Google cache)
  • Origin and tuning of the magnetocaloric effect in the magnetic refrigerant Mn1.1Fe0.9(P0.8Ge0.2)
  • [1] Magnetic technology revolutionizes refrigeration]
  • Evaluation of thermodynamic quantities in magnetic refrigeration

October 27, 2023
magnetic, refrigeration, cooling, technology, based, magnetocaloric, effect, this, technique, used, attain, extremely, temperatures, well, ranges, used, common, refrigerators, gadolinium, alloy, heats, inside, magnetic, field, loses, thermal, energy, environme. Magnetic refrigeration is a cooling technology based on the magnetocaloric effect This technique can be used to attain extremely low temperatures as well as the ranges used in common refrigerators 1 2 3 4 Gadolinium alloy heats up inside the magnetic field and loses thermal energy to the environment so it exits the field and becomes cooler than when it entered A magnetocaloric material warms up when a magnetic field is applied The warming is due to changes in the internal state of the material releasing heat When the magnetic field is removed the material returns to its original state reabsorbing the heat and returning to original temperature To achieve refrigeration the material is allowed to radiate away its heat while in the magnetized hot state Removing the magnetism the material then cools to below its original temperature The effect was first observed in 1881 by a German physicist Emil Warburg followed by French physicist P Weiss and Swiss physicist A Piccard in 1917 5 The fundamental principle was suggested by P Debye 1926 and W Giauque 1927 6 The first working magnetic refrigerators were constructed by several groups beginning in 1933 Magnetic refrigeration was the first method developed for cooling below about 0 3 K a temperature attainable by pumping on 3 He vapors Contents 1 Magnetocaloric effect 1 1 Equation 1 2 Thermodynamic cycle 1 3 Applied technique 2 Working materials 2 1 Paramagnetic salts 2 2 Nuclear demagnetization 3 Commercial development 4 History 4 1 Room temperature devices 5 See also 6 References 7 Further reading 8 External linksMagnetocaloric effect editThe magnetocaloric effect MCE from magnet and calorie is a magneto thermodynamic phenomenon in which a temperature change of a suitable material is caused by exposing the material to a changing magnetic field This is also known by low temperature physicists as adiabatic demagnetization In that part of the refrigeration process a decrease in the strength of an externally applied magnetic field allows the magnetic domains of a magnetocaloric material to become disoriented from the magnetic field by the agitating action of the thermal energy phonons present in the material If the material is isolated so that no energy is allowed to re migrate into the material during this time i e an adiabatic process the temperature drops as the domains absorb the thermal energy to perform their reorientation The randomization of the domains occurs in a similar fashion to the randomization at the curie temperature of a ferromagnetic material except that magnetic dipoles overcome a decreasing external magnetic field while energy remains constant instead of magnetic domains being disrupted from internal ferromagnetism as energy is added One of the most notable examples of the magnetocaloric effect is in the chemical element gadolinium and some of its alloys Gadolinium s temperature increases when it enters certain magnetic fields When it leaves the magnetic field the temperature drops The effect is considerably stronger for the gadolinium alloy Gd5 Si2 Ge2 7 Praseodymium alloyed with nickel PrNi5 has such a strong magnetocaloric effect that it has allowed scientists to approach to within one millikelvin one thousandth of a degree of absolute zero 8 Equation edit The magnetocaloric effect can be quantified with the following equation D T a d H 0 H 1 T C T H H M T H T H d H displaystyle Delta T ad int H 0 H 1 left frac T C T H right H left frac partial M T H partial T right H dH nbsp where D T a d displaystyle Delta T ad nbsp is the adiabatic change in temperature of the magnetic system around temperature T H is the applied external magnetic field C is the heat capacity of the working magnet refrigerant and M is the magnetization of the refrigerant From the equation we can see that the magnetocaloric effect can be enhanced by a large field variation a magnet material with a small heat capacity a magnet with large changes in net magnetization vs temperature at constant magnetic fieldThe adiabatic change in temperature D T a d displaystyle Delta T ad nbsp can be seen to be related to the magnet s change in magnetic entropy D S displaystyle Delta S nbsp since 9 D S T H 0 H 1 M T H T d H displaystyle Delta S T int H 0 H 1 left frac partial M T H partial T right dH nbsp This implies that the absolute change in the magnet s entropy determines the possible magnitude of the adiabatic temperature change under a thermodynamic cycle of magnetic field variation T Thermodynamic cycle edit nbsp Analogy between magnetic refrigeration and vapor cycle or conventional refrigeration H externally applied magnetic field Q heat quantity P pressure DTad adiabatic temperature variationThe cycle is performed as a refrigeration cycle that is analogous to the Carnot refrigeration cycle but with increases and decreases in magnetic field strength instead of increases and decreases in pressure It can be described at a starting point whereby the chosen working substance is introduced into a magnetic field i e the magnetic flux density is increased The working material is the refrigerant and starts in thermal equilibrium with the refrigerated environment Adiabatic magnetization A magnetocaloric substance is placed in an insulated environment The increasing external magnetic field H causes the magnetic dipoles of the atoms to align thereby decreasing the material s magnetic entropy and heat capacity Since overall energy is not lost yet and therefore total entropy is not reduced according to thermodynamic laws the net result is that the substance is heated T DTad Isomagnetic enthalpic transfer This added heat can then be removed Q by a fluid or gas gaseous or liquid helium for example The magnetic field is held constant to prevent the dipoles from reabsorbing the heat Once sufficiently cooled the magnetocaloric substance and the coolant are separated H 0 Adiabatic demagnetization The substance is returned to another adiabatic insulated condition so the total entropy remains constant However this time the magnetic field is decreased the thermal energy causes the magnetic moments to overcome the field and thus the sample cools i e an adiabatic temperature change Energy and entropy transfers from thermal entropy to magnetic entropy measuring the disorder of the magnetic dipoles 10 Isomagnetic entropic transfer The magnetic field is held constant to prevent the material from reheating The material is placed in thermal contact with the environment to be refrigerated Because the working material is cooler than the refrigerated environment by design heat energy migrates into the working material Q Once the refrigerant and refrigerated environment are in thermal equilibrium the cycle can restart Applied technique edit The basic operating principle of an adiabatic demagnetization refrigerator ADR is the use of a strong magnetic field to control the entropy of a sample of material often called the refrigerant Magnetic field constrains the orientation of magnetic dipoles in the refrigerant The stronger the magnetic field the more aligned the dipoles are corresponding to lower entropy and heat capacity because the material has effectively lost some of its internal degrees of freedom If the refrigerant is kept at a constant temperature through thermal contact with a heat sink usually liquid helium while the magnetic field is switched on the refrigerant must lose some energy because it is equilibrated with the heat sink When the magnetic field is subsequently switched off the heat capacity of the refrigerant rises again because the degrees of freedom associated with orientation of the dipoles are once again liberated pulling their share of equipartitioned energy from the motion of the molecules thereby lowering the overall temperature of a system with decreased energy Since the system is now insulated when the magnetic field is switched off the process is adiabatic i e the system can no longer exchange energy with its surroundings the heat sink and its temperature decreases below its initial value that of the heat sink The operation of a standard ADR proceeds roughly as follows First a strong magnetic field is applied to the refrigerant forcing its various magnetic dipoles to align and putting these degrees of freedom of the refrigerant into a state of lowered entropy The heat sink then absorbs the heat released by the refrigerant due to its loss of entropy Thermal contact with the heat sink is then broken so that the system is insulated and the magnetic field is switched off increasing the heat capacity of the refrigerant thus decreasing its temperature below the temperature of the heat sink In practice the magnetic field is decreased slowly in order to provide continuous cooling and keep the sample at an approximately constant low temperature Once the field falls to zero or to some low limiting value determined by the properties of the refrigerant the cooling power of the ADR vanishes and heat leaks will cause the refrigerant to warm up Working materials editThe magnetocaloric effect MCE is an intrinsic property of a magnetic solid This thermal response of a solid to the application or removal of magnetic fields is maximized when the solid is near its magnetic ordering temperature Thus the materials considered for magnetic refrigeration devices should be magnetic materials with a magnetic phase transition temperature near the temperature region of interest 11 For refrigerators that could be used in the home this temperature is room temperature The temperature change can be further increased when the order parameter of the phase transition changes strongly within the temperature range of interest 2 The magnitudes of the magnetic entropy and the adiabatic temperature changes are strongly dependent upon the magnetic ordering process The magnitude is generally small in antiferromagnets ferrimagnets and spin glass systems but can be much larger for ferromagnets that undergo a magnetic phase transition First order phase transitions are characterized by a discontinuity in the magnetization changes with temperature resulting in a latent heat 11 Second order phase transitions do not have this latent heat associated with the phase transition 11 In the late 1990s Pecharksy and Gschneidner reported a magnetic entropy change in Gd5 Si2 Ge2 that was about 50 larger than that reported for Gd metal which had the largest known magnetic entropy change at the time 12 This giant magnetocaloric effect GMCE occurred at 270 K which is lower than that of Gd 294 K 4 Since the MCE occurs below room temperature these materials would not be suitable for refrigerators operating at room temperature 13 Since then other alloys have also demonstrated the giant magnetocaloric effect These include Gd5 Six Ge1 x 4 La Fex Si1 x 13 Hx and MnFeP1 x Asx alloys 11 13 Gadolinium and its alloys undergo second order phase transitions that have no magnetic or thermal hysteresis 14 However the use of rare earth elements makes these materials very expensive Current research has been used to describe alloys with a significant magnetocaloric effect in terms of a thermodynamic system Literature says that Gd5 Si2Ge2 for example may be described as a thermodynamic system provided it satisfies the condition of being a quantity of matter or region in space chosen for study 15 Such systems have become relevant to modern research in thermodynamics because they serve as plausible materials for the creation of high performance thermoelectric materials Ni2 Mn X X Ga Co In Al Sb Heusler alloys are also promising candidates for magnetic cooling applications because they have Curie temperatures near room temperature and depending on composition can have martensitic phase transformations near room temperature 3 These materials exhibit the magnetic shape memory effect and can also be used as actuators energy harvesting devices and sensors 16 When the martensitic transformation temperature and the Curie temperature are the same based on composition the magnitude of the magnetic entropy change is the largest 2 In February 2014 GE announced the development of a functional Ni Mn based magnetic refrigerator 17 18 The development of this technology is very material dependent and will likely not replace vapor compression refrigeration without significantly improved materials that are cheap abundant and exhibit much larger magnetocaloric effects over a larger range of temperatures Such materials need to show significant temperature changes under a field of two tesla or less so that permanent magnets can be used for the production of the magnetic field 19 20 Paramagnetic salts edit The original proposed refrigerant was a paramagnetic salt such as cerium magnesium nitrate The active magnetic dipoles in this case are those of the electron shells of the paramagnetic atoms In a paramagnetic salt ADR the heat sink is usually provided by a pumped 4 He about 1 2 K or 3 He about 0 3 K cryostat An easily attainable 1 T magnetic field is generally required for initial magnetization The minimum temperature attainable is determined by the self magnetization tendencies of the refrigerant salt but temperatures from 1 to 100 mK are accessible Dilution refrigerators had for many years supplanted paramagnetic salt ADRs but interest in space based and simple to use lab ADRs has remained due to the complexity and unreliability of the dilution refrigerator At a low enough temperature paramagnetic salts become either diamagnetic or ferromagnetic limiting the lowest temperature that can be reached using this method citation needed Nuclear demagnetization edit One variant of adiabatic demagnetization that continues to find substantial research application is nuclear demagnetization refrigeration NDR NDR follows the same principles but in this case the cooling power arises from the magnetic dipoles of the nuclei of the refrigerant atoms rather than their electron configurations Since these dipoles are of much smaller magnitude they are less prone to self alignment and have lower intrinsic minimum fields This allows NDR to cool the nuclear spin system to very low temperatures often 1 µK or below Unfortunately the small magnitudes of nuclear magnetic dipoles also makes them less inclined to align to external fields Magnetic fields of 3 teslas or greater are often needed for the initial magnetization step of NDR In NDR systems the initial heat sink must sit at very low temperatures 10 100 mK This precooling is often provided by the mixing chamber of a dilution refrigerator 21 or a paramagnetic salt Commercial development editResearch and a demonstration proof of concept device in 2001 succeeded in applying commercial grade materials and permanent magnets at room temperatures to construct a magnetocaloric refrigerator 22 On August 20 2007 the Riso National Laboratory Denmark at the Technical University of Denmark claimed to have reached a milestone in their magnetic cooling research when they reported a temperature span of 8 7 K 23 They hoped to introduce the first commercial applications of the technology by 2010 As of 2013 this technology had proven commercially viable only for ultra low temperature cryogenic applications available for decades Magnetocaloric refrigeration systems are composed of pumps motors secondary fluids heat exchangers of different types magnets and magnetic materials These processes are greatly affected by irreversibilities and should be adequately considered At year end Cooltech Applications 24 announced that its first commercial refrigeration equipment would enter the market in 2014 Cooltech Applications launched their first commercially available magnetic refrigeration system on 20 June 2016 At the 2015 Consumer Electronics Show in Las Vegas a consortium of Haier Astronautics Corporation of America and BASF presented the first cooling appliance 25 BASF claim of their technology a 35 improvement over using compressors 26 In November 2015 at the Medica 2015 fair 27 Cooltech Applications presented in collaboration with Kirsch medical GmbH the world s first magnetocaloric medical cabinet 28 One year later in September 2016 at the 7th International Conference on Magnetic Refrigeration at Room Temperature Thermag VII held in Torino Italy Cooltech Applications presented the world s first magnetocaloric frozen heat exchanger 29 In 2017 Cooltech Applications presented a fully functional 500 liters magnetocaloric cooled cabinet with a 30 kg load and an air temperature inside the cabinet of 2 C That proved that magnetic refrigeration is a mature technology capable of replacing the classic refrigeration solutions 30 One year later in September 2018 at the 8th International Conference on Magnetic Refrigeration at Room Temperature Thermag VIII Cooltech Applications presented a paper on a magnetocaloric prototype designed as a 15 kW proof of concept unit 31 This has been considered by the community as the largest magnetocaloric prototype ever created 32 At the same conference it has been announced that due to financial issues Cooltech Applications declared bankruptcy 33 Later on in 2019 Ubiblue company today named Magnoric is formed by some of the old Cooltech Application s team members The entire patent portfolio form Cooltech Applications was taken over by Magnoric since then while publishing additional patents at the same time In 2019 at the 5th Delft Days Conference on Magnetocalorics Ubiblue presented their last prototype 34 Later the magnetocaloric community acknowledged that Ubiblue had the most developed magnetocalorics prototypes 35 Thermal and magnetic hysteresis problems remain to be solved for first order phase transition materials that exhibit the GMCE 19 One potential application is in spacecraft Vapor compression refrigeration units typically achieve performance coefficients of 60 of that of a theoretical ideal Carnot cycle much higher than current MR technology Small domestic refrigerators are however much less efficient 36 In 2014 giant anisotropic behaviour of the magnetocaloric effect was found in HoMn2 O5 at 10 K The anisotropy of the magnetic entropy change gives rise to a large rotating MCE offering the possibility to build simplified compact and efficient magnetic cooling systems by rotating it in a constant magnetic field 37 In 2015 Aprea et al 38 presented a new refrigeration concept GeoThermag which is a combination of magnetic refrigeration technology with that of low temperature geothermal energy To demonstrate the applicability of the GeoThermag technology they developed a pilot system that consists of a 100 m deep geothermal probe inside the probe water flows and is used directly as a regenerating fluid for a magnetic refrigerator operating with gadolinium The GeoThermag system showed the ability to produce cold water even at 281 8 K in the presence of a heat load of 60 W In addition the system has shown the existence of an optimal frequency f AMR 0 26 Hz for which it was possible to produce cold water at 287 9 K with a thermal load equal to 190 W with a COP of 2 20 Observing the temperature of the cold water that was obtained in the tests the GeoThermag system showed a good ability to feed the cooling radiant floors and a reduced capacity for feeding the fan coil systems History editThe effect was discovered first observed by German physicist Emil Warburg in 1881 39 Subsequently by French physicist Pierre Weiss and Swiss physicist Auguste Piccard in 1917 5 Major advances first appeared in the late 1920s when cooling via adiabatic demagnetization was independently proposed by Peter Debye in 1926 and chemistry Nobel Laureate William F Giauque in 1927 It was first demonstrated experimentally by Giauque and his colleague D P MacDougall in 1933 for cryogenic purposes when they reached 0 25 K 40 Between 1933 and 1997 advances in MCE cooling occurred 41 In 1997 the first near room temperature proof of concept magnetic refrigerator was demonstrated by Karl A Gschneidner Jr by the Iowa State University at Ames Laboratory This event attracted interest from scientists and companies worldwide who started developing new kinds of room temperature materials and magnetic refrigerator designs 7 A major breakthrough came 2002 when a group at the University of Amsterdam demonstrated the giant magnetocaloric effect in MnFe P As alloys that are based on abundant materials 42 Refrigerators based on the magnetocaloric effect have been demonstrated in laboratories using magnetic fields starting at 0 6 T up to 10 T Magnetic fields above 2 T are difficult to produce with permanent magnets and are produced by a superconducting magnet 1 T is about 20 000 times the Earth s magnetic field Room temperature devices edit Recent research has focused on near room temperature Constructed examples of room temperature magnetic refrigerators include Room temperature magnetic refrigerators Sponsor Location Announcement date Type Max cooling power W 1 Max DT K 2 Magnetic field T Solid refrigerant Quantity kg COP 3 Ames Laboratory Astronautics 43 Ames Iowa Madison Wisconsin US February 20 1997 Reciprocating 600 10 5 S Gd spheresMater Science Institute Barcelona 44 45 Barcelona Spain May 2000 Rotary 5 0 95 P Gd foilChubu Electric Toshiba 46 Yokohama Japan Summer 2000 Reciprocating 100 21 4 S Gd spheresUniversity of Victoria 47 48 Victoria British Columbia Canada July 2001 Reciprocating 2 14 2 S Gd amp Gd1 x Tbx L B Astronautics 49 Madison Wisconsin US September 18 2001 Rotary 95 25 1 5 P Gd spheresSichuan Inst Tech Nanjing University 50 Nanjing China 23 April 2002 Reciprocating 23 1 4 P Gd spheres and Gd5Si1 985Ge1 985Ga0 03 powderChubu Electric Toshiba 51 Yokohama Japan October 5 2002 Reciprocating 40 27 0 6 P Gd1 x Dyx L B Chubu Electric Toshiba 51 Yokohama Japan March 4 2003 Rotary 60 10 0 76 P Gd1 x Dyx L B 1Lab d Electrotechnique Grenoble 52 Grenoble France April 2003 Reciprocating 8 8 4 0 8 P Gd foilGeorge Washington University 53 US July 2004 Reciprocating 5 2 P Gd foilAstronautics 54 Madison Wisconsin US 2004 Rotary 95 25 1 5 P Gd and GdEr spheres La Fe0 88 Si130 0 12 H1 0University of Victoria 55 Victoria British Columbia Canada 2006 Reciprocating 15 50 2 S Gd Gd0 74 Tb0 26 and Gd0 85 Er0 15 pucks 0 12University of Salerno 56 Salerno Italy 2016 Rotary 250 12 1 2 P Gd 0 600 mm spherical particles 1 20 0 5 2 5MISiS 57 Tver and Moscow Russia 2019 High speed rotary Gd bricks of two types cascaded1maximum cooling power at zero temperature difference DT 0 2maximum temperature span at zero cooling capacity W 0 L B layered bed P permanent magnet S superconducting magnet 3 COP values under different operating conditionsIn one example Prof Karl A Gschneidner Jr unveiled a proof of concept magnetic refrigerator near room temperature on February 20 1997 He also announced the discovery of the GMCE in Gd5 Si2 Ge2 on June 9 1997 12 Since then hundreds of peer reviewed articles have been written describing materials exhibiting magnetocaloric effects See also editCoefficient of performance COP Cryostat Curie s law Dilution refrigerator Electrocaloric effect Thermoacoustic refrigerationReferences edit Franca E L T dos Santos A O Coelho A A 2016 Magnetocaloric effect of the ternary Dy Ho and Er platinum gallides Journal of Magnetism and Magnetic Materials 401 1088 1092 Bibcode 2016JMMM 401 1088F doi 10 1016 j jmmm 2015 10 138 a b c Bruck E 2005 Developments in magnetocaloric refrigeration Journal of Physics D Applied Physics 38 23 R381 R391 Bibcode 2005JPhD 38R 381B doi 10 1088 0022 3727 38 23 R01 S2CID 122788079 a b Khovaylo V V Rodionova V V Shevyrtalov S N Novosad V 2014 Magnetocaloric effect in reduced dimensions Thin films ribbons and microwires of Heusler alloys and related compounds Physica Status Solidi B 251 10 2104 Bibcode 2014PSSBR 251 2104K doi 10 1002 pssb 201451217 S2CID 196706851 a b Gschneidner K A Pecharsky V K 2008 Thirty years of near room temperature magnetic cooling 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sup gt e lt sup gt conference internationale sur le froid magnetique a 6052 World s No 1 Retail Trade Fair https www sciencedirect com science article abs pii S0140700720303911 https onlinelibrary wiley com doi full 10 1002 aenm 201903741 largest magnetocaloric prototype Dr Sergiu Lionte s speech at Thermag VIII conference as invited speaker DDMC 2019 TU Delft in Dutch Retrieved 2021 11 07 Kitanovski Andrej 2020 Energy Applications of Magnetocaloric Materials Advanced Energy Materials 10 10 doi 10 1002 aenm 201903741 Sand J R Vineyard E A Bohman R H 2012 08 31 Information Bridge DOE Scientific and Technical Information Sponsored by OSTI PDF Osti gov Retrieved 2012 10 04 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Balli M Jandl S Fournier P Gospodinov M M 2014 Anisotropy enhanced giant reversible rotating magnetocaloric effect in HoMn2O5 single crystals PDF Applied Physics Letters 104 6868 232402 1 to 5 Bibcode 2014ApPhL 104w2402B doi 10 1063 1 4880818 Aprea C Greco A Maiorino A GeoThermag A geothermal magnetic refrigerator 2015 International Journal of Refrigeration 59 pp 75 83 Warburg E G 1881 Magnetische Untersuchungen Annalen der Physik 249 5 141 164 Bibcode 1881AnP 249 141W doi 10 1002 andp 18812490510 Giauque W F MacDougall D P 1933 Attainment of Temperatures Below 1 Absolute by Demagnetization of Gd2 SO4 3 8H2O Phys Rev 43 9 768 Bibcode 1933PhRv 43 768G doi 10 1103 PhysRev 43 768 Gschneidner K A Jr Pecharsky V K 1997 Bautista R G et al eds Rare Earths Science Technology and Applications III Warrendale PA The Minerals Metals and Materials Society p 209 Pecharsky V K Gschneidner K A Jr 1999 Magnetocaloric Effect and Magnetic Refrigeration J Magn Magn Mater 200 1 3 44 56 Bibcode 1999JMMM 200 44P doi 10 1016 S0304 8853 99 00397 2 Gschneidner K A Jr Pecharsky V K 2000 Magnetocaloric Materials Annu Rev Mater Sci 30 1 387 429 Bibcode 2000AnRMS 30 387G doi 10 1146 annurev matsci 30 1 387 Gschneidner K A Jr Pecharsky V K 2002 Chandra D Bautista R G eds Fundamentals of Advanced Materials for Energy Conversion Warrendale PA The Minerals Metals and Materials Society p 9 Tegus O Bruck E de Boer F R Buschow K H J 2002 Transition metal based magnetic refrigerants for room temperature applications Nature 415 6868 150 152 Bibcode 2002Natur 415 150T doi 10 1038 415150a PMID 11805828 S2CID 52855399 Zimm C Jastrab A Sternberg A Pecharsky V K Gschneidner K A Jr Osborne M Anderson I 1998 Description and Performance of a Near Room Temperature Magnetic Refrigerator Advances in Cryogenic Engineering p 1759 doi 10 1007 978 1 4757 9047 4 222 ISBN 978 1 4757 9049 8 a href Template Cite book html title Template Cite book cite book a journal ignored help Bohigas X Molins E Roig A Tejada J Zhang X X 2000 Room temperature magnetic refrigerator using permanent magnets IEEE Transactions on Magnetics 36 3 538 Bibcode 2000ITM 36 538B doi 10 1109 20 846216 Lee S J Kenkel J M Pecharsky V K Jiles D C 2002 Permanent magnet array for the magnetic refrigerator Journal of Applied Physics 91 10 8894 Bibcode 2002JAP 91 8894L doi 10 1063 1 1451906 Hirano N 2002 Development of magnetic refrigerator for room temperature application AIP Conference Proceedings Vol 613 pp 1027 1034 doi 10 1063 1 1472125 Rowe A M and Barclay J A Adv Cryog Eng 47 995 2002 Richard M A 2004 Magnetic refrigeration Single and multimaterial active magnetic regenerator experiments Journal of Applied Physics 95 4 2146 2150 Bibcode 2004JAP 95 2146R doi 10 1063 1 1643200 S2CID 122081896 Zimm C Paper No K7 003 Am Phys Soc Meeting March 4 Austin Texas 2003 Archived copy Archived from the original on 2004 02 29 Retrieved 2006 06 12 a href Template Cite web html title Template Cite web cite web a CS1 maint archived copy as title link Wu W Paper No K7 004 Am Phys Soc Meeting March 4 Austin Texas 2003 Archived copy Archived from the original on 2004 02 29 Retrieved 2006 06 12 a href Template Cite web html title Template Cite web cite web a CS1 maint archived copy as title link a b Hirano N Paper No K7 002 Am Phys Soc Meeting March 4 Austin Texas Archived copy Archived from the original on 2004 02 29 Retrieved 2006 06 12 a href Template Cite web html title Template Cite web cite web a CS1 maint archived copy as title link Clot P Viallet D Allab F Kedous Lebouc A Fournier J M Yonnet J P 2003 A magnet based device for active magnetic regenerative refrigeration IEEE Transactions on Magnetics 39 5 3349 Bibcode 2003ITM 39 3349C doi 10 1109 TMAG 2003 816253 Shir F Mavriplis C Bennett L H Torre E D 2005 Analysis of room temperature magnetic regenerative refrigeration International Journal of Refrigeration 28 4 616 doi 10 1016 j ijrefrig 2004 08 015 Zimm C Paper No K7 003 Am Phys Soc Meeting March 4 Austin Texas 2003 Archived copy Archived from the original on 2004 02 29 Retrieved 2006 06 12 a href Template Cite web html title Template Cite web cite web a CS1 maint archived copy as title link Rowe A Tura A 2006 Experimental investigation of a three material layered active magnetic regenerator International Journal of Refrigeration 29 8 1286 doi 10 1016 j ijrefrig 2006 07 012 Aprea C Greco A Maiorino A Masselli C 2016 The energy performances of a rotary permanent magnet magnetic refrigerator International Journal of Refrigeration 61 1 1 11 doi 10 1016 j ijrefrig 2015 09 005 Rossijskie inzhenery sozdali vysokoeffektivnyj magnitnyj holodilnik Further reading editLounasmaa Experimental Principles and Methods Below 1 K Academic Press 1974 Richardson and Smith Experimental Techniques in Condensed Matter Physics at Low Temperatures Addison Wesley 1988 Lucia U 2008 General approach to obtain the magnetic refrigeration ideal Coefficient of Performance COP Physica A Statistical Mechanics and Its Applications 387 14 3477 3479 arXiv 1011 1684 Bibcode 2008PhyA 387 3477L doi 10 1016 j physa 2008 02 026 Bouhani H 2020 Engineering the magnetocaloric properties of PrVO3 epitaxial oxide thin films by strain effects Applied Physics Letters 117 7 072402 arXiv 2008 09193 Bibcode 2020ApPhL 117g2402B doi 10 1063 5 0021031 S2CID 225378969 de Souza M 2021 Elastocaloric effect induced adiabatic magnetization in paramagnetic salts due to the mutual interactions Scientific Reports 11 9461 9431 Bibcode 2021NatSR 11 9431S doi 10 1038 s41598 021 88778 4 PMC 8093207 PMID 33941810 External links editCooling by adiabatic demagnetization The Feynman Lectures on Physics What is magnetocaloric effect and what materials exhibit this effect the most Ames Laboratory news release May 25 1999 Work begins on prototype magnetic refrigeration unit Refrigeration Systems Terry Heppenstall s notes University of Newcastle upon Tyne November 2000 XRS Adiabatic Demagnetization Refrigerator Executive Summary A Continuous Adiabatic Demagnetization Refrigerator doc format Google cache Origin and tuning of the magnetocaloric effect in the magnetic refrigerant Mn1 1Fe0 9 P0 8Ge0 2 1 Magnetic technology revolutionizes refrigeration Evaluation of thermodynamic quantities in magnetic refrigeration Retrieved from https en wikipedia org w index php title Magnetic refrigeration amp oldid 1181796299, wikipedia, wiki, book, books, library,

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