2010
DOI: 10.1016/j.cryogenics.2010.02.020
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Development of double-stage ADR for future space missions

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Cited by 9 publications
(5 citation statements)
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“…We introduced the AGGHS to the DADR and successfully cooled the detector stage down to 60 mK [1,2]. It is working properly more than a year.…”
Section: Conclusion and Future Prospectsmentioning
confidence: 98%
“…We introduced the AGGHS to the DADR and successfully cooled the detector stage down to 60 mK [1,2]. It is working properly more than a year.…”
Section: Conclusion and Future Prospectsmentioning
confidence: 98%
“…We fabricated a compact He cryostat for this experiment (about 40 cm in diameter and 60 cm in height), following papers [5,6]. We a show photo and a schematic drawing of the cryostat in Fig.…”
Section: Design Of Adrmentioning
confidence: 99%
“…To obtain high resolution, it typically operates at temperatures below 100 mK. The only cryogenic refrigeration technology that can reach such low temperatures under gravity-free conditions is adiabatic demagnetization refrigeration (ADR). This technology relies on the magnetocaloric effect (MCE), i.e., the magnetic entropy or adiabatic temperature of magnetic refrigerants changes in response to the applied magnetic field. Therefore, ADR has been intensively investigated by space administrations in the past three decades, such as NASA/Goddard Space Flight Center, JAXA (Japan), and ESA (Europe). As ADR operates in the temperature range of 100 mK to 4 K and no magnetic refrigerants reported so far exhibit a large magnetic entropy change (−Δ S m ) throughout this temperature range, a cascaded multistage ADR system is adopted to achieve continuous refrigeration. , In the current ADR system, paramagnetic salts are used as magnetic refrigerants below 1 K because they have small −Δ S m at temperatures above 1 K, , while Gd 3 Ga 5 O 12 (GGG) is employed as magnetic refrigerants at 1–4 K. , However, the −Δ S m of GGG, despite being much larger than that of paramagnetic salts, is objectively insufficient, especially under a low magnetic applied field on account of the higher need for the cooling power of recent advances in arraying and multiplexing technologies . Hence, there is an urgent need to seek magnetic refrigerants with large −Δ S m at temperatures of 1–4 K for the increasing requirements.…”
Section: Introductionmentioning
confidence: 99%
“…8−10 As ADR operates in the temperature range of 100 mK to 4 K and no magnetic refrigerants reported so far exhibit a large magnetic entropy change (−ΔS m ) throughout this temperature range, a cascaded multistage ADR system is adopted to achieve continuous refrigeration. 11,12 In the current ADR system, paramagnetic salts are used as magnetic refrigerants below 1 K because they have small −ΔS m at temperatures above 1 K, 13,14 while Gd 3 Ga 5 O 12 (GGG) is employed as magnetic refrigerants at 1−4 K. 15,16 However, the −ΔS m of GGG, despite being much larger than that of paramagnetic salts, is objectively insufficient, especially under a low magnetic applied field on account of the higher need for the cooling power of recent advances in arraying and multiplexing technologies. 17 Hence, there is an urgent need to seek magnetic refrigerants with large −ΔS m at temperatures of 1−4 K for the increasing requirements.…”
Section: ■ Introductionmentioning
confidence: 99%