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17. Urbain G, Weiss P, Trombe F (1935) Un nouveau m
é
tal ferromagn
é
tique, le gadolinium.
Comptes Rendus 200:2132
-
2134
18. Marsh J (1963) MSc. Disertation, West Virginia University
19. Silars MP (1965) MSc. Disertation, West Virginia University
20. Brown GV (1976) Magnetic heat pumping near room temperature. J Appl Phys 47:3673
-
3680
21. Barclay JA, Steyert WA (1982) Active magnetic regenerator. US Patent 4.332.135 A
22. Pecharsky VK, Gschneidner KA Jr (1997) Giant magnetocaloric effect in Gd
5
(Si
2
Ge
2
). Phys
Rev Lett 78:4494
4497
23. Gschneidner KA Jr, Pecharsky VK, Tsokol AO (2005) Recent developments
-
in
1539
24. Shen BG, Sun JR, Hu FX et al (2009) Recent progress in exploring magnetocaloric materials.
Adv Mater 21:4545
magnetocaloric materials. Rep Prog Phys 68:1479
-
4564
-
25. Br
ck E, Tegus O, Cam Thanh DT et al (2008) A review on Mn based materials for magnetic
refrigeration: structure and properties. Int J Refrig 31:763
ü
770
26. Phan MH, Yu SC (2007) Review of the magnetocaloric effect in manganite materials. J Magn
Magn Mater 308:325
-
340
27. Gutfleisch O, Willard MA, Br
ü
ck E et al (2010) Magnetic materials and devices for the 21st
century: stronger, lighter, and more energy ef
cient. Adv Mater 23(7):821
-
842
28. Sandeman KG (2012) Magnetocaloric materials: the search for new systems. Scripta Mater 67
(6):566
-
571
29. Tishin AM, Spichkin YI (2003) The magnetocaloric effect and its applications. Institute of
Physics Publishing, Philadelphia
30. Smith A, Bahl CRH, Bj
-
rk R et al (2012) Materials challenges for high performance
magnetocaloric refrigeration devices. Adv Energy Mater 2:1288
ø
1318
31. Yu B, Gao Q, Zhang B et al (2003) Review on research of room temperature magnetic
refrigeration. Int J Refrig 26:622
-
636
32. Engelbrecht K, Bahl CRH (2010) Evaluating the effect of magnetocaloric properties on
magnetic refrigeration performance. J Appl Phys 108:123918
33. Basso V, Sasso CP, Bertotti G et al (2006) Effect of material hysteresis in magnetic
refrigeration cycles. Int J Refrig 29:1358
-
1365
34. Engelbrecht K, Nielsen KK, Bahl CRH et al (2013) Material properties and modeling
characteristics for MnFeP
1
−
x
As
x
materials for application in magnetic refrigeration. J Appl
Phys 113(17):173510
35. von Moos L, Nielsen KK, Engelbrecht K et al (2014) Experimental investigation of the effect
of thermal hysteresis in
rst order material MnFe(P, As) applied in an AMR device. Int J
Refrig 37(1):303
-
306
36. Nielsen KK, Engelbrecht K (2012) The influence of the solid thermal conductivity on active
magnetic regenerators. J Phys D Appl Phys 45:145001
37. Fiorillo F (2004) Measurement and characterization of magnetic materials. Elsevier Academic
Press, Amsterdam
38. Bj
-
rk R, Bahl CRH, Katter M (2010) Magnetocaloric properties of LaFe
13-x-y
Co
x
Si
y
and
commercial grade Gd. J Magn Magn Mater 322:3882
ø
3888
-
39. Dan
kov SY, Tishin AM (1998) Magnetic phase transition and the magnetothermal properties
of gadolinium. Phys Rev B 57(6):3478
40. Jayaraman TV, Boone L, Shield JE (2011) Near room temperature magnetic entropy changes
in as-cast Gd
100-x
Mn
x
(x = 0, 5, 10, 15, and 20 at.%) alloys. J Alloy Compd 509:1411
'
1417
41. Jayaraman TV, Boone L, Shield JE (2013) Magnetocaloric effect and refrigerant capacity in
melt-spun Gd-Mn alloys. J Magn Magn Mater 345:153
-
158
42. Pecharsky VK, Gschneidner KA Jr (1999) Magnetocaloric effect and magnetic refrigeration.
J Magn Magn Mater 200:44
-
56
43. Ka
š
til J, Javorsk
ý
P, Kamar
á
d J (2011) Magnetocaloric effect of Gd-Tb alloys: influence of the
sample shape anisotropy. Appl Phys A 104:205
-
209
44. Couillaud S, Gaudin E, Franco V et al (2011) The magnetocaloric properties of GdScSi and
GdScGe. Intermetallics 19:1573
-
1578
-
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