Crystal Growth of High-melting Multi-component Rare Earth-Transition Metal Intermetallic Compounds from the Melt

Behr, G.; Löser, W.; Graw, G.; Bitterlich, H.; Fink, J.; Schultz, L.

doi:10.1002/1521-4079(200004)35:4<461::aid-crat461>3.0.co;2-d

Cited by 23 publications

(18 citation statements)

References 29 publications

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“…Single crystals of RNi 2 [B 2 C] with R ¼ Pr, Tb, Dy, and Ho few mm in size were grown by a cold crucible method using RF-heating [51]. Larger crystals of high quality (low widths of superconducting transition temperature and magnetic ordering temperatures, if applicable) with R ¼ Y, Pr, Tb, Ho and M ¼ Ni were grown by RF-zone melting from polycrystalline materials [38][39][40][52][53][54][55]. This technique was also suitable for crystals of solid solution phases with two different rare-earth metals [56].…”

Section: Borocarbides Rm 2 [B 2 C] and Rm[bc]mentioning

confidence: 99%

See 1 more Smart Citation

Rare-earth metal transition metal borocarbide and nitridoborate superconductors

Niewa¹,

Shlyk²,

Blaschkowski

2011

Zeitschrift Für Kristallographie

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Abstract. Few years after the discovery of superconductivity in high-T c cuprates, borocarbides and shortly after nitridoborates with reasonably high T c s up to about 23 K attracted considerable attention. Particularly for the rareearth metal series with composition RNi 2 [B 2 C] it turned out, that several members exhibit superconductivity next to magnetic order with both T c above or below the magnetic ordering temperature. Therefore, these compounds have been regarded as ideal materials to study the interplay and coexistence of superconductivity and long range magnetic order, due to their comparably high ordering temperatures and similar magnetic and superconducting condensation energies. This review gathers information on the series

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Section: Borocarbides Rm 2 [B 2 C] and Rm[bc]mentioning

confidence: 99%

“…A recent brief review gathers details on the floating zone growth of RNi 2 [B 2 C] compounds [57]. During these investigations pseudobinary sections of some phase diagrams R--Ni--B--C were determined [38,40,41,52] [62,63].…”

Section: Borocarbides Rm 2 [B 2 C] and Rm[bc]mentioning

confidence: 99%

Rare-earth metal transition metal borocarbide and nitridoborate superconductors

Niewa¹,

Shlyk²,

Blaschkowski

2011

Zeitschrift Für Kristallographie

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“…Crystals grown by the Ni 2 B-flux method provide a basis for the determination of several anisotropic physical properties of quaternary RNi 2 B 2 C but suffer from the relatively small size and imperfections arising from the flux (Cho et al, 1995;Rathnayaha et al, 1997). For some of the compounds the FZ methods were applied for the growth of bulk crystals typically 6 mm in diameter and up to 40 mm in length (Takeya, Hirano and Kadowaki, 1996;Takeya, Kadowaki, Mirata and Mirano, 1996;Behr et al, 1999;Behr and Löser, 2005). The TbNi 2 B 2 C compound displays antiferromagnetic ordering below T N = 14 K. The relevant pseudobinary section TbB 2 C 2 -TbNi 2 B 2 C-TbNi 4 B of the quaternary phase diagram with a peritectic temperature of T p = 1518 • C is shown in Figure 30 (Behr et al, 1999).…”

Section: Crystal Growth Activities Of Less-common Magnetic Alloysmentioning

confidence: 99%

Crystal Growth of Magnetic Materials

Behr

Löser

2007

Handbook of Magnetism and Advanced Magnetic Materials

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In this chapter, the various methods for crystal growth of magnetic materials are summarized and principles of choosing the appropriate growth method, which depends on phase diagram features of the alloy system, the required size, physical, and chemical perfection of single crystalline samples, are briefly discussed. The crystal growth of the following classes of materials is considered: soft magnetic pure metals and alloys, highly anisotropic compounds for high‐density magnetic recording media, rare earth–transition metal compounds for high‐performance permanent magnets, high‐magnetostrictive intermetallic compounds and ferromagnetic shape memory alloys for magnetomechanical applications, magnetocaloric materials, selected intermetallic compounds for spintronics, multiferroic materials, and some other less‐common magnetic compounds.

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“…Even exotic phenomena such as magnetically mediated superconductivity in CePd 2 Si 2 are predicted [6]. In recent years single crystals both of RE 2 PdSi 3 [10][11][12][13][14][15] and CeTM 2 Si 2 compounds [16,17] were grown. They provided a basis for elucidating the sizeable anisotropy of the magnetic properties of RE 2 PdSi 3 compounds caused by the delicate balance of crystal-electric field and magnetic exchange interaction [9,10,[13][14][15].…”

Section: Introductionmentioning

confidence: 99%

“…Despite the large interest in crystal structure and physical properties of RE-Pd-Si intermetallic compounds there was a nearly complete lack of phase diagram data. Because of the reactivity of elements and high melting temperatures of the compounds ternary phase diagrams, Tb-Pd-Si [11], and Dy-Pd-Si [12], were studied only very recently in context with crystal growth experiments.…”

Section: Introductionmentioning

confidence: 99%