Low Temperature Vibrating Sample Magnetometr Cryogenic Limited (CRYOGENIC)

Profilová karta (PDF)

Detailed description:

This cryogen-free magnet system (CRYOGENIC), suitable for measuring both electrical and magnetic properties of samples, allows the experimenter to achieve low temperatures 1.6K up to 400K while applying magnetic fields up to 9T to their samples.

The Cryogen-Free High Field Measurement System combines the latest cryogen-free technology with sophisticated measurement techniques providing a versatile, powerful investigative device achieving low temperatures and high magnetic fields without the use of liquid helium or nitrogen. The cryocooler provides the cooling to both the magnet and the variable temperature insert (VTI).

Available for these field and temperature ranges are the following measurement options:
· DCR (direct current resistivity)
· VSM (vibrating sample magnetometry)
· ACS (alternative current susceptibility)

Publications:

• Mohelský, I., 2020: Infrared magneto–spectroscopy of Bi2Te3 topological insulator. MASTER´S THESIS , p. 1 - 49
  (FTIR, WOOLLAM-MIR, MAGNETRON, CRYOGENIC, KRATOS-XPS)
• RAMAZANOV, S.; SOBOLA, D.; ORUDZHEV, F.; KNÁPEK, A.; POLČÁK, J.; POTOČEK, M.; KASPAR, P.; DALLAEV, R., 2020: Surface Modification and Enhancement of Ferromagnetism in BiFeO3 Nanofilms Deposited on HOPG. NANOMATERIALS 10(10), p. 1990-1 - 17, doi: 10.3390/nano10101990; FULL TEXT
  (HELIOS, SIMS, KRATOS-XPS, CRYOGENIC)
• Hajduček, J., 2019: Substrate-controlled nucleation of the magnetic phase transtition in nanostructures. BACHELOR´S THESIS , p. 1 - 46
  (MAGNETRON, ICON-SPM, CRYOGENIC, MIRA, RIE-FLUORINE, EVAPORATOR, VERSALAB)
• Rienks, EDL.; Wimmer, S.; Sanchez-Barriga, J.; Caha, O.; Mandal, PS.; Ruzicka, J.; Ney, A.; Steiner, H. ; Albu, M.; Kothleitner, G.; Michalicka, J. ; Khan, SA.; Minar, J.; Ebert, H.; Bauer, G. ; Freyse, F.; Varykhalov, A.; Rader, O. Springholz, G. , 2019: Large magnetic gap at the Dirac point in Bi2Te3/MnBi2Te4 heterostructures. NATURE 576(7787), p. 423 - 19, doi: 10.1038/s41586-019-1826-7; FULL TEXT
  (CRYOGENIC, TITAN, HELIOS, RIGAKU9)
• Jaskowiec, J., 2019: Spatial confinement effects in metamagnetic nanostructures. MASTER´S THESIS , p. 1 - 55
  (MAGNETRON, MIRA, RAITH, ICON-SPM, CRYOGENIC, VERSALAB)

• Friš, P.; Munzar, D.; Caha, O.; Dubroka, A., 2018: Direct observation of double exchange in ferromagnetic La0.7Sr0.3CoO3 by broadband ellipsometry. PHYSICAL REVIEW B 97(4), p. 045137-1 - 045137-5, doi: 10.1103/PhysRevB.97.045137
  (WOOLLAM-MIR, WOOLLAM-VIS, RIGAKU9, FTIR, CRYOGENIC)
• Motyčková, L., 2018: Epitaxial growth and characterization of metamagnetic nanoparticles for biomedical applications. BACHELOR´S THESIS , p. 1 - 55
  (MAGNETRON, ICON-SPM, LYRA, CRYOGENIC)
• Kukolova, A., 2017: Experimental study of electronic properties of manganites and electron stimulated desorption. MASTER´S THESIS , p. 1 - 91
  (WOOLLAM-MIR, WOOLLAM-VIS, CRYOGENIC)
• Jaskowiec, J., 2017: Magnetic Force Microscopy and Transport Properties of Metamagnetic Nanostructures. BACHELOR´S THESIS , p. 1 - 47
  (MAGNETRON, MIRA, RAITH, ICON-SPM, CRYOGENIC, LYRA)
• Holobrádek, J., 2017: Transport Properties of One Magnetic Nanostructures. BACHELOR´S THESIS , p. 1 - 48
  (TITAN, ICON-SPM, MIRA, EVAPORATOR, WIRE-BONDER, CRYOGENIC)

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