Electrostatic Levitation Lab

Iowa State University Department of Physics and Astronomy

Published Work

1.

N. A. Mauro, A. J. Vogt, K. S. Derendorf, M. L. Johnson, G. E. Rustan, D. G. Quirinale, A. Kreyssig, K. A. Lokshin, J. C. Neuefeind, Ke An, Xun-Li Wang, A. I. Goldman, T. Egami, and K. F. Kelton, “Electrostatic levitation facility optimized for neutron diffraction studies of high temperature liquids at a spallation neutron source,” Review of Scientific Instruments 87, 013904 (2016).

2.

M. L. Johnson, M. E. Blodgett, K. A. Lokshin, N. A. Mauro, J. Neuefeind, C. Pueblo, D. G. Quirinale, A. J. Vogt,T. Egami, A. I. Goldman, and K. F. Kelton, “Measurements of structural and chemical order in Zr80Pt20 and Zr77Rh23 liquids,” Physical Review B 93, 054203 (2016).

3.

D. G. Quirinale, G. E. Rustan, A. Kreyssig, and A. I. Goldman, “Synergistic stabilization of metastable Fe23B6 and ?-Fe in undercooled Fe83B17,” Applied Physics Letters 106, 241906 (2015).

4.

D. G. Quirinale, G. E. Rustan, S. R. Wilson, M. J. Kramer, A. I. Goldman, and M. I. Mendelev, “Appearance of metastable B2 phase during solidification of Ni50Zr50 alloy: electrostatic levitation and molecular dynamics simulation studies,” J. Phys: Condens. Matter 27, 085004 (2015).

5.

G. E. Rustan, N. S. Spyrison, A. Kreyssig, R. Prozorov and A. I. Goldman, Noncontact technique for measuring the electrical resistivity and magnetic susceptibility of electrostatically levitated materials,” Rev. Sci. Instrum. 83, 103907 (2012).

6.

N. A. Mauro, V. Wessels, J. C. Bendert, S. Klein, A. K. Gangopadhyay, M. J. Kramer, S. G. Hao, G. E. Rustan, A. Kreyssig, A. I. Goldman, and K. F. Kelton, “Short and medium-range order in Zr80Pt20 liquids,” Phys. Rev. B 83, 184109 (2011).

7.

V. Wessels, A. K. Gangopadhyay, K. K. Sahu, R. W. Hyers, S. M. Canepari, J. R. Rogers, M. J. Kramer, A. I. Goldman, D. Robinson, J. W. Lee, J. R. Morris, and K. F. Kelton, “Rapid chemical and topological ordering in supercooled liquid Cu46Zr54,” Phys. Rev. B 83, 094116 (2011).

8.

M.I. Mendelev, M.J. Kramer, R.T. Ott, D.J. Sordelet, M.F. Besser, A. Kreyssig, A.I. Goldman, V. Wessels, K.K. Sahu, K.F. Kelton, R.W. Hyers, S. Canepari, and J.R. Rogers, "Experimental and computer simulation determination of the structural changes occurring through the liquid-glass transition in Cu-Zr alloys," Philosophical Magazine, Vol. 90, Iss. 29 (2010).

9.

S. G. Hao, M. J. Kramer, C. Z. Wang, K.M. Ho, S. Nandi, A. Kreyssig, A.I. Goldman, V. Wessels, K. K. Sahu, K. F. Kelton, R. W. Hyers, S. M. Canepari, andJ. R. Rogers, “Experimental and ab initio structural studies of liquid Zr2Ni,” Phys. Rev. B 79, 104206 (2009).

10.

G. W. Lee, A. K. Gangopadhyay, R. W. Hyers, T. J. Rathz, J. R. Rogers, D. S. Robinson, A. I. Goldman, and K. F. Kelton, “Local structure of equilibrium and supercooled Ti-Zr-Ni liquids,” Phys. Rev. B 77, 184102 (2008).

11.

T. H. Kim, A. I. Goldman, and K. F. Kelton, "Structural study of supercooled liquid silicon," Philosophical Magazine, Vol. 88, Iss. 2, (2008).

12.

T. H. Kim, G. W. Lee, A. K. Gangopadhyay, R. W. Hyers, J. R. Rogers, A. I. Goldman, and K. F. Kelton, “Structural studies of a Ti–Zr–Ni quasicrystal-forming liquid,” J. Phys.: Condens. Matter 19, 455212 (2007).

13.

T. H. Kim, A. K. Gangopadhyay, L. Q. Xing, G. W. Lee, Y. T. Shen, K. F. Kelton, A. I. Goldman, R. W. Hyers, and J. R. Rogers, “Role of Ti in the formation of Zr–Ti–Cu–Ni–Al glasses,” Appl. Phys. Lett. 87, 251924 (2005).

14.

T. H. Kim, G. W. Lee, B. Sieve, A. K. Gangopadhyay, R. W. Hyers, T. J. Rathz, J. R. Rogers, D. S. Robinson, K. F. Kelton, and A. I. Goldman, “In situ High-Energy X-Ray Diffraction Study of the Local Structure of Supercooled Liquid Si,” Phys. Rev. Lett. 96, 085501 (2005).

15.

A. K. Gangopadhyay, G. W. Lee, K. F. Kelton, J. R. Rogers, A. I. Goldman, D. S. Robinson, T. J. Rathz and R. W. Hyers, “Beamline electrostatic levitator for in situ high energy x-ray diffraction studies of levitated solids and liquids,” Rev. Sci. Instrum. 76, 073901 (2005).