Biomedical Engineering Reference
In-Depth Information
115. T. Slezak, et al., 'Noncollinear magnetization structure at the thickness-driven
spin-reorientation transition in epitaxial Fe films on W(110),' Phys Rev Lett,
vol. 105, p. 027206, Jul 9 2010.
116. R. Fromter, et al., 'Imaging the cone state of the spin reorientation transition,'
Phys Rev Lett, vol. 100, p. 207202, May 23 2008.
117. J. Choi, et al., 'Magnetic bubble domain phase at the spin reorientation
transition of ultrathin Fe/Ni/Cu(001) film,' Phys Rev Lett, vol. 98, p. 207205,
May 18 2007.
118. K. Y. Wang, et al., 'Spin reorientation transition in single-domain,' Phys Rev
Lett, vol. 95, p. 217204, Nov 18 2005.
119. J. Hong, et al., 'Manipulation of spin reorientation transition by oxygen
surfactant growth: a combined theoretical and experimental approach,' Phys
Rev Lett, vol. 92, p. 147202, Apr 9 2004.
120. L. M. Garcia, et al., 'Orbital magnetic moment instability at the spin
reorientation transition of Nd2Fe14B,' Phys Rev Lett, vol. 85, pp. 429-32, Jul
10 2000.
121. E. Y. Vedmedenko, et al., 'Magnetic microstructure of the spin reorientation
transition: a computer experiment,' Phys Rev Lett, vol. 84, pp. 5884-7, Jun 19
2000.
122. G. Garreau, et al., 'Spin-reorientation transition in ultrathin Tb/Co films,' Phys
Rev B Condens Matter, vol. 53, pp. 1083-6, Jan 15 1996.
123. H. Fritzsche, et al., 'Angular dependence of perpendicular magnetic surface
anisotropy and the spin-reorientation transition,' Phys Rev B Condens Matter,
vol. 49, pp. 15665-8, Jun 1 1994.
124. V. L. Sobolev, et al., 'Spin-reorientation phase transition in Nd2CuO4 in an
external magnetic field: Unusual manifestations of magnetoelastic coupling,'
Phys Rev B Condens Matter, vol. 48, pp. 3417-22, Aug 1 1993.
125. Z. Q. Qiu, et al., 'Asymmetry of the spin reorientation transition in ultrathin Fe
films and wedges grown on Ag(100),' Phys Rev Lett, vol. 70, pp. 1006-9, Feb 15
1993.
126. M. R. Safari, et al., 'Accuracy verification of magnetic resonance imaging
(MRI) technology for lower-limb prosthetic research: utilising animal soft tissue
specimen and common socket casting materials,' Sci World J, vol. 2012,
p. 156186, 2012.
127. Y. Yang, et al., 'Portable magnetic tweezers device enables visualization of the
three-dimensional microscale deformation of
soft biological materials,'
Biotechniques, vol. 51, pp. 29-34, Jul 2011.
128. R. Shakya, et al., 'Amphiphilic and magnetic properties of a new class of
cluster-bearing [L2Cu4(mu4-O)(mu2-carboxylato)4] soft materials,' Chemistry,
vol. 13, pp. 9948-56, 2007.
129. J. P. Butler, et al., 'Measuring surface-area-to-volume ratios in soft porous
materials using laser-polarized xenon interphase exchange nuclear magnetic
resonance,' J Phys Condens Matter, vol. 14, pp. L297-304, Apr 8 2002.
130. S. Yin, et al., 'Local structure evolution of FexNi77-xCu(1-)Nb2P14B6 soft
magnetic materials by mechanical alloying,' J Synchrotron Radiat, vol. 8,
pp. 889-91, Mar 1 2001.
131. A. Vazquez and O. Sotolongo-Costa, 'Dynamics of a domain wall in soft-
