Publications Home
211. "CPP Magnetoresistance in
Metallic Multilayers, A critical review. (J. Bass). J. Magn.
Magn. Mat. 408, 244-320 (2016.
210. "Spin-Flipping in Pt and at
Co/Pt Interfaces", (H.Y.T. Nbuyen, W.P. Pratt Jr., J. Bass).
J. Magn. Magn. Mat. 361, 30 (2014).
209.
“Current-Perpendicular-to-Plane (CPP)-Magnetoresistance”, (J.
Bass). Handbook of Spintronics (Eds. Y. Xu, D Awschalom, &
J Nitta) Springer Publ,
208.
Spin
Relaxation at Sputtered
207.
Spin-Flipping
at Sputtered Co/Ag Interfaces”, (H.Y.T. Nguyen, R. Loloee,
W.P. Pratt Jr. J. Bass), Phys. Rev. B86, 064413
(2012).
206.
Giant Magnetoresistance: Experiment, (J. Bass), In
“Spin-Transport and Magnetism in Electronic Systems”, E.
Tsymbal and
205.
Current-Perpendicular-to-Plane (CPP) Specific Resistance of
Al/Cu Interfaces. (A. Sharma,
204. A Study of Spin-Flipping in Sputtered IrMn using Py-based, Exchange-Biased Spin-Valves, (R. Acharyya, H.Y.T. Nguyen, W.P. Pratt Jr., and J. Bass). J. Appl. Phys. 109, 07C503 (2011).
203. Spin-Flipping at sputtered Co90Fe10/Cu Interfaces, (H.Y.T.Nguyen, R. Acharyya, W.P. Pratt Jr., and J. Bass) J.Appl. Phys. 109, 07C903 (2011).
202. Conduction Electron
Scattering and Spin-Flipping at Sputtered Co/Ni Interfaces,
(H.Y.T. Nguyen, R. Acharyya, E. Huey, B. Richard, R. Loloee,
W.P. Pratt Jr., J. Bass, Shuai Wang and Ke Xia), Phys. Rev. B 82, 220421(R), 2010).
201.
Current-Perpendicular-to-Plane Spin Transport Properties of CoFe
Alloys: Spin Diffusion Length and Scattering Asymmetry, (C. Ahn,
K.-H. Shin, R. J. Bass, R. Loloee, W.P. Pratt Jr.) J. Appl.
Phys., 108, 023908 (2010).
200. CPP transport
properties of Ni/Ru and Co90Fe10/Cu
interfaces, (D.K. Kim, Y.S. Lee, H.Y.T. Nguyen, R. Acharyya, R.
Loloee, K.-H. Shin, Y.K. Kim, B.-C. Min, W.P. Pratt Jr., J.
Bass), IEEE Trans. On Magn.,
46, 1374, (2010).
199. Spin-flipping
associated with the antiferromagnet IrMn, (R. Acharyya, H.Y.T.
Nguyen, W.P. Pratt Jr., and J. Bass), IEEE Trans. On Magn., 46, 1454, (2010).
198. Unusual current
perpendicular-to-plane (CPP) magnetoresistance (MR) for thick Co
layers—difference in MR for fcc and hcp Co, (B. Dassonneville,
R. Acharyya, H.Y.T. Nguyen, R. Loloee, W.P. Pratt Jr., and J.
Bass), IEEE Trans. On Magn.,
46, 1405, (2010).
187. Two Simple tests for Models of Current-Induced
Magnetization Switching. (N. Theodoropoulou, A. Sharma, W.P.
Pratt Jr. ,J. Bass, M.D. Stiles, J. Xiao) J. Appl. Phys. 103,
07A70 (2008).
186. Studies of Effects of Current on Exchange Bias: A Brief
Review. (J. Bass, A. Sharma, Z. Wei, M. Tsoi), J. of
Magnetics of The Korean Magnetics Society 13, 1 (2008).
185. Ballistic vs Diffusive
Transort in Current-Induced Magnetization Switching, (
184. Specific Resistance and Scattering Asymmetry of Py/Pd, Fe/V,
Fe/Nb, and Co/Pt Interfaces. (A. Sharma, J.A. Romero, N.
Theodoropoulou, R. Loloee, W.P. Pratt Jr., and J. Bass, J. Appl.
Phys. 102, 113916
(2007)..
183. HRTEM and
182. Specific Resistance, Scattering Asymmetry, and some
Thermal Instability, of Co/Al, Fe/Al, and Co91Fe9/Al
Interfaces,
(N. Theodoropoulou, A. Sharma T. Haillard, R. Loloee, W.P. Pratt
Jr., and J. Bass, J. Zhang, and M.A. Crimp), IEEE Trans. On Magn. 43,
2860 (2007).
181. Spin-Diffusion Lengths in Metals and Alloys, and
Spin-Flipping at Metal/Metal Interfaces: an Experimentalist’s
Critical Review (J. Bass and W.P. Pratt Jr.), J. Phys. Cond. Matt.
19, 183201 (2007).
180. Changing Exchange Bias in Spin Valves with an Electric
Current (Z. Wei, A. Sharma, A.S. Nunez, P.M. Haney, R.A. Duine, J.
Bass, A.H. MacDonald, and M. Tsoi), Phys. Rev. Lett. 98, 116603 (2007).
179. Effect of asymmetric leads on critical switching current in
magnetic nanopillars. (H. Kurt, M. AlHajDarwish, W.P. Pratt Jr.,
and J. Bass), Appl. Phys. Lett. 89, 082513
(2006).
178. Interface Specific Resistance and Scattering Asymmetry of Permalloy/Al. (N. Theodoropoulou, A. Sharma, R. Loloee, W.P. Pratt Jr., J. Bass, A. Fert, and H. Jaffres) J. Appl. Phys. 99, 08G502 (2006).
177. Studies of Current-Driven
Excitations in Co/Cu/Co Trilayer Nanopillars, (S. Urazhdin, N.O.
Birge, W.P. Pratt Jr., and J. .Bass), "Theory of
Quantum Transport in Metallic and Hybrid Nanostructures, A.Glatz
et al., (Eds), Springer (2006), Pg 39.
176. Comparison of Measured and Calculated Specific Resistances
of Pd/Pt Interfaces (S.K. Olson, R. Loloee, N. Theodoropoulou,
W.P. Pratt Jr., J. Bass, P.X. Xu, and Ke Xia), Appl. Phys. Lett. 87,
252508 (2005).
175. Pd/Ag and Pd/Au Interface Specific Resistances and
Interfacial Spin-Flipping (C. Galinon, K. Tewolde, R. Loloee,
W.-C. Chiang, S. Olson, H. Kurt, W.P. Pratt Jr., J. Bass, P.X. Xu,
Ke Xia, and M. Talanana) Applied Physics Letters, 86, 182502 (2005).
174. Manipulating Current-Induced Magnetization Switching, (S.
Urazhdin, H. Kurt, M. AlHajDarwish, N.O. Birge, W.P. Pratt Jr.,
and J. Bass) J. Appl. Phys. 97,
10C701 (2005).
173. . Current-induced Magnetization
Switching in Permalloy-based nanopillars with Cu, Ag, and Au,
(H. Kurt, R. Loloee, W.P. Pratt Jr., and J. Bass) J. Appl. Phys.
97, 10C706 (2005).
172. Electrical Resistivities of Metals and Alloys, (J. Bass) in
Encyclopedia of Condensed Matter Physics (Elsevier Publ.) Bassani, Liedl, Wyder Eds., Vol. 1,
pps 219-225, (2005).
171. Changes in Magnetic
Scattering Anisotropy at a Ferromagnetic/Superconducting
Interface (K . Eid, H. Kurt, W.P. Pratt Jr. and J. Bass), Phys.
Rev. B70, 100411(R)
(2004).
170. Controlled Normal and Inverse Current-Induced Magnetization
Switching and
Magnetoresistance in
Magnetic Nanopillars, (M. AlHajDarwish, H. Kurt, S. Urazhdin, A.
Fert, R. Loloee, W.P. Pratt Jr., and J. Bass), Phys. Rev. Lett.
93, 157203 (2004).
169. Studies of DC Current-Driven Switching in
Ni(84)Fe(16)/N/Ni(84)Fe(16) Magnetic Nanopillars with N = Cu or
Cu(Pt), (S. Urazhdin, W.P. Pratt Jr., and J. Bass), J. Magn.
Magn. Mat. 282, 264
(2004)..
168. Search for Mean-Free-Path Effects in Current
Perpendicular-to-Plane Magnetoresistance, (Wen. C. Chiang, C.
Ritz, K. Eid, R. Loloee, W.P. Pratt Jr., and J. Bass), Phys. Rev.
B69, 184405 (2004)
167. Current Driven Switching in Magnetic Multilayer
Nanopillars, (S. Urazhdin, N.O. Birge, W.P. Pratt Jr., and J.
Bass), J. Appl. Phys. 95,
7429 (2004), .
166.
Inverted Current-Driven Switching in Fe(Cr)/Cr/Fe(Cr)
Nanopillars, (M.
AlHajDarwish, A. Fert, W.P. Pratt Jr., and J. Bass) J. Appl.
Phys. 95, 6771 (2004).
165. Coupling Effects on Current-Assisted Magnetization Switching, (S. Urazhdin, W.P. Pratt Jr., and J. Bass), J. Magn. Magn. Mat. 272-276, 1586 (2004)..
164.
Current-Driven Excitations in Magnetic Multilayers, A Brief
Review (J. Bass, S. Urazhdin, N.O. Birge, and W.P. Pratt Jr.),
Phys. Stat. Sol. (a) 201,
1379 (2004).
163. Switching
Current vs Magnetoresistance in Magnetic Multilayer Nanopillars,
(S. Urazhdin, N.O. Birge, W.P. Pratt Jr., and J. Bass), Appl.
Phys. Lett. 84, 1516
(2004).
162.
Current-driven Magnetic Excitations in Permalloy-Based
Multilayer Nanopillars (S. Urazhdin, N.O.
Birge, W.P. Pratt Jr., and J. Bass), Phys. Rev. Lett. 91,
146803 (2003).
161. Effect of Antiferromagnetic
Interlayer Coupling on Current-Assisted Magnetization Switching, (S. Urazhdin, H. Kurt, W.P. Pratt
Jr. and J. Bass), Appl. Phys. Lett. 83, 114 (2003).
160. Spin-Memory Loss and CPP-Magnetoresistance in Sputtered
Multilayers with Au (H. Kurt, Wen-C. Chiang, C. Ritz, K.Eid, W.P.
Pratt Jr., and J. Bass), J. Appl. Phys. 93, 7918 (2003).
159. Enhancing Current-Perpendicular-to-Plane Magnetoresistance (CPP-MR) by Adding Interfaces Within Ferromagnetic Layers (K. Eid, W.P. Pratt Jr., and J. Bass) J. Appl. Phys, 93, 3445 (2003).
158. Magnetotransport (Experimental), (J. Bass), in “Spin Transport and Magnetic Interactions" Book, Eds. A. Chtchelkanova, S. Wolf, and Y. Idzerda, Kluwer/Plenum (2003), Pgs. 210-312..
157. Spin-Memory Loss at 4.2K in Sputtered Pd, Pt, and at Pd/Cu and Pt/Cu Interfaces (H. Kurt, R. Loloee, K. Eid, W.P. Pratt Jr., and J. Bass), Appl. Phys. Lett. 81, 4787 (2002).
156. Current driven Resonances in Magnetic Multilayers (M. Tsoi, V. Tsoi, J. Bass, A.G.M. Jansen, and P. Wyder), Phys. Rev. Lett 89, 246803 (2002).
155. Interfacial Properties of Fe/Cr Multilayers n the Current-Perpendicular-to-Plane Geometry, (A. Zambano, K. Eid, R. Loloee, W.P. Pratt Jr., and J. Bass) J. Magn. Magn. Mat. Lett. 253, 51 (2002)..
154. Version 7/21/01 Current-Perpendicular-to-Plane (CPP) Magnetoresistance, (J. Bass and W.P. Pratt Jr.), Physica B 321, 1 (2002).
153. Current-perpendicular-to-plane Magnetoresistance Properties of Ru and Co/Ru Interfaces, (K. Eid, R. Fonck, M. AlHajDarwish, J. Bass, and W. P. Pratt Jr.), J. Appl. Phys., 91, 8102 (2002).
152. Spin-Memory Loss in Metallic Superlattices, (W.P. Pratt Jr., J.Y. Gu, and J. Bass), MRS Symposium Proc., "Spintronics", T.J. Klemmer, J.Z. Sun, A. Fert, and J. Bass Eds., 690, 173 (2002).
151. Further Evidence against Mean-Free-Path Effects in the CPP-MR, (K. Eid, M. Tsoi, D. Portner, R. Loloee, W.P. Pratt Jr., and J. Bass), J. Magn. Magn. Mat. 240, 171 (2002).
150. Absence of Mean-Free-Path Effects in CPP Magnetoresistance of Magnetic Multilayers. (K. Eid, D. Portner, J. Borchers, R. Loloee, M. AlHaj Darwish, M. Tsoi, H. Kurt, K.V. O’Donavan, W.P Pratt Jr., and J. Bass. Phys. Rev. B65, 054424 (2002).
149. The Effect of Indium Contamination and Nb Contact Layers on the Structure of Ag/NiFe GMR SVs, (H. Geng, J. W. Heckman, R. Loloee, W.P. Pratt Jr., and M.A. Crimp), Materials Sci. & Eng. B86, 245 (2001).
148.CPP Magnetoresistance of Magnetic Multilayers: Mean-free-path is not the Culprit, (K. Eid, D. Portner, R. Loloee, W.P. Pratt Jr., and J. Bass), J. Magn. Magn. Mat. 224, L205 (2001).
147.Structural Characterization of Epitaxial GMR Magnetic Multilayers and Spin Valves Grown by Sputter Deposition,(H. Geng, R. Loloee, J.W. Heckman,J. Bass, W.P. Pratt Jr. and M.A Crimp) , in Magnetic Materials, Structures, and Processing for Information Storage, M.A. Seigler, C. Murray, T.P. Nolan, S. Wang, and B.J. Daniels, Eds, MRS Proceedings (In Press).
146. Loss of Spin-Direction Memory (Spin-Relaxation) at Non-Magnetic Interfaces, (W. Park, D. Baxter, S. Steenwyk, I. Moraru, W.P .Pratt Jr., and J. Bass), Phys. Rev. B62, 1178 (2000).
145. Generation and Detection of Phase Coherent Current-Driven Magnons in Magnetic Multilayers, (M. Tsoi, A.G.M. Jansen, J. Bass, W.-C. Chiang, V. Tsoi, and P. M. Wyder), Nature 406, 46 (2000).
144. Current Perpendicular Magnetoresistances of NiCoFe and NiFe ‘Permalloys’ (L. Vila, W. Park, J. Cabellero, D. Bozek, R. Loloee, W.P.Pratt Jr., and J. Bass), J. Appl. Phys. 87, 8610 (2000).
143. Polarized Neutron Reflectivity Characterization of Weakly Coupled Co/Cu Multilayers, (J.A. Borchers, J. A.Dura, C.F. Majkraz, S.Y. Hsu, R. Loloee, W.P. Pratt, and J. Bass) Physica B 283, 162 (2000).
142. Magnetic Depth Profiling Co/Cu Multilayers to Investigate Magnetoresistance, (J. Unguris, D. Tulchinsky, M.H. Kelley, J.A. Borchers, J.A Dura, C.F. Majkrzak, (S.Y. Hsu, R. Loloee, W.P. Pratt Jr. and J. Bass), J. Appl. Phys. 87, 6639 (2000).
141. Enhancing Current-Perpendicular Magnetoresistance in Permalloy-based Exchange-Biased Spin Valves by Increasing Spin-Memory Loss, (J.Y. Gu, S.D. Steenwyk, A.C. Reilly, W. Park, R. Loloee, J. Bass, and W.P. Pratt Jr.), J. Appl. Phys. 87, 4831 (2000).
140. Thermoelectricity (Update) McGraw-Hill Encyclopedia of Science and Technology (2000).
139. Magnetotransport in Metals, (J. Bass) in “Methods in Materials Research”, E.N. Kaufmann Ed., John Wiley & Sons (2000).
138. Studying Conduction Electron-Interface Interactions Using Transverse Electron Focusing, (V.S. Tsoi, J. Bass, and P. Wyder), Rev. Mod. Phys. 71, 1641 (1999).
137. Current
Perpendicular (CPP) Magnetoresistance in Magnetic Metallic
Multilayers (J. Bass and W.P. Pratt Jr.), J. Magn. Magn. Mat.
200, 274 (1999). (Erratum, JMMM 296, 65 (2006)).
136. Occasional ‘Long Range’ Non-equilibrium bcc Structures in NiFe/Cu Spin-Valves (H. Geng, J.W. Heckman, W.P. Pratt Jr., J. Bass, M. Crimp, F.J. Espinosa, S. Conradson, and D. Lederman) J. Appl. Phys. 86, 4166 (1999).
135. Perpendicular Giant Magnetoresistance of Co91Fe9/Cu Exchange-Biased Spin-Valves: Further Evidence for a Unified Picture, (A.C. Reilly, W. Park, R. Slater, B. Ouaglal, W. P. Pratt Jr., J. Bass), J. Magn. Magn. Mat. 195, L269 (1999).
134. Resistance and Spin-Direction Memory Loss at Nb/Cu Interfaces, (D. Baxter, S.D. Steenwyk, J. Bass, and W.P. Pratt, Jr)., J. Appl. Phys. 85, 4545 (1999).
133. Test of Unified Picture of Spin Dependent Transport in Perpendicular (CPP) Giant Magnetoresistance and Bulk Alloys, (W.-Park, R. Loloee, J. Caballero, W.P. Pratt, Jr., P.A. Schroeder, J. Bass, A. Fert, and C. Vouille) J. Appl. Phys. 85, 4542 (1999).
132. Observation of Antiparallel Order in Weakly Coupled Co/Cu Multilayers,(J. Borchers, J.A. Dura, C.F. Majkrzak, J. Unguris, D. Tulchinsky, M.H. Kelley, S.Y.Hsu,R. Loloee, J. Bass, and W.P. Pratt Jr.) Phys. Rev. Lett. 82, 2796 (1999).
131. Effect of Deposition Parameters on the CPP GMR of NiMnSb-Based Spin-Valve Structures, (J.A. Caballero, A.C. Reilly, Y Hao, J. Bass, W.P. Pratt Jr., F. Petroff, and J.R. Childress) J. Magn. Magn. Mat. 198-199, 55 (1999).
130.Giant Magnetoresistance in Copper/Permalloy Multilayers. (P. Holody, R. Loloee, J. Bass, W.P.Pratt Jr, and P.A; Schroeder) Phys. Rev. B58, 12230 (1998).
129. Structural Studies of Silver/Permalloy and Copper/Permalloy GMR Spin-Valve Multilayers, (H. Geng, W. Zhu, J.W. Heckmann, W.P. Pratt, J. Bass, and M.A. Crimp), in “Mechanisms and Principles of Epitaxial Growth in Metallic Systems”, L.T. Wille, C.P. Burmester, K. Terakura, G. Comsa, and E.D. Williams, Eds., MRS Soc. Symp. Proc. 528, 67 (1998).
128. Giant Magnetoresistance of Current-Perpendicular Exchange-Biased Spin-Valves of Co/Cu. (A.C. Reilly, W.-C. Chiang, W.-J. Park, S.Y. Hsu, R. Loloee, S. Steenwyk, W.P. Pratt Jr. and J. Bass) IEEE Trans. Magn. 34, 939 (1998).
127. Magnetoresistance of
NiMnSb-based Multilayers and Spin-Valves. (J.A. Caballero,
126. Excitation of a Magnetic Multilayer by Electric Current. (M.Tsoi, A.G.M. Jansen,J. Bass, W.-C. Chiang, M. Seck, V. Tsoi, and P. Wyder). Phys. Rev. Lett. 80, 4281 (1998).(Erratum: PRL 81, 493 (1998)).
125. Current-Perpendicular (CPP) Giant
Magnetoresistance--Larger and Simpler than
124. Perpendicular Giant Magnetoresistance of Co/Cu
Multilayers with Fluctuating Co
123. Perpendicular-Current
Transport in Exchange-Biased Spin-Valves, (W.P. Pratt Jr.,
S.D. Steenwyk, S.Y. Hsu, W.-C. Chiang, A.C. Schaefer, R.
Loloee, and J. Bass),
122. Perpendicular Current
Exchange Biased Spin-Valve Evidence for a Short Spin
121. Search for Point-Contact Giant Magnetoresistance in Co/Cu Multilayers. (M.V. Tsoi, A.G.M. Jansen, and J. Bass) J. Appl. Phys. 81, 5530 (1997).
120. Variation of Multilayer
Magnetoresistance with Ferromagnetic Layer Sequence:
119. A Comparison of
Hysteresis Loops from Giant Magnetoresistance and
118. Perpendicular Interface Resistances in Sputtered
Ag/Cu, Ag/Au, and Au/Cu
117. Non-Linear Susceptibility of CuMn and AuFe
Spin-Glass Based Multilayers (L. Su,
116. Resistivities of
Sputtered Ni(4.2nm)/Co(tCo)),
Ag(3.3nm)/Cu(tCu), and
115. Finite Size Effects in NiMn Spin-Glass.(L. Hoines, J.A. Cowen, and J. Bass), J. Appl. Phys. 79, 6151 (1996).
114. How Predictable is the
Current Perpendicular to the Plane (CPP) Magnetoresistance?
113. Transverse Electron Focusing, Quantum Electron
Kinetics, and the Hall Effect in Bi,
112. Current Perpendicular and Parallel Giant
Magnetoresistances in Co/Ag Multilayers,
111. High resolution Transmission Electron Microscopy
Study of Metallic Spin-
110. Thermoelectricity
(Update),J. Bass, McGraw-Hill
Encyclopedia of Science and
109. Studying Spin-Dependent Scattering in
Magnetic Multilayers by Means of
108. Prediction and Measurement of Perpendicular
(CPP) Giant Magnetoresistance of
107. Giant Magnetoresistance in Ag/Co and Cu/Co Multilayers with Very Thin CoLayers, (R. Loloee, P.A. Schroeder, W. P. Pratt, Jr., J. Bass, and A. Fert), Physica, B204 274 (1995).
106. Magnetic States of
Magnetic Multilayers at Different Fields, (P.A. Schroeder,
S.-F. Lee,
105. Conductivity in Metals and Alloys (P.L.
Rossiter and J. Bass), Encyclopedia
104. How to Isolate Effects of Finite Spin
Diffusion Length on Giant Magnetoresistance in
103. Spin Diffusion Length and Giant
Magnetoresistance at Low Temperatures,
102. Giant CPP-Magnetoresistance of Ni/Ag
Multilayers, (Q. Yang, S.F. Lee, P. Holody,
101. Finite Size Effects in AuFe Spin Glass Layers,
(L. Hoines, J.A. Cowen, and J. Bass),
100. TEM of Electron-Beam Induced
Crystallization of an Amorphous AuFe(0.03)/Si
99. Perpendicular Magnetoresistance in Cu/Co and
Cu/NiFe Multilayers, P.A. Schroeder,
98. Giant Magnetoresistance with Current
Perpendicular to the Multilayer Planes
97. Giant Magnetoresistance with Current
Perpendicular to the Layer Planes of Ag/Co and
96. Perpendicular Magnetoresistance in Ag/Co and
Cu/Co Multilayers, (P.A. Schroeder,
95.Two-Channel
Analysis
of CPP-MR Data for Ag/Co and AgSn/Co Multilayers,
94.Field Dependent Interface
Resistance" of Ag/Co Multilayers, (S.-F. Lee, W.P. Pratt Jr.,
93.Coupling of Thin
Layers of a Disordered Magnet (Spin Glass) Through a Variety
of
92.Transverse Electron Focusing
as a Way of Studying Surface Crystallography,
91. Finite Size Effects in Metallic Spin
Glasses (J. Bass and J. Cowen), Recent Progress in
90. Aging in a Two-Dimensional CuMn Spin Glass, (J.
Mattsson, P. Granberg,
89. Multilayered Spin Glass Films--Sensitive Probes
of RKKY, (J. Mattsson, P. Granberg,
88. Electronic Transport in Normal Metals, (P.
Rossiter and J. Bass),Materials Science
87. Thermoelectricity (Update), (J. Bass),
McGraw-Hill Encyclopedia of
86. Thermoelectricity, (J. Bass), Colliers Encyclopedia, 22, 284 (1991).
85.Dynamics of Coupled
Two-Dimensional Cu(Mn) Spin-Glass Films, (P. Granberg, J.
84.Finite Size Effects in Thin
AgMn Spin-Glass Layers, (R. Stubi, L. Hoines, M.L. Wilson,
83.Perpendicular Giant
Magnetoresistances of Ag/Co Multilayers (W.P. Pratt Jr., S.-F.
Lee,
82. 2D to 3D Recoupling in AgMn/Cu Multilayers (R.
Stubi, J.A. Cowen, and J. Bass),
81. Dimensionality Effects in Artificially Layered
Spin Glass Structures (J.A. Cowen,
80.How Thin a Spin Glass is
Still a Spin Glass? (L. Hoines, R. Stubi, R.
79. Superconductor-Ferromagnet Boundary Resistance (C. Fierz, S.-F. Lee, W.P. Pratt, Jr., P.A. Schroeder, and J. Bass), J. Phys.Cond. Mat: 2, 970 (1990).
78. 2D and 3D Spin Glass Dynamics in Thin Cu(Mn)
Films (J. Mattsson,
77. Very Low Temperature Thermoelectric Ratio of KRb,
KNa and LiMg Alloys (J. Zhao,
76. Perpendicular Resistance of Thin Co Films in
Contact withSuperconducting Nb,
75. Universality of Finite Size Effects in CuMn and
AgMn Spin-Glasses, (J. Cowen,
74. The Temperature Dependent Electrical
Resistivities of the Alkali Metals, (J. Bass,
73.Finite Size Effects in Thin
CuMn Spin-Glass Layers, (G.G. Kenning, J. Cowen,
72. Dimensionality Crossover in CuMn Spin Glass
Films, (P. Granberg, P. Norblad,
71.Transport Anomalies in K in
Contact with Hydro- and Fluorocarbons, (Z.Z. Yu, Y. Qian,
70.Very Low Temperature
Resistivity of KRb, KNa, and LiMg Alloys, (J. Zhao, Y.J. Qian,
69. Finite Size Effects in a Metallic Spin Glass,
(J.A. Cowen, G.G. Kenning, and J. Bass),
68.Electronic Transport
Properties of Thin Potassium Wires Below 1K: II.
Thermoelectric
67.Electronic Transport
Properties of Thin Potassium Wires Below 1K: I. Derivative of
66. Electron Transport Properties of Ag/Co Layered
Metallic Films (J. Slaughter,
65. Low Temperature Resistivity Anomalies in
Concentrated LiMg Alloys (J. Zhao,
64. Mass Enhancement from Nernst-Ettingshausen
Measurements on Al below 1K
63.Nernst-Ettingshausen
Measurements on Al below 1K (A. Amjadi and J. Bass),
62.Point Contact
Spectroscopy in Al/In Heterojunctions (H. Sato, K. Yonemitsu,
and
61.Electron-Electron
Scattering in Li, (J. Zhao, W.P. Pratt, Jr., P.A. Schroeder,
and
60.Very Low Temperature
Resistivity Anomaly in KRb, KNa and LiMg Alloys, (J. Bass,
59.Transport Anomalies in
Potassium in contact with polyethylene, (Z.-Z. Yu, W.P. Pratt
Jr.,
58.Linear
Magnetoresistance due to Sample Thickness Variations, with
Applications to
57.The Electrical Resistivity
of Na below 1K, (Z.-Z. Yu, W.P. Pratt, Jr., and J. Bass),
56. The Electrical Resistivity of Na below 1K, (Z.-Z.
Yu, W.P. Pratt, Jr.. and J. Bass),
55. Observation of a Resistance Minimum in Potassium
Samples below 0.5K, (Z.-Z. Yu,
54. Low Temperature Anomaly in the Resistivity of KRb
Alloys, (Z.Z. Yu, M. Haerle,
53.A Negative
Temperature Derivative of Resistivity in Thin Potassium
Samples:The
52. Electrical Resistivity of Metals and Alloys at
Cryogenic Temperatures: A Review,
51.The Electrical Resistivities
of Li and Rb Below 1K, (Z.-Z. Yu, M. Haerle, J.W. Zwart,
50. Size Dependence of the Thermopowers of
Pure Metals, (J. Bass), Landolt-Bornstein
49. Thermoelectricity (Update), (J. Bass),
McGraw-Hill Encyclopedia of Science and
48. Electrical Resistivity of Pure Metals and
Dilute Alloys, (J. Bass) Landolt-Bornstein
47.Anomalous Electrical
Resistivity of Potassium Below 0.35K, (C. W. Lee, M. Haerle,
46. High Precision Electrical Resistivity
Measurements on Potassium, (W.P. Pratt, Jr.,
45.Linear Magnetoresistance
caused by Sample Thickness Variations, (G.J.C.L. Bruls,
44.The Electrical Resistivity
of Aluminum below 4.2K, (J.H.J.M. Ribot, J. Bass,
43.Concerning Proposed
Superconducting Fluctuations in the Electrical Resistivity of
Bulk
42.Transverse Electron Focusing
and Specular Reflection in Silver, (V.S. Tsoi, J. Bass,
41.Electronic Transport in
Tungsten and Iron-Doped Tungsten below 1K, (C. Uher,
40.Further Evidence for
Electron-Electron Scattering in Al, (J.H.J.L. Ribot, J. Bass,
39. Observed and Predicted Many-Body Effects in
Thermoelectricity in Metals,
38. Magnetothermopower and Magnetoresistivity of
PtCo, (C.W. Lee, J.R. Cleveland,
37.Thermopower and
Magneto-Thermopower of PtCo, (C.W. Lee, C.L. Foiles, and
36. Thermoelectric Measurements at Millikelvin
Temperatures, (W.P. Pratt, Jr., C. Uher,
35.Measurement of
Electron-Phonon Mass Enhancement in Thermoelectricity, (J.
Bass,
34.The Low Temperature, High
Field Nernst-Ettingshausen Coefficient of Al,
33.Thermopower Anomalies in
PtCo in the Temperature Range 4K to 300K,
32.Conference Summary,
(J. Bass), Proceedings EPS Study Conference on Transport in
31.Electron-Phonon Mass
Enhancement, A Many-Body Effect in Thermoelectricity, (J. Bass
30.Electrical Resistivity and
Thermoelectric Ratio of Reference Grade Pt Below 1K,
29.A Resistivity Minimum in
Tungsten and its Correlation with Thermoelectric Anomalies,
28. Thermoelectricity, (J. Bass), McGraw-Hill
Encyclopedia of Science and Technology,
27.The Electrical Resistivity
of Tungsten Below 1K, (E.L. Stone III, M.D. Ewbank,
26.Low Temperature Electron
Diffusion Magnetothermopower of Aluminum: I.
25.Giant-Magneto-Thermopower
Oscillations in Indium, (B.J. Thaler and J. Bass), Phys.
24.Thermoelectric Measurements
on Tungsten at Ultra-Low Temperatures,
23.Electron-Phonon Mass
Enhancement in Thermoelectricity, (J.L. Opsal, B.J. Thaler,
and
22.Phonon-Enhanced Effective
Mass Thermopower Oscillations in Aluminum,
21. Evidence for Specular Reflection in Thin Tungsten
Wire, (E.L. Stone III,
20.The Vacancy Formation
Energy in Platinum, (J. Zetts and J. Bass), Phil. Mag. 31,
419
19.Measurements of Quenched-in
Resistivity in Thin Single Crystal Tungsten Wires,
18. A.C. Measurements of the Seebeck Coefficient of
Nickel Near Its Curie Temperature,
17.Magnetic Field Dependence of
the Thermopower of Dilute Aluminum Alloys,
16.Comment on the
Stewart-Huebener Procedure for Determining Deviations from
15.Deviations from Matthiessen's Rule, (J. Bass), Adv. in Phys., 21, 431 (1972).
14.Magnetically Induced Sign
Change in the Thermopowers of Aluminum and Indium,
13.A Study of Vacancies in
Tungsten Quenched in Superfluid Helium, (R.J. Gripshover,
12.An A. C. System for
Measuring Thermopower, (R.H. Freeman and J. Bass), Rev. Sci.
11.Vacancies and Matthiessen's
Rule in Gold and Platinum, (R.J. Gripshover, J. Zetts, and J.
10.The Resistivity of
Fine Platinum Wires, (R. Freeman, F.J. Blatt, and J. Bass),
Phys. der
9.Size-Dependent Deviations
from Matthiessen's Rule in Aluminum, (J.B. Van Zytveld and
8. Quenching Platinum and Tungsten in
Superfluid Helium, (R. Gripshover, J. Zetts, and
7.The Thermopower of Pure
Aluminum, (R. Gripshover, J.B. Van Zytveld, and J. Bass),
6.Vacancy-Impurity Binding
Energies in Aluminum-Tin Alloys, (J. Bass), Phys. Lett. 24A,
5.The Formation and Motion
Energies of Vacancies in Aluminum, (J. Bass), Phil. Mag. 15,
4. Vacancy Migration to Sinks During Quenches, (C.P.
Flynn, J. Bass, and D. Lazarus),
3.Quenched Resistance in Dilute
Gold-Tin and Gold-Silver Alloys, (J. Bass), Phys. Rev.
2.The Formation and Motion
Energies of Vacancies in Gold, (C.P. Flynn, J. Bass, and D.
1.Effect of Pressure on the
Mobility of Interstitial Carbon in Iron, (J. Bass and D.
Lazarus),