Elizabeth J. Podlaha-Murphy

Selected Publications

1. Che-Yeh Lim, Q. Huang, X. Xie, A. Safir, S. A. Harfenist, R. Cohn and E. J. Podlaha “Development of an Electrodeposited Nanomold from Compositionally Modulated Alloys, ” Journal of Applied Electrochemistry, in press 2004.
2. A. Lozano-Morales and E.J. Podlaha, “The Effect of Al2O3 Nanopowder on Cu Electrodeposition,” Journal of the Electrochemical Society, in press 2004.
3. Q. Huang and E.J. Podlaha, Simulation of Pulsed Electrodeposition for GMR FeCoNiCu/Cu Multilayers,” Journal of the Electrochemical Society, 151 (2), C119-C126 (2004).
4. A. Panda and E.J. Podlaha, “Nanoparticles to Improve Mass Transport Inside Deep Recesses,” Electrochemical and Solid-State Letters, 6, C149 (2003).
5. Q. Huang, D. P. Young, and E.J. Podlaha, Magnetoresistance of Electrodeposited FeCoNiCu/Cu Multilayers,” Journal of Applied Physics 94 (3): 1864-1867 (2003).
6. Y. Zhuang and E. J. Podlaha, “NiCoFe Ternary Alloy Deposition: II. Influence of Electrolyte Concentration,” Journal of the Electrochemical Society, 150 (4): C219-C224 (2003).
7. Y. Zhuang and E. J. Podlaha, “NiCoFe Ternary Alloy Deposition: III. A Mathematical Model,” Journal of the Electrochemical Society, 150 (4): C225-C233 (2003).
8. Q. Huang, D. P. Young, J. Y. Chan, J. Jiang and E. J. Podlaha, "Electrodeposition of FeCoNiCu/Cu Compositionally Modulated Multilayers," Journal of the Electrochemical Society, 149 (6): C349-C354 (2002).
9. ·A. Muhkerjee, D. Harrison and E. J. Podlaha, "Electrosynthesis of Nanocrystalline Ceria-Zirconia," Electrochemical and Solid-State Letters, 4 (9): D5-D7 (2001).
10. E. J. Podlaha, "Selective Electrodeposition of Nanoparticulates into Metal Matrices," Nano Letters, 1 (8) 413-416 (2001).
11. ·A. Breaux-Vidrine and E.J. Podlaha, "Composite Electrodeposition of Ultra Fine g-Alumina Particles in Nickel Matrices I. Citrate and Chloride Electrolytes," Journal of Applied Electrochemistry, 31 (4) 461-468 (2001).
12. J. Gong and E.J. Podlaha, "Electrodeposition of Fe-Tb Alloys from an Aqueous Electrolyte," Electrochemical and Solid-State Letters, 3 (9) 422-425 (2000).
13. Y. Zhuang and E.J. Podlaha, “NiCoFe Ternary Alloy Deposition: I. An Experimental Kinetic Study,” Journal of the Electrochemical Society, 147, 2231-2236 (2000).
14. N. Zech, E.J. Podlaha and D. Landolt, “Anomalous Codeposition of Iron-Group Alloys, I. Experimental Results,” Journal of the Electrochemical Society, 146, 2886-2891 (1999).
15. N. Zech, E.J. Podlaha and D. Landolt, “Anomalous Codeposition of Iron-Group Alloys, II. Mathematical Model,” Journal of the Electrochemical Society, 146, 2892-2900 (1999).
16. D. Landolt, E.J. Podlaha and N. Zech, “Mathematical Modeling of Electrochemical Alloy Deposition,” Zeitschrift für Physikalische Chemie, 208, 167-182 (1999).
17. N. Zech, E.J. Podlaha and D. Landolt, “ Rotating Cylinder Hull Cell Study of Anomalous Codeposition of Binary Iron-Group Alloys,” Journal of Applied Electrochemistry, 28: (11) 1251-1260 (1998).
18. E. J. Podlaha and D. Landolt, “Pulse-Reverse Plating of Nanocomposite Thin Films,” Journal of the Electrochemical Society, 144, L200-L202 (1997).
19. E. J. Podlaha and D. Landolt, "Induced Codeposition: III. Molybdenum Alloys with Nickel, Cobalt and Iron," Journal of the Electrochemical Society, 144, 1672-1680 (1997).
20. E. J. Podlaha, A. Bögli, Ch. Bonhôte and D. Landolt, "Development of a New, Pseudo-Inverted Disk Electrode," Journal of Applied Electrochemistry, 27, 805-814 (1997).
21. E. J. Podlaha and D. Landolt, "Induced Codeposition: I. Experimental Investigation of Ni-Mo Alloys," Journal of the Electrochemical Society, 143, 885-892 (1996).
22. E. J. Podlaha and D. Landolt, "Induced Codeposition: II. Mathematical Modeling of Ni-Mo Alloys," Journal of the Electrochemical Society, 143, 893-899 (1996).
23. E. J. Podlaha and J. M. Fenton, "Characterization of a Flow-by RVC Electrode Reactor for the Removal of Heavy Metals from Dilute Solutions," Journal of Applied Electrochemistry, 25, 299-306 (1995).
24. E. J. Podlaha, Ch. Bonhôte, and D. Landolt, "A Mathematical Model and Experimental Study of the Electrodeposition of Ni-Cu Alloys from Complexing Electrolytes," Electrochimica Acta, 39, 2649-2657 (1994).
25. E. J. Podlaha and H. Y. Cheh, "Modeling of Cylindrical Alkaline Cells, V. High Discharge Rates," Journal of the Electrochemical Society, 141, 15-27 (1994).
26. E. J. Podlaha and H. Y. Cheh, "Modeling of Cylindrical Alkaline Cells, VI. Variable Discharge Conditions," Journal of the Electrochemical Society, 141, 28-35 (1994).
27. E. J. Podlaha and H. Y. Cheh, "Modeling of Cylindrical Alkaline Cells, VII. A Wound Cell Model," Journal of the Electrochemical Society, 141, 1751-1758 (1994).
28. E. J. Podlaha, M. Matlosz and D. Landolt, "Electrodeposition of High Mo Content Ni-Mo Alloys under Forced Convection," Journal of the Electrochemical Society, 140, L149-L151 (1993).
29. W. J. Horkans, I.-C. Hsu Chang, P. C. Andricacos and E. J. Podlaha, "Determination of Partial Currents During CuNi Electrodeposition using Rotating Ring-Disk Electrodes Journal of the Electrochemical Society, 138, 411-416 (1991).
30. J. M. Fenton, D. T. Grasso and E. J. Podlaha, "A Laboratory Porous Flow-Through Electrode Reactor with Interchangeable Electrodes," Journal of the Electrochemical Society, 137, 2809-2811 (1990).
    
    

Last modified on May 27, 2004