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1. |
Rowe, A. and Li, X., "Mathematical Modeling of Proton Exchange Membrane Fuel Cells," J. of Power Sources, Elsevier, 102 (2001) 82-96. |
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2. |
Rowe, A. and Barclay, J., "Ideal Magnetocaloric Effect for Active Magnetic Regenerators," Journal of Applied Physics, 93 3 (2003) 1672-1676. |
3. |
Richard, M-A., Rowe, A.M., Chahine, R., “Magnetic Refrigeration: single and multi-material active magnetic regenerator experiments.” Journal of Applied Physics, 95 4 (2004) 2146-2150. |
4. |
Peksoy, O., and Rowe, A. “Demagnetizing effects in active magnetic regenerators.” Journal of Magnetism and Magnetic Materials, 288C (2005), 424-432. |
5. |
Rowe, A. and Tura, A. “Experimental Investigation of a Three-material Layered AMR”, International Journal of Refrigeration, 29 (2006) 1286-1293. |
6. |
MacDonald, B. and Rowe, A. “Impacts of External Heat Transfer Enhancements on Metal Hydrides Storage Tanks,” International Journal of Hydrogen Energy, 31 (2006) 1721-1731. |
7. |
Jeong, S., Numazawa, T., and Rowe, A., “A review of magnetic refrigeration technology,” Journal of the Korean Institute of Applied Superconductivity and Cryogenics, 8 (2006) 1-10. |
8. |
MacDonald, B. and Rowe, A., “A thermally coupled metal hydride hydrogen storage and fuel cell system,” Journal of Power Sources 161 (2006) 346–355. |
9. |
Maddaloni, J., Rowe, A., and van Kooten, G. C. “Wind Integration into Various Generation Mixtures,” Submitted to Renewable Energy, Sept (2007) |
10. |
Maddaloni, J. and Rowe, A., “Natural gas exergy recovery powering distributed hydrogen production,” International Journal of Hydrogen Energy, 32 (2007) pp. 557-566 |
11. |
Rowe, A., and Tura, A., “Active magnetic regenerator performance enhancement using passive magnetic materials,” Submitted to Journal of Magnetism and Magnetic Materials, Feb (2007). |
12. |
Maddaloni, J., van Kooten, G. C., and Rowe, A. “Network Constrained Wind Integration: An Optimal Cost Approach,” Accepted in Energy Policy, Oct (2007) |
13. |
MacDonald, B. and Rowe, A., “Experimental and numerical analysis of dynamic metal hydride hydrogen storage systems,” Accepted for publication in Journal of Power Sources Sept 2007. |
14. |
Blanchfield, J., Garret, C., Wild, P. and Rowe, A. “The Extractable Power from a Channel Linking a Bay to the Open Ocean,” Submitted to Journal of Power and Energy, Proceedings of the Institution of Mechanical Engineers Part A, Sept 2007. |
15. |
Rowe, A., Barclay, J., and Dost, “Design of an Apparatus for a 5T Conduction-Cooled NbTi Solenoid with a 203 mm Room-Temperature Bore,” Advances in Cryogenic Engineering, Plenum Press, New York 45 (2000) 651. |
16. |
Rowe, A. and Barclay, J., “Static and Dynamic Force Balancing in Reciprocating Active Magnetic Refrigerators,” Advances in Cryogenic Engineering, 47 (2002) 1003-1010. |
17. |
Rowe, A. and Barclay, J., "Design of an Active Magnetic Regenerator Test Apparatus," Advances in Cryogenic Engineering, 47 (2002) 995-1002. |
18. |
Barclay, J.A. Rowe, A.M., Barclay, M.A., “Pressure Build-up in LNG and LH2 Vehicular Cryogenic Storage Tanks.” Advances in Cryogenic Engineering, American Institute of Physics, New York, 49 (2004) 41-47. |
19. |
McDonald, R.L., Rowe, A.M., Dost, S., and Lent, B., “Design of a 1.25 T Superconducting Magnet Apparatus with a Rotating Magnetic Field.” Advances in Cryogenic Engineering, American Institute of Physics, New York, 49 (2004) 726-733. |
20. |
Rowe, A., Peksoy, O., and Barclay, J., “Demagnetizing Effects in Active Magnetic Regenerators.” Advances in Cryogenic Engineering, American Institute of Physics, New York, 49 (2004) 1713-1720. |
21. |
Rowe, A., Tura, A., Richard, M-A., Chahine, R., and Barclay, J., “An Overview of Operating Experience using the AMR Test Apparatus.” Advances in Cryogenic Engineering, American Institute of Physics, New York, 49 (2004) 1721-1728. |
22. |
Tura, A., Roszmann, J., Dikeos, J., and Rowe, A. “Cryogenic AMR Test Apparatus,” Advances in Cryogenic Engineering, edited by J. Weisend et al, AIP, New York, 51 (2006) 985-992. |
23. |
Dikeos, J. and Rowe, A., “Regenerator optimization through the numerical analysis of an active magnetic regenerator (AMR) refrigeration cycle,” Advances in Cryogenic Engineering, edited by J. Weisend et al, AIP, New York, 51 (2006) pp. 993-1000. |
24. |
Francescutti, P. and Rowe, A. “Cryogenic test apparatus for a magnetic and piezoelectric actuation system,” Apparatus.” Advances in Cryogenic Engineering, edited by J. Weisend et al, AIP, New York, 51 (2006) 1775-1782. |
25. |
Rowe, A. and Tura. A. “Active Magnetic Regenerator Enhancement using Passive Magnetic Materials,” Proceedings of the 2nd International Conference on Magnetic Refrigeration at Room Temperature, Portoroz, Slovenia April 11-13 (2007) |
26. |
Tura. A. and Rowe, A. “Design and Testing of a Permanent Magnet Magnetic Refrigerator,” Proceedings of the 2nd International Conference on Magnetic Refrigeration at Room Temperature, Portoroz, Slovenia April 11-13 (2007) |
27. |
Rowe, A. and Tura, A. “Cryogenic Testing of an Active Magnetic Regenerative Refrigerator,” submitted to Advances in Cryogenic Engineering July (2007). |
28. |
Rowe, A. “Performance Metrics for Active Magnetic Refrigerators” Proceedings of the 3rd International Conference on Magnetic Refrigeration at Room Temperature, Des Moines, Iowa May 12-15 (2009) Keynote |
29. |
Tura, A. and Rowe, A. “Progress in the Characterization and Optimization of a Permanent Magnet Magnetic Refrigerator” Proceedings of the 3rd International Conference on Magnetic Refrigeration at Room Temperature, Des Moines, Iowa May 12-15 (2009) |
30.
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Arnold, D. Schopfer, S. Tura, A. and Rowe, A.“Apparatus and Method to Determine Convective Heat Transfer Coefficient and Friction Factor in Regenerators” Proceedings of the 3rd International Conference on Magnetic Refrigeration at Room Temperature, Des Moines, Iowa May 12-15 (2009) |
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