Louis Martin

Education History

• M.S., Materials Science and Engineering, Johns Hopkins University
• Ph.D., Materials Science and Engineering, Johns Hopkins University

Work Experience

Principal Engineer, RSI Pipeline Solutions

Publications

1. K. DePalma, M. Walluk, and L. P. Martin, “Mechanical Properties of High Carbon Steel Coatings on Gray Cast Iron Formed by Twin Wire ARC,” Technology Innovation for the Circular Economy: Recycling, Remanufacturing, Design, Systems Analysis and Logistics, (2024): 555-571.

2. L.P. Martin, A. Luccitti, and M. Walluk, “Evaluation of additive friction stir deposition of AISI 316L for repairing surface material loss in AISI 4340,” The International Journal of Advanced Manufacturing Technology, 121, no. 3 (2022) 2365-2381.

3. K. DePalma, M. Walluk, L. P. Martin, and K. Sisak, “Investigation of mechanical properties of twin wire arc repair of cast iron components,” Journal of Thermal Spray Technology, 31, no. 1 (2022) 315-328.

4. L.P. Martin, A. Luccitti, and M. Walluk. “Evaluation of additive friction stir deposition for the repair of cast Al-1.4 Si-1.1 Cu-1.5 Mg-2.1 Zn,” Journal of Manufacturing Science and Engineering 144, no. 6 (2022) 061006.

5. L.P. Martin, Allen Luccitti, and Mark Walluk. “Repair of aluminum 6061 plate by additive friction stir deposition,” The International Journal of Advanced Manufacturing Technology, (2022) 1-15.

6. L.P. Martin, A. M. Hodge, and G. H. Campbell, “Compaction behavior and mechanical properties of uniaxially pressed Bi-W composites,” Metall. Mater. Trans. A, 40A, 2124 (2009).

7. A.M. Hodge, M. Kumar, L.P. Martin and G.H. Campbell, “Intermetallic layer formation and its effect on the mechanical behavior of laminated Ta-Au composites,” Mat. Sci. Eng., A, 494, 276 (2008).

8. R.T. Krone, L.P. Martin, J.R. Patterson, D. Orlikowski and J. H. Nguyen, “Fabrication and characterization of graded impedance impactors for gas gun experiments from hot pressed magnesium and polyethylene powders,” Mat. Sci. Eng., A, 479, 300 (2008).

9. L.Y. Woo, L.P. Martin, R.S. Glass, W. Wang, S. Jung, R.J. Gorte, E.P. Murray, R.F. Novak, and J.H. Visser, “Effect of electrode composition and microstructure on impedancemetric nitric oxide sensors based on yttria-stabilized zirconia electrolyte,” J. Electrochem. Soc., 155, J32-40 (2008).

10. L.P. Martin, J.R. Patterson, D. Orlikowski and J.H. Nguyen, “Application of Tape-Cast Graded Impedance Impactors for Light-Gas Gun Experiments,” J. Appl. Phys., 102, 023507: 1 –10 (2007).

11. L.P. Martin, A. M. Hodge, and G. H. Campbell, “Compaction behavior of uniaxially cold-pressed Bi-Ta composites,” Scripta Materialia, 57, 229-232 (2007).

12. L.Y. Woo, L.P. Martin and R.S. Glass, “Impedance Characterization of a model Au / yttria-stabilized zirconia (YSZ) / Au Electrochemical Cell in Varying Oxygen and NOx Concentrations,” J. Electrochem. Soc., 154, J129-135 (2007).

13. L.P. Martin, L.Y. Woo and R.S. Glass, “Impedancemetric NOx sensing using YSZ electrolyte and YSZ/Cr2O3 composite electrodes J. Electrochem. Soc., 154, J97-104 (2007).

14. L.P. Martin, D. Orlikowski and J.H. Nguyen, “Fabrication and Characterization of Graded Impedance Impactors for Gas Gun Experiments from Tape Cast Metal Powders,” Mat. Sci. Eng., A, 427, 83-91 (2006).

15. S.W. Song, L.P. Martin, R.S. Glass, E.P. Murray, J.H. Visser, R.E. Soltis, R.F. Novak and D.J. Kubinski, “Aging Studies of Sr-doped LaCrO3/YSZ/Pt Cells for an Electrochemical NOx Sensor,” J. Electrochem. Soc., 153, H171-H180 (2006).

16. L.P. Martin and R.S. Glass, “Hydrogen Sensor Based on Yttria-Stabilized Zirconia and Tin-Doped Indium Oxide Electrode,” J. Electrochem. Soc., 152, H43-H47, (2005).

17. L.P. Martin, A.Q. Pham, and R.S. Glass, “Electrochemical Hydrogen Sensor for Safety Monitoring,” Solid State Ionics, 175, 527-530 (2004).

18. L.P. Martin, A.Q. Pham and R. Glass, “Effect of Cr2O3 Electrode Morphology on the Nitric Oxide Response of a Stabilized Zirconia Sensor,” Sensors and Actuators, B-96, 53-60 (2003).

19. L.P. Martin, D.H. Chambers and G.H. Thomas, “Experimental and Simulated Ultrasonic Characterization of Complex Damage in Fused Silica,” IEEE Trans. Ultrason., Ferroelec., Freq. Contr., 49 [2], 255-265, (2002).

20. L.P. Martin, M.A Norton and G.H. Thomas, “Ultrasonic Monitoring of Laser Damage in Fused Silica,” Appl. Phys. Lett., 78 [22], 3403-3405, (2001).

21. L.P. Martin, E.A. Lindgren, M. Rosen and H. Sidhu, “Ultrasonic Determination of Elastic Moduli in Cement During Hydrostatic Loading to 1 GPa,” Mat. Sci. Eng., A279, 87-94, (2000).

22. L.P. Martin, J.C. Poret, A. Danon and M. Rosen, “Effect of Adsorbed Water on the Ultrasonic Velocity in Alumina Powder Compacts,” Mat. Sci. Eng., A252, 27-35, (1998).

23. A. Birnboim, D. Gershon, J. Calame, A. Birman, Y. Carmel, J. Rodgers, B. Levush, Yu.V. Bykov, A. G. Eremeev, V. V. Holoptsev, V. E. Semenov, D. Dadon, L.P. Martin, M. Rosen and R. Hutcheon, “Comparative Study of Microwave Sintering of Zinc Oxide at 2.45, 30 and 83 GHz,” J. Am. Ceram. Soc., 81, 1493-1501, (1998).

24. L.P. Martin, D. Nagle and M. Rosen, “The Effect of Particle Size Distribution Upon Specific Surface Area and Ultrasonic Velocity in Sintered Ceramic Powders,” Mat. Sci. Eng., A246, 151-160, (1998).

25. L.P. Martin, D. Dadon, M. Rosen, D. Gershon, K.I. Rybakov, A. Birman, J. Calame, B. Levush, Y. Carmel and R. Hutcheon, “Effects of Anomalous Permittivity on the Microwave Heating of Zinc Oxide,” J. Appl. Phys., 83, 432-437, (1998).

26. L.P. Martin and M. Rosen, “Constant Heating-Rate Analysis of Densification Kinetics in Sintering Zinc Oxide,” J. Mat. Synth. Proc., 4, 371-375, (1997).

27. L.P. Martin and M. Rosen, “Correlation Between Surface Area Reduction and Ultrasonic Velocity in Sintered Zinc Oxide Powders,” J. Am. Ceram. Soc., 80, 839-846, (1997).

28. L.P. Martin and M. Rosen, “Analysis of Ultrasonic Velocity Measurements on Sintering Zinc Oxide,” Ultrasonics, 35, 65-73, (1997).

29. J. P. Calame, A. Birman, Y. Carmel, D. Gershon, B. Levush, A.A. Sorokin, V.E. Semenov, D. Dadon, L.P. Martin and M. Rosen, “A Dielectric Mixing Law for Porous Ceramics Based on Fractal Boundaries,” J. Appl. Phys., 80, 3992-4000, (1996).

30. L.P. Martin, D. Dadon, D. Gershon, A. Birman, B. Levush, Y. Carmel and M. Rosen, “Ultrasonic and Dielectric Characterization of Microwave-Sintered and Conventionally Sintered Zinc Oxide,” J. Am. Ceram. Soc.,4, 2652-2658, (1996).

31. L.P. Martin, D. Dadon and M. Rosen, “Evaluation of Ultrasonically Determined Elasticity Porosity Relations in Zinc Oxide,” J. Am. Ceram. Soc., 79 [5], 1281-1289 (1996).

32. D. Dadon, L.P. Martin, A. Birman, Y. Carmel, D. Gershon, J.P. Calame, B. Levush and M. Rosen, “Temperature and Porosity Gradients Developed During Non-isothermal Microwave Processing of Zinc Oxide,” J. Mat. Synth. and Proc., 4 [2], 95-103 (1996).

33. J.J. Suter, P.A. Zucker and L.P. Martin, “Precision Accelerometers for Gravity Gradient Measurements,” JHU/APL Technical Digest, 15, 347 352 (1994).

34. L.P. Martin, J. J. Suter and M. Rosen, “Sapphire Resonator Transducer Accelerometer for Space Gravity Gradiometry,” J. Phys. D: Applied Phys., 27, 875 880 (1994).