L. Kabacoff, "Nanoceramic Coatings Exhibit Much Higher Toughness and Wear Resistance than Conventional Coatings," The AMPTIAC Newsletter, 6 (Spring, 2002), pp. 37-42.

J.M. Guillemany, S. Dosta, J. Nin, and J.R. Miguel, "Study of the Properties of WC-Co Nanostructured Coatings Sprayed by High-Velocity Oxyfuel," J. Thermal Spray Tech., 14 (2005), pp. 405-413.  Note: Univ. Barcelona team performs comprehensive direct comparison of "unoptimized" coatings using Inframat superfine WC/Co thermal spray feedstock against conventional coatings using commercial WC/Co feedstock (H.C. Starck).

T.D. Xiao, X.Q. Ma, H. Zhang, D.E. Reisner, P.M. Raj, L. Wan, and R. Tummala, "Magnetic Nanocomposite Paste: An Ideal High- µ, k and Q Nanomaterial for Embedded Inductors in High Frequency Electronic Appls.," Procs. 9th World Multiconference on Systemics, Cybernetics and Informatics, July 10-13, 2005, Orlando, FL.

Y. Qiao, T. E. Fischer, A. Dent, "The Effects of Fuel Chemistry and Feedstock Powder Structure on the Mechanical and Tribological Properties of HVOF Thermal-sprayed WC–Co Coatings with Very Fine Structures," Surface and Coatings Technology 172 (2003) pp. 24–41. Note: Traugott Fischer's group at Stevens Tech demonstrate that coatings sprayed at Stony Brook using InfralloyTM powder reduce decarburization, resulting in improved wear resistance.

The Navy's use of Inframat's ceramic nanocoating technology is excerpted (p. 6) in the National Nanotechnology Initiative ("NNI") Supplement to the President's Budget for Fiscal Year 2004 .