Brian Washburn

Brian Washburn
Associate Professor
Address:	36C Cardwell Hall
Phone:	(785) 532-2263
E-mail:	washburn@phys.ksu.edu
Personal Webpage
Ph.D. Georgia Institute of Technology, 2002
B.S. University of Wisconsin - Parkside, 1994

Research Area

My research falls within the intersection of nonlinear fiber optics, laser physics, and photonic crystal technology. Optics has many academic topics that can be applied to develop useful technology. I enjoy working on physics research that addresses questions of basic science while having significant technological or industrial impact. This line of research allows students to develop strong theoretical and experimental skills, to experience a broad research background in a variety of research topics, and to understand aspects of working in industry. Currently, I am supervising graduate students JinKang Lim and Rajesh Kadel, and undergraduate Daniel Moeder. I work collaboratively with members in Dr. Kristan Corwin’s group including postdoc Karl Tillman, graduate students Kevin Knabe, Andrew Jones, Rajesh Thapa, and Shun Wu. I also have many outside collaborations which include two companies and two outside universities.

Our research has made significant contributions to fiber based infrared frequency combs, which can be used as a robust and portable system for precision spectroscopy. We have phase-stabilized, for the first time, a fiber laser that uses carbon nanotubes for a saturable absorber. The carbon nanotube fiber laser frequency comb offers much promise as a portable, robust, and inexpensive fiber frequency comb with further potential for scaling to higher repetition frequencies. We performed careful measurements to measure the fractional stability of this comb and compared it with combs in our laboratory. We have also combed this comb to a Cr:Forsterite laser based comb. In addition, we have used the carbon nanotube laser comb to measure the accuracy of Dr. Corwin’s gas filled hollow optical fiber frequency references. With the help of Daniel Moeder, we are developing methods for injecting carbon nanotubes in photonic crystal fibers to serve as the saturable absorber.

Dr. Corwin and I are part of a collaborative program to develop molecular gas-filled hollow optical fiber lasers. This collaboration includes the University of New Mexico, the University of Bath, and Precision Photonics Corporation. We demonstrated what we believe is the first optically pumped gas laser based on population inversion in a hollow core photonic crystal fiber. The laser produces mid-IR (3.1-3.2 μm) lasing by optically pumping with 1.5 μm, nanosecond pulses. We are in the process of making a similar molecular gas which will have lower lasing threshold. Andrew Jones and new graduate student Rajesh Kadel are working on the making the first acetylene filled fiber laser.

Research Support

ARO STTR
AFOSR
Kansas DEPSCoR
ARO STTR
National Science Foundation

Recent Selected Publications

"C₂H₂ Gas Laser Inside Hollow-Core Photonic Crystal Fiber Based on Population Inversion", A. M. Jones, V. V. Nampoothiri, A. Ratanavis, R. Kadel, N. Wheeler, F. Couny, F. Benabid, W. Rudolph, B. R. Washburn, and K. L. Corwin, Conference of Lasers and Electro-optics (CLEO), San Jose, CA (2010)
“10 kHz accuracy of an optical frequency reference based on ¹²C₂H₂-filled large-core kagome photonic crystal fibers”, K. Knabe, S. Wu, J. Lim, K. A. Tillman, P. S. Light, Fr. Couny, N. Wheeler, R. Thapa, A. M. Jones, J. W. Nicholson, B. R. Washburn, F. Benabid, and K. L. Corwin, , 17, 18, pp. 16017–16026 (2009)
"A phase-stabilized carbon nanotube fiber laser frequency comb", J. Lim, K. Knabe, K. A. Tillman, W. Neely, Y. Wang, R. Amezcua-Correa, F. Couny, P. S. Light, F. Benabid, J. C. Knight, K. L. Corwin, J. W. Nicholson, and Brian R. Washburn, Opt. Express 17, 14115-14120 (2009)
“Sub-33 fs Pulses from an All-Fiber Parabolic Amplifier Employing Hollow-Core Photonic Bandgap Fiber”, Y. Wang, J. Lim, R. Amezcua-Correa, J.C. Knight, and B.R. Washburn, , Frontiers in Optics, OSA Annual Meeting, Rochester, NY (2008)
"Splicing Hollow-Core Photonic Bandgap Fibers to Step-Index Fibers Using an Arc Fusion Splicer”, R. Thapa, K. Knabe K. L. Corwin, and B. R. Washburn, Optics Express, v 14, n 21, p 9576-9583 October (2006).