/College of Engineering and Applied Sciences
Department of Mechanical Engineering

Thomas Cubaud, PhD

Thomas CubaudAssociate Professor

Office: Heavy Engineering 218

Email Address: thomas.cubaud@stonybrook.edu

Phone Number: 631-632-9431 

Lab Website: Microfluidics and Interfacial Fluid Dynamics Laboratory Website

Bio:

Dr. Thomas Cubaud's research interests span between microfluidics, interfacial phenomena, hydrodynamics, nanotechnologies, and soft matter physics. He is interested in the development and the application of methods to produce and control interfaces at the microscale. Dr. Cubaud's research is aimed at developing innovative microfluidic systems into diagnostic, manufacturing, and delivery tools for a wide variety of fluids and soft material. He is a member of the American Society of Mechanical Engineers (ASME), the American Society for Engineering Education (ASEE), and the American Physical Society (APS). 

Education:

  • Paris-Sud University/ESPCI, France, Ph.D. 2001
  • Paris-Sud University, France, M.S. 1998
  • Paris-Sud University, France, B.S. 1997

 

Professional Experience:

  • Department of Mechanical Engineering, Stony Brook University, 2007- present
  • Postdoctoral Research Scholar, Chemistry and Biochemistry Department, University of California, Los Angeles, 2005-2007
  • Postdoctoral Research Scholar, Mechanical and Aerospace Engineering Department, University of California, Los Angeles, 2002-2005

 

Awards & Publications:

  • TBD

 

Professional Memberships & Service:

  • Member of the American Society of Mechanical Engineers (ASME), 
  • Member of the American Society for Engineering Education (ASEE), 
  • Member of the American Physical Society (APS). 

Overview:

Thomas Cubaud’s research is aimed at developing the science and engineering of small-scale flows to new potentials. He studies physical hydrodynamics and examines interfacial phenomena and transport properties of soft materials in microsystems. Research topics include multiphase flows, surface tension, wetting dynamics, miscible flows, and fluid instabilities. Long term goals include conception of innovative microfluidic systems for the diagnostic, manufacturing, and delivery of complex fluids.

Highlights & Accomplishments:

  • Pioneered Multiphase Flow Studies in Microchannels
  • Discovered Viscous Thread Folding in Microsystems
  • Unraveled Various Interfacial Fluid Phenomena and Hydrodynamic Instabilities at the Small-Scale

Research Interests:

  • Manipulation of Complex Fluids and Granular Flows
  • Natural and Industrial Reactive Flow Processes
  • Bubbles, Droplets, and Fluid Mechanics
  • Material Synthesis and Energy Applications