Dr. Huber came to NIST as a National Research Council Postdoctoral Associate working with Dr. Jim Ely where she worked extensively on various corresponding-states based models for the prediction of thermophysical properties of hydrocarbon mixtures for both defined and undefined (heavy oil fractions) mixtures. Some of this work was incorporated in the NIST Standard Reference Database 4 (SuperTrapp) which was one of NIST's early efforts to disseminate thermophysical property information in the form of computer programs. She later became involved in the research at NIST to model the thermophysical properties of alternatives to ozone-depleting CFC and HCFC refrigerants and fire suppression fluids. She now is the Group Leader of the Theory and Modeling of Fluids Group in the Thermophysical Properties Division. In her spare time she enjoys spending time with her family, eating chocolate and drinking coffee, identifying and photographing wildflowers, trail running, and hiking in the mountains. She may be the only person in Colorado who does not ski.
Recently Dr. Huber has been involved in the development of thermophysical property models for environmentally friendly (low GWP and non-ozone depleting) refrigerants and fire suppression fluids. She also is active in the development of fluid models for the design of microscale heat exchangers. Other interest are developing thermodynamic and transport properties of alternative transportation fuels (including biofuels and hydrogen), thermophysical properties of heavy hydrocarbon systems, jet fuels, diesel, and rocket fuels through the use of surrogate mixture models, in which she works closely with the Experimental Properties of Fluids Group. Of particular interest are the development of models for viscosity and thermal conductivity of both pure fluids and mixtures. She also continues to be involved in the development of software to disseminate thermophysical property information (REFPROP, SuperTrapp).
Perkins, R.A., and Huber, M.L., "Measurement and Correlation of the Thermal Conductivity of 2,3,3,3-Tetrafluoroprop-1-ene (R1234yf) and trans-1,3,3,3-Tetrafluoropropene (R1234ze(E))", J. Chem. Eng. Data, in press
Bruno, T.J., Lovestead, T.M., and Huber, M.L., "Prediction and Preliminary Standardization of Fire Debris Constituents with the Advanced Distillation Curve Method", J. Forensic Sciences 56: S192-S202 (2011)
Assael, M.J., Assael, J.-A., Huber, M.L., Perkins, R.A., Takata, Y., " Correlation of the Thermal Conductivity of Normal and Parahydrogen from the Triple Point to 1000 K and up to 100 MPa," J. Phys. Chem. Ref. Data 40 (2011) 1-13
Huber, M.L., Bruno, T.J., Chirico, R.D., Diky, V., Kazakov, A.F., Lemmon, E.W., Muzny, C.D., and Frenkel, M., "Equations of State on Demand: Application for Surrogate Fuel Development", Int. J. Thermophys. 32:596-613 (2011).
Bruno, T.J., and Huber, M.L., "Evaluation of the Physicochemical Authenticity of Aviation Kerosene Surrogate Mixtures. Part 2: Analysis and Prediction of Thermophysical Properties", Energy & Fuels 24:4277-4284 (2010).
Huber, M.L.,Perkins, R.A., Laesecke, A., Friend, D.G., Sengers, J.V., Assael, M.J., Metaxa, I.N., Vogel, E.,Mares, R., and Miyagawa, K., "New International Formulation for the Viscosity of H2O", J. Phys. Chem. Ref. Data 38: 101-125 (2009)