@article{peralta_bangi_2006, title={Finite element model for the heating of frozen wood}, volume={38}, number={2}, journal={Wood and Fiber Science}, author={Peralta, P. N. and Bangi, A. P.}, year={2006}, pages={359–364} }
 @article{peralta_bangi_2005, title={Sensible heating approach to controlling the equilibrium moisture content of wood}, volume={55}, number={12}, journal={Forest Products Journal}, author={Peralta, P. N. and Bangi, A. P.}, year={2005}, pages={17–20} }
 @article{marlowe_ramsey_peralta_bangi_2004, title={GIS mapping of monthly outdoor and indoor equilibrium moisture content for the United States}, volume={54}, number={12}, journal={Forest Products Journal}, author={Marlowe, W. J. and Ramsey, J. D. and Peralta, P. and Bangi, A. P.}, year={2004}, pages={122–125} }
 @article{peralta_bangi_2003, title={A nonlinear regression technique for calculating the average diffusion coefficient of wood during drying}, volume={35}, number={3}, journal={Wood and Fiber Science}, author={Peralta, P. N. and Bangi, A. P.}, year={2003}, pages={401–408} }
 @article{peralta_bangi_2000, title={Grid-based tactile sensor system for shrinkage pressure measurement}, volume={32}, number={1}, journal={Wood and Fiber Science}, author={Peralta, P. N. and Bangi, A. P.}, year={2000}, pages={52–60} }
 @article{peralta_bangi_1998, title={Modeling wood moisture sorption hysteresis based on similarity hypothesis. I. Direct approach}, volume={30}, number={1}, journal={Wood and Fiber Science}, author={Peralta, P. N. and Bangi, A. P.}, year={1998}, pages={48–55} }
 @article{peralta_bangi_1998, title={Modeling wood moisture sorption hysteresis based on similarity hypothesis. II. Capillary-radii approach}, volume={30}, number={2}, journal={Wood and Fiber Science}, author={Peralta, P. N. and Bangi, A. P.}, year={1998}, pages={148–154} }
 @article{peralta_bangi_lee_1997, title={Thermodynamics of moisture sorption by the giant-timber bamboo}, volume={51}, ISSN={["0018-3830"]}, DOI={10.1515/hfsg.1997.51.2.177}, abstractNote={The thermodynamic interaction of water with giant-timber bamboo (Phyllostachys bambusoides Sieh. & Zucc.) was investigated. Thermodynamic properties were evaluated based on isosteric calculations from sorption isotherms at 20, 30, 40 and 50°C. The results show that. compared to wood, giant-timber bamboo exhibits less hygroscopicity and greater hysteresis. The differential heat of sorption. Q was found to be an exponential function of fractional moisture content, m, and decreased somewhat with increasing temperature. The relation Q s = (Q s ) o exp(-B 1 m) was considered to he reasonably adequate, but a better fit was provided by the equation Q s = A 2 + B 2 m + C 2 exp(-D 2 m) so that it was used in the calculation of the heat of wetting, W, and the integral heat of sorption, (W o - W). The differential heat of sorption at ovendry condition fell within the range observed for wood and other lignocellulosic material, The free energy, G., and the entropy, S., of sorbed water were in close agreement with those observed for wood, reconfirming the theory that definite enthalpy, free energy, and entropy changes accompany the sorption of water by lignocellulosic materials.}, number={2}, journal={HOLZFORSCHUNG}, author={Peralta, PN and Bangi, AP and Lee, AWC}, year={1997}, pages={177–182} }