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2021
S. Emre Demirel, Li, J., and Hasan, M. M. Faruque, “Membrane Separation Process Design and Intensification”, Industrial & Engineering Chemistry Research, 2021.
S. Emre Demirel, Li, J., and Hasan, M. M. Faruque, “Membrane Separation Process Design and Intensification”, Industrial & Engineering Chemistry Research, vol. 60, pp. 7197–7217, 2021.
E. N. Pistikopoulos, Tian, Y., and Bindlish, R., “Operability and control in process intensification and modular design: Challenges and opportunities”, AIChE Journal, vol. 67, p. e17204, 2021.
E. N. Pistikopoulos, Tian, Y., and Bindlish, R., “Operability and control in process intensification and modular design: Challenges and opportunities”, AIChE Journal, vol. 67, p. e17204, 2021.
Y. Tian, Pappas, I., Burnak, B., Katz, J., and Pistikopoulos, E. N., “Simultaneous design & control of a reactive distillation system – A parametric optimization & control approach”, Chemical Engineering Science, vol. 230, p. 116232, 2021.
Y. Tian, Pappas, I., Burnak, B., Katz, J., and Pistikopoulos, E. N., “Simultaneous design & control of a reactive distillation system – A parametric optimization & control approach”, Chemical Engineering Science, vol. 230, p. 116232, 2021.
M. Sadaf Monjur, Demirel, S. Emre, Li, J., and Hasan, M. M. Faruque, “SPICE_MARS: A Process Synthesis Framework for Membrane-Assisted Reactive Separations”, Industrial & Engineering Chemistry Research, vol. 60, pp. 7635–7655, 2021.
M. Sadaf Monjur, Demirel, S. Emre, Li, J., and Hasan, M. M. Faruque, “SPICE_MARS: A Process Synthesis Framework for Membrane-Assisted Reactive Separations”, Industrial & Engineering Chemistry Research, 2021.
2020
A. K. Tula, Eden, M. R., and Gani, R., “Computer-aided process intensification: Challenges, trends and opportunities”, AIChE Journal, vol. 66, p. e16819, 2020.
A. Arora, Li, J., Zantye, M. S., and Hasan, M. M. Faruque, “Design standardization of unit operations for reducing the capital intensity and cost of small‐scale chemical processes”, AIChE Journal, vol. 66, 2020.
A. Arora, Li, J., Zantye, M. S., and Hasan, M. M. Faruque, “Design standardization of unit operations for reducing the capital intensity and cost of small‐scale chemical processes”, AIChE Journal, vol. 66, p. e16802, 2020.
S. Hye Kim and Boukouvala, F., “Surrogate-based optimization for mixed-integer nonlinear problems”, Computers & Chemical Engineering, vol. 140, p. 106847, 2020.
S. Hye Kim and Boukouvala, F., “Surrogate-based optimization for mixed-integer nonlinear problems”, Computers and Chemical Engineering, vol. 140, 2020.
Y. Tian, Pappas, I., Burnak, B., Katz, J., and Pistikopoulos, E. N., “A Systematic Framework for the synthesis of operable process intensification systems – Reactive separation systems”, Computers and Chemical Engineering, vol. 134, p. 106675, 2020.
Y. Tian, Pappas, I., Burnak, B., Katz, J., and Pistikopoulos, E. N., “A Systematic Framework for the synthesis of operable process intensification systems – Reactive separation systems”, Computers & Chemical Engineering, vol. 134, p. 106675, 2020.
Y. Tian and Pistikopoulos, E. N., “Toward an Envelope of Design Solutions for Combined/Intensified Reaction/Separation Systems”, Industrial & Engineering Chemistry Research, vol. 59, pp. 11350-11354, 2020.
Y. Tian and Pistikopoulos, E. N., “Toward an Envelope of Design Solutions for Combined/Intensified Reaction/Separation Systems”, Industrial & Engineering Chemistry Research, vol. 59, pp. 11350–11354, 2020.
2019
S. Avraamidou and Pistikopoulos, E. N., “A Bi-Level Formulation And Solution Method For The Integration Of Process Design And Scheduling”, Computer Aided Chemical Engineering, vol. 47, pp. 17-22, 2019.
S. Avraamidou and Pistikopoulos, E. N., “A Bi-Level Formulation And Solution Method For The Integration Of Process Design And Scheduling”, Computer Aided Chemical Engineering, vol. 47, pp. 17–22, 2019.
M. M. F. Hasan, Demirel, S. E., and Li, J., “A Building Block Approach to Process Intensification”, Chemical Engineering Progress, 2019.
M. M. F. Hasan, Demirel, S. E., and Li, J., “A Building Block Approach to Process Intensification”, Chemical Engineering Progress, 2019.
A. K. Tula, Eden, M. R., and Gani, R., “Component based development of computer-aided tools for different applications”, Computer Aided Chemical Engineering, vol. 46, pp. 91-96, 2019.
A. K. Tula, Eden, M. R., and Gani, R., “Component based development of computer-aided tools for different applications”, Computer Aided Chemical Engineering, vol. 46, pp. 91–96, 2019.
A. K. Tula, Eden, M. R., and Gani, R., “Computer‐aided process intensification: Challenges, trends and opportunities”, AIChE Journal, 2019.
S. Mohammadi and Cremaschi, S., “Efficiency of Uncertainty Propagation Methods for Estimating Output Moments”, Computer Aided Chemical Engineering, pp. 487-492, 2019.
S. Mohammadi and Cremaschi, S., “Efficiency of Uncertainty Propagation Methods for Estimating Output Moments”, Computer Aided Chemical Engineering, pp. 487–492, 2019.
S. Emre Demirel, Li, J., and Hasan, M. M. Faruque, “A General Framework for Process Synthesis, Integration, and Intensification”, Industrial & Engineering Chemistry Research, vol. 58, pp. 5950-5967, 2019.
S. Emre Demirel, Li, J., and Hasan, M. M. Faruque, “A General Framework for Process Synthesis, Integration, and Intensification”, Industrial & Engineering Chemistry Research, vol. 58, pp. 5950–5967, 2019.
Y. Tian and Pistikopoulos, E. N., “Generalized Modular Representation Framework for the Synthesis of Extractive Separation Systems”, Computer Aided Chemical Engineering, pp. 475-480, 2019.
Y. Tian and Pistikopoulos, E. N., “Generalized Modular Representation Framework for the Synthesis of Extractive Separation Systems”, Computer Aided Chemical Engineering, pp. 475–480, 2019.
A. K. Tula, Eden, M. R., and Gani, R., “Hybrid method and associated tools for synthesis of sustainable process flowsheets”, Computers and Chemical Engineering, vol. 131, 2019.
A. K. Tula, Eden, M. R., and Gani, R., “Hybrid method and associated tools for synthesis of sustainable process flowsheets”, Computers and Chemical Engineering, vol. 131, p. 106572, 2019.
S. Hye Kim and Boukouvala, F., “Machine learning-based surrogate modeling for data-driven optimization: a comparison of subset selection for regression techniques”, Optimization Letters, 2019.
S. Hye Kim and Boukouvala, F., “Machine learning-based surrogate modeling for data-driven optimization: a comparison of subset selection for regression techniques”, Optimization Letters, vol. 14, 2019.
G. Hüllen, Zhai, J., Kim, S. Hye, Sinha, A., Realff, M. J., and Boukouvala, F., “Managing Uncertainty in Data-Driven Simulation-Based Optimization”, Computers & Chemical Engineering, p. 106519, 2019.
G. Hüllen, Zhai, J., Kim, S. Hye, Sinha, A., Realff, M. J., and Boukouvala, F., “Managing Uncertainty in Data-Driven Simulation-Based Optimization”, Computers & Chemical Engineering, p. 106519, 2019.
A. K. Tula, Eden, M. R., and Gani, R., “ProCAFD: Computer-aided Tool for Sustainable Process Synthesis, Intensification and Hybrid solutions”, Computer Aided Chemical Engineering, vol. 46, pp. 481-486, 2019.
A. K. Tula, Eden, M. R., and Gani, R., “ProCAFD: Computer-aided Tool for Sustainable Process Synthesis, Intensification and Hybrid solutions”, Computer Aided Chemical Engineering, vol. 46, pp. 481–486, 2019.
B. A. Williams and Cremaschi, S., “Surrogate Model Selection for Design Space Approximation And Surrogate-model based Optimization”, Computer Aided Chemical Engineering, vol. 47, pp. 353-358, 2019.
B. A. Williams and Cremaschi, S., “Surrogate Model Selection for Design Space Approximation And Surrogate-model based Optimization”, Computer Aided Chemical Engineering, vol. 47, pp. 353–358, 2019.
S. E. Demirel, Li, J., and Hasan, M. M. F., “Sustainable Process Intensification Using Building Blocks”, ACS Sustainable Chemistry & Engineering, vol. 8, pp. 157–162, 2019.
Y. Tian and Pistikopoulos, E. N., “Synthesis of operable process intensification systems: advances and challenges”, Nanotechnology: water-energy nexus ● Process Systems Engineering: process intensification, vol. 25, pp. 101–107, 2019.
Y. Tian and Pistikopoulos, E. N., “Synthesis of operable process intensification systems: advances and challenges”, Current Opinion in Chemical Engineering, vol. 25, pp. 101-107, 2019.
Y. Tian and Pistikopoulos, E. N., “Synthesis of Operable Process Intensification Systems - Steady-State Design with Safety and Operability Considerations”, Industrial and Engineering Chemistry Research, vol. 58, pp. 6049–6068, 2019.
Y. Tian and Pistikopoulos, E. N., “Synthesis of Operable Process Intensification Systems - Steady-State Design with Safety and Operability Considerations”, Industrial and Engineering Chemistry Research, vol. 58, pp. 6049-6068, 2019.
A. K. Tula, Eden, M. R., and Gani, R., “Systematic Method and Tool for Sustainable Process Synthesis, Design, Analysis and Innovation”, Computer Aided Chemical Engineering, vol. 47, pp. 385-390, 2019.
A. K. Tula, Eden, M. R., and Gani, R., “Systematic Method and Tool for Sustainable Process Synthesis, Design, Analysis and Innovation”, Computer Aided Chemical Engineering, vol. 47, pp. 385–390, 2019.
J. Li, Demirel, S. Emre, and Hasan, M. M. Faruque, “Systematic Process Intensification involving Zeotropic Distillation”, Computer Aided Chemical Engineering, pp. 421-426, 2019.
J. Li, Demirel, S. Emre, and Hasan, M. M. Faruque, “Systematic Process Intensification involving Zeotropic Distillation”, Computer Aided Chemical Engineering, vol. 47, pp. 421–426, 2019.
2018
S. E. Davis, Cremaschi, S., and Eden, M. R., “Efficient Surrogate Model Development: Impact of Sample Size and Underlying Model Dimensions”, Computer Aided Chemical Engineering, vol. 44, pp. 979–984, 2018.