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Submitted
J. T. O'Connor, Kowall, C., Haapala, K., Agrawal, N., and Paul, B., “Specialty Chemicals Production Case Study: Economic Analysis of Modular Chemical Process Intensification vs. Conventional Stick-Built Approaches”, Journal of Advanced Manufacturing and Processing, vol. 3, Submitted.
2022
A. N. Azri, Patel, R., Ozbuyukkaya, G., Kowall, C., Cormack, G., Proust, N., Enick, R., and Veser, G., “Batch-to-Continuous transition in the specialty chemicals Industry: Impact of operational differences on the production of dispersants”, Chemical Engineering Journal, vol. 445, p. 136775, 2022.
Y. Tian, Meduri, V., Bindlish, R., and Pistikopoulos, E. N., “A Process Intensification synthesis framework for the design of dividing wall column systems”, Computers & Chemical Engineering, vol. 160, p. 107679, 2022.
H. Goyal, Chen, T. - Y., Chen, W., and Vlachos, D. G., “A review of microwave-assisted process intensified multiphase reactors”, Chemical Engineering Journal, vol. 430, p. 133183, 2022.
2021
L. Yan, Edgar, T. F., and Baldea, M., “Dynamic process intensification: Fundamentals and implementation to ternary distillation”, AIChE Journal, vol. 67, p. e17262, 2021.
A. Shankar Raman, Haapala, K. R., O'Connor, J. T., and Paul, B. K., “Economic risk analysis for the capture of a distributed energy resource using modular chemical process intensification”, Journal of Advanced Manufacturing and Processing, vol. 3, p. e10096, 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.
R. B. Dudek and Li, F., “Selective hydrogen combustion as an effective approach for intensified chemical production via the chemical looping strategy”, Fuel Processing Technology, vol. 218, p. 106827, 2021.
M. D. Sees, Kirkes, T., and Chen, C. Chyun, “A simple and practical process modeling methodology for pressure swing adsorption”, Computers and Chemical Engineering, vol. 147, p. 107235, 2021.
M. D. Sees, Kirkes, T., and Chen, C. Chyun, “A simple and practical process modeling methodology for pressure swing adsorption”, Computers and Chemical Engineering, vol. 147, p. 107235, 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.
T. E. Tolley and Fronk, B. M., “FEASIBILITY OF PROCESS INTENSIFICATION OFWATER-GAS SHIFT REACTION USING A MICROREACTOR WITH INTEGRATED COOLING”, in 5th Thermal and Fluids Engineering Conference (TFEC), 2020, pp. 163–172.
T. E. Tolley and Fronk, B. M., “FEASIBILITY OF PROCESS INTENSIFICATION OFWATER-GAS SHIFT REACTION USING A MICROREACTOR WITH INTEGRATED COOLING”, in 5th Thermal and Fluids Engineering Conference (TFEC), 2020.
T. E. Tolley and Fronk, B. M., “Investigation of the benefits of diabatic microreactors for process intensification of the water-gas shift reaction within the steam reforming process”, International Journal of Hydrogen Energy, 2020.
D. Fernandez Rivas, Boffito, D. C., Faria-Albanese, J., Glassey, J., Afraz, N., Akse, H., Boodhoo, K. V. K., Bos, R., Cantin, J., Chiang, Y. Wai, Commenge, J. Marc, Dubois, J. Luc, Galli, F., de Mussy, J. Paul Guene, Harmsen, J., Kalra, S., Keil, F. J., Morales-Menendez, R., Navarro-Brull, F. J., Noël, T., Ogden, K., Patience, G. S., Reay, D., Santos, R. M., Smith-Schoettker, A., Stankiewicz, A. I., van den Berg, H., van Gerven, T., van Gestel, J., van der Stelt, M., van de Ven, M., and Weber, R. S., “Process intensification education contributes to sustainable development goals. Part 1”, 2020.
D. Fernandez Rivas, Boffito, D. C., Faria-Albanese, J., Glassey, J., Afraz, N., Akse, H., Boodhoo, K. V. K., Bos, R., Cantin, J., Chiang, Y. Wai (Emily, Commenge, J. - M., Dubois, J. - L., Galli, F., de Mussy, J. Paul Guene, Harmsen, J., Kalra, S., Keil, F. J., Morales-Menendez, R., Navarro-Brull, F. J., Noël, T., Ogden, K., Patience, G. S., Reay, D., Santos, R. M., Smith-Schoettker, A., Stankiewicz, A. I., van den Berg, H., van Gerven, T., van Gestel, J., van der Stelt, M., van de Ven, M., and Weber, R. S., “Process intensification education contributes to sustainable development goals. Part 1”, Education for Chemical Engineers, vol. 32, pp. 1–14, 2020.
D. Fernandez Rivas, Boffito, D. C., Faria-Albanese, J., Glassey, J., Cantin, J., Afraz, N., Akse, H., Boodhoo, K. V. K., Bos, R., Chiang, Y. Wai, Commenge, J. Marc, Dubois, J. Luc, Galli, F., Harmsen, J., Kalra, S., Keil, F., Morales-Menendez, R., Navarro-Brull, F. J., Noël, T., Ogden, K., Patience, G. S., Reay, D., Santos, R. M., Smith-Schoettker, A., Stankiewicz, A. I., van den Berg, H., van Gerven, T., van Gestel, J., and Weber, R. S., “Process intensification education contributes to sustainable development goals. Part 2”, Education for Chemical Engineers, vol. 32, pp. 15-24, 2020.
D. Fernandez Rivas, Boffito, D. C., Faria-Albanese, J., Glassey, J., Cantin, J., Afraz, N., Akse, H., Boodhoo, K. V. K., Bos, R., Chiang, Y. Wai, Commenge, J. Marc, Dubois, J. Luc, Galli, F., Harmsen, J., Kalra, S., Keil, F., Morales-Menendez, R., Navarro-Brull, F. J., Noël, T., Ogden, K., Patience, G. S., Reay, D., Santos, R. M., Smith-Schoettker, A., Stankiewicz, A. I., van den Berg, H., van Gerven, T., van Gestel, J., and Weber, R. S., “Process intensification education contributes to sustainable development goals. Part 2”, Education for Chemical Engineers, vol. 32, pp. 15–24, 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.
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.
J. P. Polin, Carr, H. D., Whitmer, L. E., Smith, R. G., and Brown, R. C., “Conventional and autothermal pyrolysis of corn stover: Overcoming the processing challenges of high-ash agricultural residues”, Journal of Analytical and Applied Pyrolysis, vol. 143, 2019.
J. P. Polin, Carr, H. D., Whitmer, L. E., Smith, R. G., and Brown, R. C., “Conventional and autothermal pyrolysis of corn stover: Overcoming the processing challenges of high-ash agricultural residues”, Journal of Analytical and Applied Pyrolysis, vol. 143, p. 104679, 2019.
L. Yan, Edgar, T. F., and Baldea, M., “Dynamic process intensification of binary distillation based on output multiplicity”, AIChE Journal, vol. 65, pp. 1162–1172, 2019.
L. Yan, Edgar, T. F., and Baldea, M., “Dynamic process intensification of binary distillation based on output multiplicity”, AIChE Journal, vol. 65, pp. 1162-1172, 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.
L. Yan, Edgar, T. F., and Baldea, M., “Maximizing energy savings attainable by dynamic intensification of binary distillation”, Studia Universitatis Babeș-Bolyai Chemia, vol. 64, pp. 357–369, 2019.
J. P. Polin, Peterson, C. A., Whitmer, L. E., Smith, R. G., and Brown, R. C., “Process intensification of biomass fast pyrolysis through autothermal operation of a fluidized bed reactor”, Applied Energy, vol. 249, pp. 276–285, 2019.
J. P. Polin, Peterson, C. A., Whitmer, L. E., Smith, R. G., and Brown, R. C., “Process intensification of biomass fast pyrolysis through autothermal operation of a fluidized bed reactor”, Applied Energy, vol. 249, pp. 276-285, 2019.
J. Bielenberg and Palou-Rivera, I., “The RAPID Manufacturing Institute – Reenergizing US efforts in process intensification and modular chemical processing”, Chemical Engineering and Processing - Process Intensification, 2019.
J. Bielenberg and Palou-Rivera, I., “The RAPID Manufacturing Institute – Reenergizing US efforts in process intensification and modular chemical processing”, Chemical Engineering and Processing - Process Intensification, 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.
S. E. Demirel, Li, J., and Hasan, M. M. F., “Sustainable Process Intensification Using Building Blocks”, Computer Aided Chemical Engineering, pp. 157-162, 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.
J. Li, Demirel, S. Emre, and Hasan, M. M. Faruque, “Systematic Process Intensification involving Zeotropic Distillation”, Computer Aided Chemical Engineering, pp. 421-426, 2019.
2018
Y. Tian, Demirel, S. Emre, Hasan, M. M. Faruque, and Pistikopoulos, E. N., “An overview of process systems engineering approaches for process intensification: State of the art”, Chemical Engineering and Processing - Process Intensification, vol. 133, pp. 160-210, 2018.
Y. Tian, Demirel, S. Emre, Hasan, M. M. Faruque, and Pistikopoulos, E. N., “An overview of process systems engineering approaches for process intensification: State of the art”, Chemical Engineering and Processing - Process Intensification, vol. 133, pp. 160–210, 2018.
J. Li, Demirel, S. Emre, and Hasan, M. M. Faruque, “Process synthesis using block superstructure with automated flowsheet generation and optimization”, AIChE Journal, vol. 64, pp. 3082–3100, 2018.
J. Li, Demirel, S. Emre, and Hasan, M. M. Faruque, “Process synthesis using block superstructure with automated flowsheet generation and optimization”, AIChE Journal, vol. 64, pp. 3082-3100, 2018.
Y. Tian, M. Mannan, S., and Pistikopoulos, E. N., “Towards a systematic framework for the synthesis of operable process intensification systems”, Computer Aided Chemical Engineering, vol. 44, pp. 2383-2388, 2018.
Y. Tian, M. Mannan, S., and Pistikopoulos, E. N., “Towards a systematic framework for the synthesis of operable process intensification systems”, Computer Aided Chemical Engineering, vol. 44, pp. 2383–2388, 2018.
Y. Tian, M. Mannan, S., Kravanja, Z., and Pistikopoulos, E. N., “Towards the synthesis of modular process intensification systems with safety and operability considerations - application to heat exchanger network”, 28 European Symposium on Computer Aided Process Engineering, vol. 43, pp. 705–710, 2018.
Y. Tian, M. Mannan, S., Kravanja, Z., and Pistikopoulos, E. N., “Towards the synthesis of modular process intensification systems with safety and operability considerations - application to heat exchanger network”, Computer Aided Chemical Engineering, vol. 43, pp. 705-710, 2018.