The Experts below are selected from a list of 1329 Experts worldwide ranked by ideXlab platform
René Muller - One of the best experts on this subject based on the ideXlab platform.
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Analytical Solution of Free Radical Polymerization: Applications-Implementing Nonisothermal Effect
Macromolecules, 2014Co-Authors: Dhiraj K. Garg, Christophe A. Serra, Yannick Hoarau, Dambarudhar Parida, Michel Bouquey, René MullerAbstract:Analytical solution (AS), as derived in our previous works for isothermal free radical polymerization (FRP), has been extended to Nonisothermal conditions in this work. Only one differential equation, i.e., the energy balance equation, was required to calculate temperature profile by stiff solver using AS as input values. The results were compared against numerical solution (NS) of the complete set of ordinary differential equations (ODE) of FRP, 11 ODE for full set of equations (FRP_Full), and 8 ODE for quasi steady state approximation (FRP_QSSA). Two different models, namely Chiu, Carratt, and Soong (CCS) and Achilias and Kiparissides (AK), for implementing the gel/glass/cage Effect, were also considered. The results were validated against published results and were found to be in excellent agreement, as well as with NS for all conditions taken. This work proved the versatility, flexibility, and adaptability of AS under all conditions (except for low temperatures) and with various models to simulate gel...
Dhiraj K. Garg - One of the best experts on this subject based on the ideXlab platform.
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Analytical Solution of Free Radical Polymerization: Applications-Implementing Nonisothermal Effect
Macromolecules, 2014Co-Authors: Dhiraj K. Garg, Christophe A. Serra, Yannick Hoarau, Dambarudhar Parida, Michel Bouquey, René MullerAbstract:Analytical solution (AS), as derived in our previous works for isothermal free radical polymerization (FRP), has been extended to Nonisothermal conditions in this work. Only one differential equation, i.e., the energy balance equation, was required to calculate temperature profile by stiff solver using AS as input values. The results were compared against numerical solution (NS) of the complete set of ordinary differential equations (ODE) of FRP, 11 ODE for full set of equations (FRP_Full), and 8 ODE for quasi steady state approximation (FRP_QSSA). Two different models, namely Chiu, Carratt, and Soong (CCS) and Achilias and Kiparissides (AK), for implementing the gel/glass/cage Effect, were also considered. The results were validated against published results and were found to be in excellent agreement, as well as with NS for all conditions taken. This work proved the versatility, flexibility, and adaptability of AS under all conditions (except for low temperatures) and with various models to simulate gel...
Christophe A. Serra - One of the best experts on this subject based on the ideXlab platform.
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Analytical Solution of Free Radical Polymerization: Applications-Implementing Nonisothermal Effect
Macromolecules, 2014Co-Authors: Dhiraj K. Garg, Christophe A. Serra, Yannick Hoarau, Dambarudhar Parida, Michel Bouquey, René MullerAbstract:Analytical solution (AS), as derived in our previous works for isothermal free radical polymerization (FRP), has been extended to Nonisothermal conditions in this work. Only one differential equation, i.e., the energy balance equation, was required to calculate temperature profile by stiff solver using AS as input values. The results were compared against numerical solution (NS) of the complete set of ordinary differential equations (ODE) of FRP, 11 ODE for full set of equations (FRP_Full), and 8 ODE for quasi steady state approximation (FRP_QSSA). Two different models, namely Chiu, Carratt, and Soong (CCS) and Achilias and Kiparissides (AK), for implementing the gel/glass/cage Effect, were also considered. The results were validated against published results and were found to be in excellent agreement, as well as with NS for all conditions taken. This work proved the versatility, flexibility, and adaptability of AS under all conditions (except for low temperatures) and with various models to simulate gel...
Yannick Hoarau - One of the best experts on this subject based on the ideXlab platform.
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Analytical Solution of Free Radical Polymerization: Applications-Implementing Nonisothermal Effect
Macromolecules, 2014Co-Authors: Dhiraj K. Garg, Christophe A. Serra, Yannick Hoarau, Dambarudhar Parida, Michel Bouquey, René MullerAbstract:Analytical solution (AS), as derived in our previous works for isothermal free radical polymerization (FRP), has been extended to Nonisothermal conditions in this work. Only one differential equation, i.e., the energy balance equation, was required to calculate temperature profile by stiff solver using AS as input values. The results were compared against numerical solution (NS) of the complete set of ordinary differential equations (ODE) of FRP, 11 ODE for full set of equations (FRP_Full), and 8 ODE for quasi steady state approximation (FRP_QSSA). Two different models, namely Chiu, Carratt, and Soong (CCS) and Achilias and Kiparissides (AK), for implementing the gel/glass/cage Effect, were also considered. The results were validated against published results and were found to be in excellent agreement, as well as with NS for all conditions taken. This work proved the versatility, flexibility, and adaptability of AS under all conditions (except for low temperatures) and with various models to simulate gel...
Dambarudhar Parida - One of the best experts on this subject based on the ideXlab platform.
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Analytical Solution of Free Radical Polymerization: Applications-Implementing Nonisothermal Effect
Macromolecules, 2014Co-Authors: Dhiraj K. Garg, Christophe A. Serra, Yannick Hoarau, Dambarudhar Parida, Michel Bouquey, René MullerAbstract:Analytical solution (AS), as derived in our previous works for isothermal free radical polymerization (FRP), has been extended to Nonisothermal conditions in this work. Only one differential equation, i.e., the energy balance equation, was required to calculate temperature profile by stiff solver using AS as input values. The results were compared against numerical solution (NS) of the complete set of ordinary differential equations (ODE) of FRP, 11 ODE for full set of equations (FRP_Full), and 8 ODE for quasi steady state approximation (FRP_QSSA). Two different models, namely Chiu, Carratt, and Soong (CCS) and Achilias and Kiparissides (AK), for implementing the gel/glass/cage Effect, were also considered. The results were validated against published results and were found to be in excellent agreement, as well as with NS for all conditions taken. This work proved the versatility, flexibility, and adaptability of AS under all conditions (except for low temperatures) and with various models to simulate gel...
