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Modeling, Analysis, and Simulation o...

Clemson University.

Modeling, Analysis, and Simulation of Adsorption in Functionalized Membranes.

紀錄類型:	書目-電子資源 : Monograph/item
正題名/作者:	Modeling, Analysis, and Simulation of Adsorption in Functionalized Membranes.
作者:	Wilson, Anastasia Bridner.
出版者:	Ann Arbor : ProQuest Dissertations & Theses, 2016
面頁冊數:	238 p.
附註:	Source: Dissertation Abstracts International, Volume: 77-12(E), Section: B.
附註:	Adviser: Lea Jenkins.
Contained By:	Dissertation Abstracts International77-12B(E).
標題:	Applied mathematics.
電子資源:	http://pqdd.sinica.edu.tw/twdaoapp/servlet/advanced?query=10152036
ISBN:	9781369067194

Modeling, Analysis, and Simulation of Adsorption in Functionalized Membranes.
Wilson, Anastasia Bridner.

Modeling, Analysis, and Simulation of Adsorption in Functionalized Membranes. - Ann Arbor : ProQuest Dissertations & Theses, 2016 - 238 p.

Source: Dissertation Abstracts International, Volume: 77-12(E), Section: B.

Thesis (Ph.D.)--Clemson University, 2016.

The emergence of biopharmaceuticals, and particularly therapeutic proteins, as a leading way to manage chronic diseases in humans has created a need for technologies that deliver purified products efficiently and quickly. Towards this end, there has been a significant amount of research on development of porous membranes used in chromatographic bioseparations. In this work, we focus on high-capacity multimodal membranes developed by Husson and colleagues in the Department of Chemical and Biomolecular Engineering at Clemson University.

ISBN: 9781369067194Subjects--Topical Terms:

377601
Applied mathematics.

Modeling, Analysis, and Simulation of Adsorption in Functionalized Membranes.
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500 $a Source: Dissertation Abstracts International, Volume: 77-12(E), Section: B.
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502 $a Thesis (Ph.D.)--Clemson University, 2016.
520 $a The emergence of biopharmaceuticals, and particularly therapeutic proteins, as a leading way to manage chronic diseases in humans has created a need for technologies that deliver purified products efficiently and quickly. Towards this end, there has been a significant amount of research on development of porous membranes used in chromatographic bioseparations. In this work, we focus on high-capacity multimodal membranes developed by Husson and colleagues in the Department of Chemical and Biomolecular Engineering at Clemson University.
520 $a Chromatographic performance of such membranes, particularly the adsorption capabilities of the membranes, depends of a large number of variables making it unrealistic to scan the available options and determine the conditions resulting in the best performance experimentally. Consequently, the goal of this work is to develop a modeling framework capable of describing the process under continuous flow conditions and software tools capable of simulating the protein chromatography process under the effect of complex adsorption relationships.
520 $a In this work, we consider the reactive transport, or advection-diffusion-reaction, problem to model the chromatography process. We focus on the case of highly advective flows as one of the advantages of using membranes in chromatography is the capacity to maintain high protein binding capacity at high flow rates. Toward this end, we utilize a streamline upwind Petrov-Galerkin (SUPG) finite element method to numerically solve the advection-dominated advection-diffusion-reaction equation for porous media.
520 $a The complicating feature of the problem arises from modeling the adsorption reaction. The most accurate, thermodynamically consistent model, or isotherm, for multimodal adsorption, recently developed by Nfor and colleagues, is highly nonlinear and implicitly defined. Even the next best model, Langmuir's isotherm, while not implicitly defined is still nonlinear. As such we develop and analyze discretization methods incorporating nonlinear, potentially implicit, adsorption isotherm models.
520 $a To gain insight into the advection-diffusion-reaction problem, we begin by analyzing the SUPG formulation for the steady state case of the advection-diffusion equation. We also analyze the time-dependent linear cases incorporating constant and linear adsorption models. Although the constant and linear adsorption models do not represent realistic adsorption relationships, the linear analysis serves as a template for the nonlinear analysis.
520 $a When incorporating nonlinear adsorption, we consider two cases: adsorption with an explicit representation as in Langmuir's isotherm and adsorption with an implicit equation as in Nfor's isotherm. In the case of an explicit adsorption relationship, three different formulations are analyzed: a time-integrated mixed methods formulation, a time-integrated SUPG formulation, and a fully implicit SUPG formulation. For the implicit adsorption relationship, a simple formulation is proposed which not only deals with the implicit definition of the isotherm but also deals with the nonlinearity: the right hand side of the isotherm relationship is evaluated at the previous time step. As expected, the solvability and stability for this relationship are all shown to have a requirement on the time step size.
520 $a We provide numerical validation for each of the a priori error estimates. We also compare results of our algorithm with data obtained from laboratory experiments. To improve the accuracy of the numerical simulations, we incorporate non-instantaneous adsorption, considering both constant and transient adsorption rates. Additionally, we numerically investigate the effects of varying velocity profiles by comparing results from simulations involving five different profiles.
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