DOCSLIB.ORG

Chemical and Biomolecular Engineering

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Chemical and Biomolecular Engineering CHEMICAL AND BIOMOLECULAR ENGINEERING A Distinctive Academic Experience Financial Advantage Lifestyle • Vast interdisciplinary research opportunities • Competitive financial support • Diverse, technologically sophisticated • Close working relationships with faculty • Affordable housing city with open, beautiful spaces • New, state-of-the-art facilities • Cost of living 6.3% below the • Access to top-rated medical facilities national average • Cultural, recreational, and sports activities including college football (National Champion eight times); pro Faculty and Research Areas hockey and soccer. Aravind R. Asthagiri, Carnegie Mellon University Li-Chiang Lin, University of California-Berkeley Computational catalysis, modeling surface chemistry. Materials discovery using molecular simulations for separations, storage and catalysis. Bhavik R. Bakshi, MIT Sustainability science and engineering. Umit S. Ozkan, Iowa State University Heterogeneous and electro-catalysis, kinetics, and catalytic materials. Robert S. Brodkey, University of Wisconsin Experimental measurements for validation of computational fluid mechanics Andre F. Palmer, Johns Hopkins University and applications to mixing processes. Biomaterials for transfusion medicine and tissue engineering. Nicholas A. Brunelli, California Institute of Technology Michael Paulaitis, Princeton University Design of heterogeneous catalytic materials and nanomaterials. Molecular simulations and modeling of weak protein-protein interactions. Jeffrey J. Chalmers, Cornell University James F. Rathman, University of Oklahoma Immunomagnetic cell separation, cancer detection, bioengineering. Molecular informatics and modeling complex chemical and biological phenomena. Stuart L. Cooper, Princeton University Polymer physics, block polymers, ionomers, polyurethanes and biomaterials. Katelyn E. Swindle-Reilly, Washington University in St. Louis Polymeric biomaterials, biomimetics and hydrogel delivery systems. Liang-Shih Fan, West Virginia University Process development of advanced combustion and clean energy systems, David L. Tomasko, University of Illinois at Urbana-Champaign gas-solid fluidization. Molecular thermodynamics, separations, and STEM retention. Martin Feinberg, Princeton University Andrew Tong, The Ohio State University Mathematics of complex chemical systems. Process development of advanced combustion and clean energy systems, gas-solid fluidization. Lisa Hall, University of Illinois at Urbana-Champaign Theory and simulation of polymeric systems. Jessica O. Winter, University of Texas at Austin Nano biotechnology, cancer diagnostics, cancer cell migration. W.S. Winston Ho, University of Illinois at Urbana-Champaign Molecular and chemical membrane separations. David Wood, Rensselaer Polytechnic Institute Biotechnology development through protein engineering. Kurt W. Koelling, Princeton University Rheology, polymer processing, and microfluidics. Barbara E. Wyslouzil, California Institute of Technology Aerosol and particle technology. Isamu Kusaka, California Institute of Technology Statistical mechanics, transport phenomena in nano scale systems. Shang-Tian Yang, Purdue University Biochemical, metabolic, and tissue engineering; biotechnology. L. James Lee, University of Minnesota Nanobiotechnology and polymers, composites and nanomaterials. Jacques Zakin, New York University Drag reduction, heat transfer, rheology. Contact: Graduate Program Coordinator • William G. Lowrie Deptartment of Chemical and Biomolecular Engineering • 151 W. Woodruff Avenue, Columbus, OH 43210-1350 email: [email protected] • ph: (614) 292-9076 • fax: (614) 292-3769 • web: cbe.osu.edu 336 Chemical Engineering Education.
Load more

Recommended publications
  • C L a S S I F I E D L I S T I N
    C LASSIFIEDL ISTINGS POSITIONS AVAILABLE ACADEMIC OPENINGS BP, CHEMICAL RESEARCH ENGINEER UNIVERSITY OF KANSAS, ASSOCIATE/FULL/DISTINGUISHED Located in Warrenville, IL, this position is responsible for conducting PROFESSOR, DEPARTMENT OF CHEMICAL AND PETROLEUM research on the development, implementation & improvement of anaerobic ENGINEERING Tenure track position beginning August 18,2003: The and related effluent control technologies for current /proposed Purified Department of Chemical and Petroleum Engineering at the University of Terephthalic Acid (PTA) plants. Other duties include formulating innovative Kansas invites nominations and applications for a senior faculty position, options to reduce the cost of environmental compliance and direct project including at the Distinguished Professor level. Rank and salary will be com- start-up of PTA wastewater treatment plants worldwide. A master’s degree mensurate with qualifications. The potential candidate is expected to work in Chemical Engineering is required. closely with the Tertiary Oil Recovery Project (TORP) and eventually assume To apply, send resume & salary history to: a leadership position in sustaining and developing TORP activities. BP Chemical, Polyester Int. Business Unit, Attn: Stephen Taylor, Senior HR Required qualifications: earned PhD degree in chemical or petroleum engi- Advisor, MC G-2, 150 W. Warrenville Rd., Naperville, IL 60563. Fax: 630- neering or a closely related field, eligible for a tenured faculty appointment at 961-6223. Email: [email protected]. No phone calls please. EOE. the associate or full professor level, ability to teach petroleum engineering www.bp.com courses and chemical engineering core courses at the undergraduate and graduate levels, and an outstanding record of research and scholarship. CAREER OPPORTUNITIES-NATIONWIDE Applicants for distinguished professorship must met additional criteria avail- EXPERIENCED CANDIDATE’S PHARMACEUTICAL/ BIOMEDICAL ONLY- able in the Faculty Senate Handbook on the KU website (www.ku.edu).
    [Show full text]
  • University of Roci Iesi'er
    UNIVERSITY OF ROCI IESI'ER ONE HUNDR E D FORTY- FOURTH COMMENCEMENT SUNDAY, MAY TWENTY-SECOND NINETEEN HUNDRED NINETY-FOUR A RICH TRADITION AT ROCHESTER 2 Table of COMMENCEMENT CEREMONIES 4 CANDIDATES' SEATING 6 Contents DIPLOMA CEREMONIES 7 HONOR SOCIETIES AND AWARDS 8 DEGREE CANDIDATES 10 College of Arts and Science 10 Bachelor of Arts 10 Bachelor of Science 18 Master of Arts 20 Master of Science 21 William E. Simon Graduate School of Business Administration 22 Margaret Warner Graduate School of Education and Human Development 22 Master of Science 22 Master of Arts in Teaching 23 Doctor of Education 23 College of Engineering and Applied Science 23 Bachelor of Arts 23 Bachelor of Science 23 Master of Science 25 University College of Liberal and Applied Studies 27 Bachelor of Science 27 Eastman School of Music 27 Bachelor of Music 27 Master of Arts 28 Master of Music 29 Doctor of Musical Arts 30 School of Medicine and Dentistry 30 Master of Science 30 Master of Public Health 31 Doctor of Medicine 31 School of Nursing 32 Bachelor of Science 32 Master of Science 33 University Council on Graduate Studies 33 Doctor of Philosophy 33 HONORARY DEGREE AND AWARD RECIPIENTS 41 EASTMAN WIND ENSEMBLE 45 CARILLO N AND CARILLONNEUR 45 SENIOR C LASS COUNCILS 46 MARSHALS 46 COMMENCEMENT COMMITTEE 46 2 Commencement season has always stood out as the "supreme festival" A rich on Rochester's academic calendar, Arthur May notes in his history of the University: From earliest years, "Oratory flowed in full spate, the tradition at literary societies put on their finest performances, trustees convened for annual decision-making, and prizes and diplomas were handed out Rochester amidst a panoply of pomp and circumstance." Though the size of the graduating class h as grown from 10 men in 1851 to mo re than 2,000 men and women today, and though many other developments have reshaped the ceremonies, today's program, like 1851's, marks t he happy celebration of each graduate's academic preparation, and the hopeful prospect of new ventures.
    [Show full text]
  • Copyright © by SIAM. Unauthorized Reproduction of This Article Is Prohibited
    SIAM J. APPL. MATH. c 2009 Society for Industrial and Applied Mathematics Vol. 69, No. 4, pp. 977–998 SENSITIVITY AND ROBUSTNESS IN CHEMICAL REACTION NETWORKS∗ † † ‡ GUY SHINAR ,URIALON, AND MARTIN FEINBERG Abstract. For a wide class of chemical reaction networks, including all those governed by detailed balanced mass-action kinetics, we examine the robustness of equilibrium species concentra- tions against fluctuations in the overall reactant supply. In particular, we present lower bounds on the individual species-concentration sensitivities that derive from reaction network structure alone, independent of kinetic parameters or even of the particular equilibrium state at which sensitivities are calculated. These bounds suggest that, in the class of reaction networks considered here, very high robustness (i.e., very low sensitivities) should be expected only when the various molecules are constructed from a large number of distinct elemental building blocks that appear in high multiplicity or that combine gregariously. This situation is often encountered in biology. Key words. equilibrium points, chemical reaction networks, sensitivity, robustness, systems biology AMS subject classifications. 80A30, 37C05, 37C25, 92C45 DOI. 10.1137/080719820 1. Introduction. 1.1. Motivation. Our interest is in understanding the relationship between the general features of a chemical reaction network and the sensitivity of its equilibria to changes in the overall supply of reactants. Although our concerns are with reaction networks in general, we are motivated by questions that arise naturally in biology. The cell is highly dynamic. Nevertheless, it is reasonable to suppose that in the cytoplasm certain biochemical modules (reaction networks) act on a timescale that is fast relative to other cellular processes (e.g., rela- tive to the production of large proteins or relative to the transport of small molecules across membranes).
    [Show full text]
  • Chapter 8 — Chemical Engineering Research at Purdue
    Chapter 8: Chemical Engineering Research at Purdue 341 Chapter 8 Chemical Engineering Research at Purdue During the early years of the School of Chemical Engineering, research work per se was non- existent. Whatever research was done by Prof. H.C. Peffer was carried out by undergraduate students, who were required to write a B.S. thesis. This thesis was on a short research project performed in the last semester of the senior year. Experimental subjects were always selected and the work could be completed in two to three weeks. Peffer, a metallurgist with Alcoa before he joined Purdue, was interested in new methods for production of metals. For the laboratory experiments his students used either the facilities of the Chemistry Department (especially of E.G. Mahin and P.N. Evans) or of the School of Mechanical Engineering. The first professional Ch.E. degree was awarded to Merle Robert Meacham (1887- 1945) in 1916 for a thesis entitled ―Potentials of the System H2-Pt-0.1N(HCl+KCl)-Hg2Cl2-Hg,‖ supervised by Nathaniel E. Loomis, an instructor in the Chemistry Department. The first M.S. degree was awarded to Ernest H. Hartwig (1895-1992) for a thesis entitled ―Effect of Segregation of Impurities upon Carbon Distribution in Steel,‖ supervised by Prof. E.G. Mahin, of Chemistry. Between 1911 and 1923 Peffer was occupied almost exclusively with teaching. Yet, he found the time for some original research. Thus, the first "publication" of the School appeared in 1923 in the form of a U.S. Patent (No. 1,465,173 issued August 14, 1923) on Electro-deposition of Co and Cr.
    [Show full text]
  • Chapter 5 — Rebirth As a Modern Program. Greenkorn, Koppel And
    Chapter 5: Rebirth as a Modern Program. Greenkorn, Koppel and Andres 127 Chapter 5 Rebirth as a Modern Program. Greenkorn, Koppel and Andres (1967 - 1987) When Professor Brage Golding departed for Ohio State University in October 1966, it was somewhat late to find an immediate replacement for the academic year. Thus, Richard Joseph Grosh (1927-, B.S. '50, M.S. '52, Ph.D. '53, all from Purdue University), Associate Dean of Engineering, was named interim acting Head of the School. Grosh, a gifted administrator and an outstanding researcher (elected to the National Academy of Engineering for outstanding heat transfer research), who a year later would become the new Dean of Engineering (1967-71), and later President of Rensselaer Polytechnic Institute (1971-76) and CEO of Renco Inc. (1976-87), had some very big plans for Chemical Engineering. He made it clear that henceforth this School would devote its primary effort to building an outstanding graduate program. Dean Grosh predicted that in ten years Purdue would be a leading graduate school, able to attract the best undergraduates not only from the Midwestern region but from other regions as well; and that although undergraduate and graduate education would receive the continuous attention of the faculty, it was in graduate research that Purdue was lacking. Most of the faculty members, especially those who had joined the faculty in the previous ten year span, welcomed this drastic change of policy with considerable enthusiasm and dedication, and found in Grosh an astute spokesman for their thoughts and expectations for change. The selection of the new Head, who was going to lead the School to a new era, took several months.
    [Show full text]
  • The Physics of God and the Quantum Gravity Theory of Everything∗
    The Physics of God and the Quantum Gravity Theory of Everything∗ James Redford† September 10, 2012 ABSTRACT: Analysis is given of the Omega Point cosmology, an extensively peer- reviewed proof (i.e., mathematical theorem) published in leading physics journals by professor of physics and mathematics Frank J. Tipler, which demonstrates that in order for the known laws of physics to be mutually consistent, the universe must diverge to infinite computational power as it collapses into a final cosmo- logical singularity, termed the Omega Point. The theorem is an intrinsic compo- nent of the Feynman–DeWitt–Weinberg quantum gravity/Standard Model Theory of Everything (TOE) describing and unifying all the forces in physics, of which itself is also required by the known physical laws. With infinite computational re- sources, the dead can be resurrected—never to die again—via perfect computer emulation of the multiverse from its start at the Big Bang. Miracles are also phys- ically allowed via electroweak quantum tunneling controlled by the Omega Point cosmological singularity. The Omega Point is a different aspect of the Big Bang cosmological singularity—the first cause—and the Omega Point has all the haec- ceities claimed for God in the traditional religions. From this analysis, conclusions are drawn regarding the social, ethical, eco- nomic and political implications of the Omega Point cosmology. ∗Originally published at the Social Science Research Network (SSRN) on December 19, 2011, doi: 10.2139/ssrn.1974708 . Herein revised on September 10, 2012. This article and its contents are re- leased in the public domain. If one desires a copyright for this work, then this article and its contents are also released under Version 3.0 of the “Attribution (By)” Creative Commons license and/or Version 1.3 of the GNU Free Documentation License.
    [Show full text]
  • Martin Feinberg
    Martin Feinberg Present Position: Richard M. Morrow Professor Emeritus of Chemical & Biomolecular Engineering and Professor Emeritus of Mathematics The Ohio State University Koffolt Laboratories 151 West Woodruff Avenue Columbus, Ohio 43210 Phone (614) 688 4883 Fax (614) 292 3769 E-Mail: [email protected] Previous Position: Professor of Chemical Engineering, University of Rochester (University of Rochester employment from 1967-1997) Visiting Positions: Physical Chemistry Laboratory, Oxford University, fall, 1974 Mathematics Research Center, University of Wisconsin, fall, 1979 Institute for Mathematics and its Applications, University of Minnesota, summer, 1983 Visiting Professor, Department of Chemical Engineering, University of the Witwatersrand, Johannesburg, South Africa, September, 1992 Visiting Professor, Department of Systems Biology, Harvard Medical School, February-August, 2007. Education: (All in chemical engineering) B.Ch.E., Cooper Union (1962) M.S., Purdue University (1963) Ph.D., Princeton University (1968) Honors: Camille & Henry Dreyfus Teacher-Scholar, 1973 Edward Peck Curtis Award for Excellence in Undergraduate Teaching, 1994 (Awarded at Commencement to just one University of Rochester faculty member each year.) Plenary Lecturer, Third SIAM Conference on Applications of Dynamical Systems, 1995 Richard Wilhelm Award of the American Institute of Chemical Engineers, 1996 John von Neumann Memorial Lecture in Theoretical Biology, Institute for Advanced Study, Princeton, N.J., 1997 MacQuigg Award for Undergraduate Teaching,
    [Show full text]
  • C L a S S I F I E D L I S T I N
    C LASSIFIEDL ISTINGS supervision/design of refinery units (e.g. FCC, CCR, Hydrotreating). Must POSITIONS AVAILABLE have good interpersonal and communication skills. Be pro-active and part of problem definition and solution. Job Descriptions: Provide leadership to CHEMICAL SAFETY BOARD, CHEMICAL INCIDENT INVESTIGATORS AND process team. Develop working relationship w/ Client process/project RECOMMENDATION SPECIALISTS engineers. Manpower planning for assigned projects. In charge of day-to- The Chemical Safety Board is an independent Federal agency, chartered by day process activities for assigned projects “Instill Value Added culture”. Congress to promote the prevention of chemical accidents at U.S. facilities. Understands client expectations and requested deliverables. Relocation The Office of Investigations and Safety Programs is currently recruiting assistance: to be negotiated. Please email resume to senior and entry-level investigators and recommendation specialists. [email protected]. Refer to Job No. # P5924 and Job Title on your Chemical Incident Investigators are required to report to the Board on the cover letter. Fax 714-503-3990; Jacobs, HR Dept., 5757 Plaza Dr., Cypress, causes of accidental chemical releases. This is accomplished by serving as CA 90630. www.jacobs.com. Jacobs is an Affirmative Action, Equal a team member at the site of chemical incidents shortly after they occur, Employment Opportunity Employer. where investigators conduct a series of interviews, workplace observations, chemical and workplace safety analyses and other fact-finding activities. Activities involve both fieldwork and analysis and report writing at CSB headquarters in Washington DC. The work products will identify root causes ACADEMIC OPENINGS and support specific recommendations for preventing chemical accidents in the future.
    [Show full text]
  • Multiple Equilibria in Complex Chemical Reaction Networks: I
    SIAM J. APPL. MATH. c 2005 Society for Industrial and Applied Mathematics Vol. 65, No. 5, pp. 1526–1546 MULTIPLE EQUILIBRIA IN COMPLEX CHEMICAL REACTION NETWORKS: I. THE INJECTIVITY PROPERTY∗ † ‡ GHEORGHE CRACIUN AND MARTIN FEINBERG Abstract. The capacity for multiple equilibria in an isothermal homogeneous continuous flow stirred tank reactor is determined by the reaction network. Examples show that there is a very delicate relationship between reaction network structure and the possibility of multiple equilibria. We suggest a new method for discriminating between networks that have the capacity for multiple equilibria and those that do not. Our method can be implemented using standard computer al- gebra software and gives answers for many reaction networks for which previous methods give no information. Key words. equilibrium points, chemical reaction networks, chemical reactors, mass-action kinetics AMS subject classifications. 80A30, 37C25, 65H10 DOI. 10.1137/S0036139904440278 1. Introduction. We are interested in studying the uniqueness of positive equi- librium points of a special but large class of systems of nonlinear ordinary differential equations (ODEs): those that derive from chemical reaction networks. In order to understand how these equations arise, we will first look informally at an example of a reaction network and see how it induces a system of ODEs. Consider some chemical species A, B, C, D, W, X, Y, and Z, and suppose that the chemical reactions occurring among these species are (1.1) A + B C, X 2A + D Y, D C + W, B + D Z. We will study a particular kind of reactor, called a continuous flow stirred tank reactor (CFSTR; see [3]) by chemical engineers.
    [Show full text]
  • Cheme N'letter/5-27-99/PDF
    Chemical Engineering NEWSLETTER Spring1999 Purdue University Dear Alumni and Friends of ChE, Katie Eckman retires... Welcome back to the Chemical Engineering In her role as the undergraduate counselor, Newsletter! Much has happened since our last Katie probably knew all of our students. publication. Most notably, we’ve completed and “Knowing” the students for her meant going launched a Strategic Plan for the School for beyond the day to day practicalities of mak- 1997-2002. I am delighted to highlight key ing sure that a student was in the right class items of this exciting road map. or on track for graduation. Her relationship Faculty and staff, with the strong involvement with a student often pre-dated that of the School’s New Directions Industrial Advi- individual’s participation within the depart- sory Council and its Executive Committee, ment, for she was also a counselor in Fresh- worked together for more than a year to de- man Engineering. Katie’s strength is her velop this plan. Officially launched Fall 1997 at ability to unite professional competence with the Council’s annual meeting, it defines the ob- interpersonal involvement. In a program as jectives, strategies, action items, and metrics difficult and rigorous as Chemical Engineer- which will drive our School over the next five ing, she provided emotional support for stu- years. Six component areas were addressed: dents having difficulties, a very • Graduate program important role deeply appreciated • Undergraduate program by the students. She’d take a per- • Faculty sonal interest in each student and • Technical infrastructure go “that extra mile” to help.
    [Show full text]
  • A Survey of Methods for Deciding Whether a Reaction Network
    A survey of methods for deciding whether a reaction network is multistationary Badal Joshi Anne Shiu August 21, 2015 Abstract Which reaction networks, when taken with mass-action kinetics, have the capacity for mul- tiple steady states? There is no complete answer to this question, but over the last 40 years various criteria have been developed that can answer this question in certain cases. This work surveys these developments, with an emphasis on recent results that connect the capacity for multistationarity of one network to that of another. In this latter setting, we consider a network N that is embedded in a larger network G, which means that N is obtained from G by remov- ing some subsets of chemical species and reactions. This embedding relation is a significant generalization of the subnetwork relation. For arbitrary networks, it is not true that if N is embedded in G, then the steady states of N lift to G. Nonetheless, this does hold for certain classes of networks; one such class is that of fully open networks. This motivates the search for embedding-minimal multistationary networks: those networks which admit multiple steady states but no proper, embedded networks admit multiple steady states. We present results about such minimal networks, including several new constructions of infinite families of these networks. Keywords: chemical reaction networks, mass-action kinetics, multiple steady states, deficiency, injectivity 1 Introduction Reaction networks taken with mass-action kinetics arise in many scientific areas, from epidemi- ology (the SIR model) to population biology (Lotka–Volterra) to systems of chemical reactions. Indeed, reaction networks often form a suitable modeling framework when the variables of in- terest take non-negative values.
    [Show full text]
  • The Princeton Companion to Applied Mathematics
    © Copyright, Princeton University Press. No part of this book may be distributed, posted, or reproduced in any form by digital or mechanical means without prior written permission of the publisher. Contributors David Acheson, Emeritus Fellow, Jesus College, Thomas J. Brennan, Professor of Law, Harvard Law School University of Oxford portfolio theory [V.10] inverted pendulums [VI.4], teaching applied mathematics [VIII.7] David S. Broomhead, Professor of Applied Mathematics, The University of Manchester (deceased) Miguel A. Alonso, Associate Professor, applications of max-plus algebra [VII.4] The Institute of Optics at the University of Rochester modern optics [V.14] Kurt Bryan, Professor of Mathematics, Rose–Hulam Institute of Technology Douglas N. Arnold, McKnight Presidential Professor of cloaking [VI.1] Mathematics, University of Minnesota the flight of a golf ball [VI.6] Dorothy Buck, Reader in BioMathematics, Imperial College London Karl Johan Åström, Emeritus Professor, knotting and linking of macromolecules [VI.8] Department of Automatic Control, Lund Institute of Technology/University of Lund Chris Budd, Professor of Applied Mathematics, control theory [IV.34] University of Bath; Professor of Mathematics, Royal Institution of Great Britain David H. Bailey, Lawrence Berkeley National Laboratory slipping, sliding, rattling, and impact: (retired); Research Fellow, University of California, Davis nonsmooth dynamics and its applications [VI.15] experimental applied mathematics [VIII.6] John A. Burns, Hatcher Professor of Mathematics
    [Show full text]