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Department of Chemistry and Biochemistry The University of Texas at Austin Phone: 512.471.3761 105 E. 24th St. Stop A5300 Fax: 512.471.0088 Allen J. Bard Austin, TX 78712-1224 E-mail: [email protected] Education Ph.D. in Chemistry, 1958, Harvard University (J. J. Lingane, mentor) M.A. in Chemistry, 1956, Harvard University (J. J. Lingane, mentor) B.Sc. in Chemistry, 1955, City College of New York, summa cum laude Thayer Scholarship, 1955-1956 National Science Foundation Predoctoral Fellowship, 1956-1958 Professional Positions Director, Center for Electrochemistry, The University of Texas, 2006-present Hackerman-Welch Regents Chair in Chemistry, The University of Texas, 1985-present Norman Hackerman Professor of Chemistry, The University of Texas, 1982-1985 Jack S. Josey Professorship in Energy Studies, The University of Texas, 1980-1982 Professor of Chemistry, The University of Texas, 1967-present Associate Professor, The University of Texas, 1962-1967 Assistant Professor, The University of Texas, 1960-1962 Instructor, The University of Texas, 1958-1960 Fulbright Fellow (University of Paris 7), 1973 Visiting Professor (University of Tokyo) 1975 Sherman Mills Fairchild Scholar (California Institute of Technology), 1977 Woodward Visiting Professor (Harvard University), 1988 Research Interests Research interests involve the application of electrochemical methods to the study of chemical problems and include investigations in electroanalytical chemistry, electron spin resonance, electro-organic chemistry, high-resolution electrochemistry, electrogenerated chemiluminescence and photoelectrochemistry. Awards 1955 Ward Medal in Chemistry 1976 Analyst of the Year (Dallas Society of Analytical Chemistry) 1977 Sherman Mills Fairchild Scholar (California Institute of Technology) 1980 Harrison Howe Award (American Chemical Society, Rochester Section) 1981 Carl Wagner Memorial Award (Electrochemical Society) 1982 National Academy of Sciences 1983 City College of New York Alumni Scientific Achievement Award 1984 Bruno Breyer Memorial Award (Royal Australian Chem. -
Alumni Newsletter
ALUMNI NEWSLETTER lr II SCHOOL OF CHEMICAL SCIENCES I! UNIVERSITY OF ILLINOIS at Urbana-Champaign NO. 7, WINTER 1972-73 A Busy Week in June Seldom have so many worthy events been crowded into one week as have graced the people of the School of Chemical Sciences this June 9-15, 1972. Dr. H. E. Carter's portrait was hung in the Chemistry Library along with those of Parr, Noyes, and Adams; Dr. Philip Handler was honored at com mencement as a Distinguished Alumnus of the University; East Chemistry was dedicated as the Roger Adams Laboratory; and Alpha Chi Sigma held its Biennial National Conclave on our campus. Individually and in com bination these celebrations brought together in Urbana students, faculty, former faculty, alumni, distinguished guests, family, and friends from far corners. Roger Adams Laboratory Dedicated Several years ago, the Board of Trustees of the University ruled that campus buildings should have names that describe their function rather than names commemorating influential University people. Fortunately, however, the board modified this rule for a very special occasion last summer, and autho rized the changing of the name of East Chemistry Building to the Roger Adams Laboratory. The building was dedicated with this new name on Sun day, June 11, as the opening event of the Biennial National Conclave of the professional chemistry fraternity, Alpha Chi Sigma. Professor Gutowsky presided at the ceremony, introducing first Dr. J. W. Peltason, Chancellor of the Upiversity of Illinois at Urbana-Champaign, who paid tribute to Professor Adams and his work. Dr. Ernest Volwiler (Ph.D. -
Newsletter 2014-15
NEWSLETTER 2014-15 Special Features Listening to the Universe ADVANCED LIGO COULD PROVIDE BREAKTHROUGH DISCOVERY LaCNS $4.9M Grant Advanced LIGO, the upgrade to the LIGO detectors that will provide Nuclear Physics an increase by a factor of 1,000 in the number of gravitational wave Big Data candidates, was officially dedicated on July 31, 2015. LIGO, together Medical Physics with its sister interferometers VIRGO and GEO in Europe and the Magnetocaloric Research planned KAGRA facility in Japan and LIGO-India, will look for the Inside this Issue predicted signals from compact binary inspirals and mergers in neutron star and black hole systems, together with the stochastic Chair’s Corner 2 signal from the Big Bang and unanticipated bursts of gravitational Awards 3 waves from distant cosmic events. Cooperative arrangements have Events 3-5 been made with observers at wavelengths from radio to gamma rays Student Activities 5 LIGO-Livingston to look for counterparts. Both the Livingston and Hanford detectors Outreach 6-7 have achieved lock, and the first science run with Advanced LIGO is scheduled to begin in Research News 8-11 September. See www.ligo.caltech.edu/LA for more information about LIGO and its Livingston Lab. Accolades 12-15 Student Profiles 17 Alumni News 18 Summer REUs on Campus Support your Alma Mater 19 For the fifth summer, the department has hosted two Research Experiences for Undergraduates programs -- one in physics and a second, in cooperation with the Louisiana Alliance for Simulation-Guided Materials Applications For more info visit: (LaSIGMA) program and CCT, in computational materials. www.phys.lsu.edu The 2015 physics program brought 15 students to campus Or contact Mimi LaValle to work with faculty in astrophysics, particle and nuclear External Relations Manager 2015 P&A REU Participants and LSU Faculty physics, condensed matter, atomic physics, quantum [email protected] computing, and medical physics. -
Chemical Reactor Engineering*
CHEMICAL REACTOR ENGINEERING* JOHN B. BUTT mental topics, with more specialized applications Northwestern University in later chapters. Descriptive kinetics and data Evanston, IL 60201 interpretation are, logically, accorded first place on each list, followed by introductory material on E. E. PETERSEN reactor design and analysis. The latter is largely University of California limited to ideal reactor models; the effect of tem Berkeley, CA 94720 perature is treated somewhat differently in an organizational manner by the three authors, but HE DEVELOPMENT OF chemical reaction the level and extent of coverage is quite similar. Tengineering as an identifiable area within Concepts of selectivity as well as rate and conver chemical engineering has led to renewed interest sion are presented early in each case and main and emphasis on courses dealing with chemical tained as an important factor in kinetics and re reaction kinetics and chemical reactor design. The actor analysis throughout. Following this intro basic issues concerning instruction in these areas ductory material, each author then turns to prob are probably not much different from those in lems associated with deviations from ideal reactor volved in any other area of chemical engineering performance. Here somewhat more variation is insofar as fundamentals vs. appllcations, extent of apparent in organization and presentation but, coverage, and similar factors. There is, however, again, the net coverage and information is quite a chemical factor involved in this area that may similar. not appear quite so prominently in other endeav The point is that, in terms of information ors, and instruction at the undergraduate level which might form the core content of a typical particularly may be sensitive to the contents of current offerings in chemistry courses. -
BCAS Vol.31 No.1 2017
BCAS Vol.31 No.1 2017 14 Bulletin of the Chinese Academy of Sciences Vol.31 No.1 2017 Int’l Cooperation The CAS Award for International Scientific Cooperation (2007-2016): Happy Tenth Anniversary By XIN Ling (Staff Reporter) en years ago, in 2007, the Chinese Academy of Sciences gave out its first Award for International Scientific Cooperation to two distinguished foreign scientists: circulating Tfluidized bed expert Lothar Reh from the Swiss Federal Institute of Technology, and agricultural economist Scott Douglas Rozelle from Stanford University. Dr. Reh’s relationship with China started in the early 1970s, when he first visited the country to foster a cooperative link between the Lurgi Group and China. After that he worked with researchers from the CAS Institute of Process Engineering (IPE) for more than two decades. He not only helped with setting up the first research facilities at IPE, including the donation of a set of experimental equipment to Beijing in the name of the Swiss government, but also was instrumental in forging a strategic cooperative agreement between IPE and his institute. Dr. Rozelle’s collaboration with the CAS Institute of Geographical Sciences and Natural Resources began in 1995. Together with his Chinese coworkers, Dr. Rozelle extensively studied China’s agriculture and rural development, and his work on the country’s agricultural economics and policies greatly enhanced the world’s understanding of rural reform in China. One year later, both winners received the International S&T Cooperation Award and Friendship -
CHEMICAL REACTION ENGINEERING* Current Status and Future Directions
[eJij9iviews and opinions CHEMICAL REACTION ENGINEERING* Current Status and Future Directions M. P. DUDUKOVIC and petrochemical industry provided a fertile ground Washington University for further development of reaction engineering con St. Louis, MO 63130 cepts. The final cornerstone of this new discipline was laid in 1957 by the First Symposium on Chemical HEMICAL REACTIONS have been used by man Reaction Engineering [3] which brought together and C kind since time immemorial to produce useful synthesized the European point of view. The Amer products such as wine, metals, etc. Nevertheless, the ican and European schools of thought were not identi unifying principles that today we call chemical reac cal, but in time they converged into the subject matter tion engineering were not developed until relatively a that we know today as chemical reaction engineering, short time ago. During the decade of the 1940's (not or CRE. The above chronology led to the establish even half a century ago!) a transition was made from ment of CRE as an accepted discipline over the span descriptive industrial chemistry to the conceptual un of a decade and a half. This does not imply that all the ification of reaction processes and reactor types. The principles important in CRE were discovered then. pioneering work in this area of industrial practice was The foundation for CRE had already been established done by Denbigh [1] in England. Then in 1947, by the early work of Frank-Kamenteski, Damkohler, Hougen and Watson [2] published the first textbook Zeldovitch, etc., but at that time they represented in the U.S. -
April 17-19, 2018 the 2018 Franklin Institute Laureates the 2018 Franklin Institute AWARDS CONVOCATION APRIL 17–19, 2018
april 17-19, 2018 The 2018 Franklin Institute Laureates The 2018 Franklin Institute AWARDS CONVOCATION APRIL 17–19, 2018 Welcome to The Franklin Institute Awards, the a range of disciplines. The week culminates in a grand United States’ oldest comprehensive science and medaling ceremony, befitting the distinction of this technology awards program. Each year, the Institute historic awards program. celebrates extraordinary people who are shaping our In this convocation book, you will find a schedule of world through their groundbreaking achievements these events and biographies of our 2018 laureates. in science, engineering, and business. They stand as We invite you to read about each one and to attend modern-day exemplars of our namesake, Benjamin the events to learn even more. Unless noted otherwise, Franklin, whose impact as a statesman, scientist, all events are free, open to the public, and located in inventor, and humanitarian remains unmatched Philadelphia, Pennsylvania. in American history. Along with our laureates, we celebrate his legacy, which has fueled the Institute’s We hope this year’s remarkable class of laureates mission since its inception in 1824. sparks your curiosity as much as they have ours. We look forward to seeing you during The Franklin From sparking a gene editing revolution to saving Institute Awards Week. a technology giant, from making strides toward a unified theory to discovering the flow in everything, from finding clues to climate change deep in our forests to seeing the future in a terahertz wave, and from enabling us to unplug to connecting us with the III world, this year’s Franklin Institute laureates personify the trailblazing spirit so crucial to our future with its many challenges and opportunities. -
UC San Diego UC San Diego Electronic Theses and Dissertations
UC San Diego UC San Diego Electronic Theses and Dissertations Title The new prophet : Harold C. Urey, scientist, atheist, and defender of religion Permalink https://escholarship.org/uc/item/3j80v92j Author Shindell, Matthew Benjamin Publication Date 2011 Peer reviewed|Thesis/dissertation eScholarship.org Powered by the California Digital Library University of California UNIVERSITY OF CALIFORNIA, SAN DIEGO The New Prophet: Harold C. Urey, Scientist, Atheist, and Defender of Religion A dissertation submitted in partial satisfaction of the requirements for the degree Doctor of Philosophy in History (Science Studies) by Matthew Benjamin Shindell Committee in charge: Professor Naomi Oreskes, Chair Professor Robert Edelman Professor Martha Lampland Professor Charles Thorpe Professor Robert Westman 2011 Copyright Matthew Benjamin Shindell, 2011 All rights reserved. The Dissertation of Matthew Benjamin Shindell is approved, and it is acceptable in quality and form for publication on microfilm and electronically: ___________________________________________________________________ ___________________________________________________________________ ___________________________________________________________________ ___________________________________________________________________ ___________________________________________________________________ Chair University of California, San Diego 2011 iii TABLE OF CONTENTS Signature Page……………………………………………………………………...... iii Table of Contents……………………………………………………………………. iv Acknowledgements…………………………………………………………………. -
Simulation of HDS Tests in Trickle-Bed Reactor
Simulation of HDS Tests in Trickle-Bed Reactor V. Tukač1, A. Prokešová1, J. Hanika1, M. Zbuzek2 and R. Černý2 1Institute of Chemical Technology, Prague, Technická 5, CZ-16628 Prague, Czech Rebublic 2Research and education centre UniCRE Litvínov, CZ-43670 Litvínov, Czech Rebublic Keywords: Hydrodesulfurization Simulation, Catalyst Tests, Trickle-Bed Reactor. Abstract: The paper deals with methodology of simulation study devoted to evaluation of reliability of HDS catalyst testing procedure in pilot three phase fixed bed reactor. Hydrodynamic behaviour of test reactor was determined by residence time distribution method. Residence time and Peclet number of axial dispersion of liquid phase were obtained by nonlinear regression of experimental data. Hydrodesulfurization reaction kinetics was evaluated by analysis of concentration data measured in high pressure trickle-bed reactor and autoclave. Simulation of reaction courses were carried out both by pseudohomogeneous model of ODE in Matlab and heterogeneous reactor model of PDE solved by COMSOL Multiphysics. Final results confirm presumption of eliminating influence of hydrodynamics on reaction kinetic results by dilution of catalyst bed by inert fine particles. 1 INTRODUCTION were supplemented by kinetic measurement of reaction rate constants and activation energies of Sustainable development demands ultra-low selected sulfuric compounds. Parallel to HDS concentrations of sulfur and nitrogen compounds in reaction also hydrodenitrogenation (HDN) takes produced engine fuels – gasoline and diesel. Present place in the catalytic reactor. Hydrodynamic data sulfur content valid in EU 10 ppm represents less were evaluated by residence time distribution (RTD) than one thousands of sulfur content of original method in laboratory glass model of pilot reactor. crude oil. Deep hydrodesulfurization (HDS) of Mathematical models of the process (Ancheyta, engine fuels is dominantly carried out in catalytic 2011) were formulated both like 1D trickle-bed reactors. -
Cv Mlhg 2015
CURRICULUM VITAE Name: GREEN, Malcolm Leslie Hodder Address: St Catherine's College, Oxford or Inorganic Chemistry Laboratory South Parks Road OXFORD, OX1 3QR Date of Birth: 16/4/36, Eastleigh, Hampshire Nationality: British Marital Status: Married. Three children Degrees: B.Sc.(Hons), London; D.I.C., M.A.(Cantab), M.A.(Oxon), C.Chem., F.R.S.C., Ph.D., F.R.S. ACADEMIC CAREER 1953-56 Acton Technical College, University of London, B.Sc Hons. Chemistry 1956-59 Imperial College of Science and Technology, London; D.I.C. Ph.D. in chemistry. Supervisor Professor Sir G. Wilkinson 1959-60 Post-doctoral Research Associates Fellow. Imperial College of Science and Technology 1960-63 Assistant Lecturer in Inorganic Chemistry at Cambridge University 1961 Fellow of Corpus Christi College, Cambridge 1963 Sepcentenary Fellow of Inorganic Chemistry, Balliol College, Oxford and Departmental Demonstrator, University of Oxford 1965 University Lecturer, University of Oxford 1971 Visiting Professor, University of Western Ontario (Spring Term) 1972 Visiting Professor, Ecole de Chimie and Institute des Substances Naturelles, Paris (six months) 1973 A.P. Sloan Visiting Professor, Harvard University, (Spring Semester) 1979-84 Appointed to the British Gas Royal Society Senior Research Fellowship 1981 Sherman Fairchild Visiting Scholar at the California Institute of Technology(4 months) 1984 Re-appointed British Gas Royal Society Senior Research Fellow (1984-6) 1987 Vice-master, Balliol College, Oxford (T.T.) 1989 Appointed Professor of Inorganic Chemistry and Head of Department, Oxford University Fellow of St Catherine's College, Oxford 2004- present Emeritus Research Professor in the Inorganic Chemistry Laboratory, Oxford University Emeritus Fellow of Balliol College and St Catherine’s College Publications Two text books, 646 refereed papers and 8 patents. -
Supplementary Figure 1: Interconnected Multiplex with Six Nodes in Two Layers (A and D) and Corresponding Aggregated Networks (B and E)
Supplementary Figure 1: Interconnected multiplex with six nodes in two layers (A and D) and corresponding aggregated networks (B and E). The nodes are ranked by their eigenvector centrality in each layer separately, in the aggregated and in the whole interconnected structure (C and F). Case A, B and C. Nodes 1 and 3 have a key role in the multilayer, being bridges between the two layers. In a collaboration network they would represent scientists working on two different research areas who allow information to flow from one subject to the other. While nodes 1 and 3 gain centrality from their connections to \hubs" on different layers, they also gain centrality from their own counterparts in other layers, making them important in the multilayer network. In the aggregated network their versatility disappears, because the information is washed out by projecting on a single layer, where nodes 2 and 6 are still \hubs" but it is not possible to capture the importance of nodes 1 and 3 in bridging different areas. Case D, E and F. This example shows how aggregating the full information on a single network introduces a spurious symmetry between nodes 2, 3, 4 and 6 that is not present in the multilayer, except for 2 and 4. The resulting score in the aggregate is not able to capture the difference between these nodes (corresponding to a degeneration in the eigenspace) while it is evident that, for instance, node 6 is more central than node 3 because of its direct connection to node 1 { the \hub" { in layer 1. -
Communications-Mathematics and Applied Mathematics/Download/8110
A Mathematician's Journey to the Edge of the Universe "The only true wisdom is in knowing you know nothing." ― Socrates Manjunath.R #16/1, 8th Main Road, Shivanagar, Rajajinagar, Bangalore560010, Karnataka, India *Corresponding Author Email: [email protected] *Website: http://www.myw3schools.com/ A Mathematician's Journey to the Edge of the Universe What’s the Ultimate Question? Since the dawn of the history of science from Copernicus (who took the details of Ptolemy, and found a way to look at the same construction from a slightly different perspective and discover that the Earth is not the center of the universe) and Galileo to the present, we (a hoard of talking monkeys who's consciousness is from a collection of connected neurons − hammering away on typewriters and by pure chance eventually ranging the values for the (fundamental) numbers that would allow the development of any form of intelligent life) have gazed at the stars and attempted to chart the heavens and still discovering the fundamental laws of nature often get asked: What is Dark Matter? ... What is Dark Energy? ... What Came Before the Big Bang? ... What's Inside a Black Hole? ... Will the universe continue expanding? Will it just stop or even begin to contract? Are We Alone? Beginning at Stonehenge and ending with the current crisis in String Theory, the story of this eternal question to uncover the mysteries of the universe describes a narrative that includes some of the greatest discoveries of all time and leading personalities, including Aristotle, Johannes Kepler, and Isaac Newton, and the rise to the modern era of Einstein, Eddington, and Hawking.