61. SRI - PSD's Chemistry & Engineering Processes Research And Development bioassays, energyrelated materials and airbag compounds as well as advancesin process engineering, carbon materials, and environmental fuel processing. http://www.sri.com/psd/chemeng/

Physical Sciences Division Poulter Laboratory - Applied Mechanics Applied Physical Sciences Laboratory Chemical and ... Technologies for License Chemical and Engineering Processes Laboratory Fluorescent Dyes Clients working with our Chemical and Engineering Processes Laboratory tap the expertise of biologists, chemists, physicists, and engineers focused on biosensors, bioassays, energy-related materials and airbag compounds as well as advances in process engineering, carbon materials, and environmental fuel processing. We offer clients the technical expertise and business insights needed for moving forward. Discover more about our: Innovative Technologies Facilities , and IP Portfolio Innovative Technologies SRI's Chemical and Engineering Processes Laboratory has spearheaded development of a wide range of innovative new technologies and techniques: Airbag Technology Our patented, environmentally benign igniter compound, containing only CHNO, can replace the heavy metal or zinc-based igniters used in most of today's airbags or inflators. SRI also patented a new class of oxidizers for use in airbag production that will boost performance of inexpensive ingredients such as ammonium nitrate. When used independently in the presence of a fuel, it provides both performance and manufacturing benefits. (US Patent No. 5,889,161) Biosensor Technology Our coating and functional protocols use a proprietary SRI luminescent reporter. The result, lower nonspecific binding and high specific binding for use in a variety of biosensor formats.

62. Bristol University: Undergraduate Prospectus - Mechanical Engineering - Introduc of materials; Environmental Thermodynamics; process engineering; process Operations;Product Design; Design and Nature; Innovation and Enterprise http://www.bris.ac.uk/prospectus/undergraduate/2006/sections/ENGF/MECH/dept_intr

skip menus prospectus home contacts how to apply ... a-z of programmmes MECHANICAL ENGINEERING Programme Specifications Programme Structures Departmental Home Page Prospectus search ... Engineering Mechanical Engineering Mechanical Engineering Research Rating: 5 Introduction The Department of Mechanical Engineering at the University of Bristol is a medium-sized department with 20 lecturing staff and an intake of around 70 undergraduates per year. The Department is consistently ranked in the top five of university mechanical engineering departments by The Guardian and The Sunday Times . Our teaching and research have both been recognised as excellent. Currently our research work covers such diverse topics as advanced materials for aero-engines, adaptive control systems theory and energy studies in power stations. While they are with us, our students have the opportunity of working with us in these areas. Programme Listing UCAS code Duration Applications Places Note MEng Mechanical Engineering BEng Mechanical Engineering MEng Mechanical Engineering with Study in Continental Europe (Mechanical Engineering with Study Abroad - entry by transfer from H300 or H301) Programme Structure The first two years are common to all students, whichever programme of study they are following. Teaching is based upon four main themes: Design, Dynamics, Materials and Thermodynamics and Fluid Mechanics. Language studies are an option offered to everybody and business studies also feature. Lectures in the four main themes of study continue in the final two years at an advanced level. At the end of your third, year you will be asked to select the courses you wish to study in your fourth year from a list of options.

63. Chemical Engineering - Wikipedia, The Free Encyclopedia Following is an example that illustrates the process engineering part of These products include high performance materials needed for aerospace, http://en.wikipedia.org/wiki/Chemical_engineering

Chemical engineering From Wikipedia, the free encyclopedia. Chemical engineering is the application of science mathematics and economics to the process of converting raw materials or chemicals into more useful or valuable forms. Chemical Engineering largely involves the design and maintenance of chemical processes for large-scale manufacture. Chemical engineers in this branch are usually employed under the title of process engineer . Following is an example that illustrates the process engineering part of chemical engineering: The individual processes used by chemical engineers (eg. distillation or chlorination ) are called unit operations and consist of chemical reaction mass- heat- and momentum- transfer operations. Unit operations are grouped together in various configurations for the purpose of chemical synthesis and/or chemical separation . Not all real processes, such as reactive distillation , are simple unit operations, but consist of intertwined transport and separation processes. Three primary physical laws underlying chemical engineering design are Conservation of mass Conservation of momentum and Conservation of energy . The movement of mass and energy around a chemical process are evaluated using Mass balances and energy balances which apply these laws to whole plants, unit operations or discrete parts of equipment. In doing so, Chemical Engineers use principles of

64. Department Of Materials-process Engineering And Applied Chemistry For Environmen 1) Division of materialsprocess engineering 2) Division of materials engineeringfor Resource and Environment 3) Division of Molecular Functional Chemistry http://www.eng.akita-u.ac.jp/main/eng/gp/gp_dmeace.htm

Department of Materials-process Engineering and Applied Chemistry for Environments The courses offered in the department cover a wide range of science and engineering relevant to development, regeneration and application of new functional materials, the effective utilization of chemical energy, and the utilization of bio-systems. It includes fundamentals and wide range of the application of the chemistry, resources engineering and the physics related to the materials. We aim at the development of new advanced technologies, which are in harmony with the environment. For the realization, the four divisions are provided for becoming a searchlight of technology creation which the age requests and for training sharpened engineer in each research field. 1) Division of Materials-process Engineering 2) Division of Materials Engineering for Resource and Environment 3) Division of Molecular Functional Chemistry 4) Division of Chemical Systems Experiment on the decomposition of hazardous chemicals by the use of microorganism.

65. Department Of Advanced Materials Engineering Advanced processing of Improved materials with Welding Technology and Surface Environmental Chemical process engineering, Advanced Topics Focusing on http://www.eng.akita-u.ac.jp/main/eng/gp/gp_damme.htm

Department of Advanced Materials Engineering Substances or materials play an essential part in modern technology. Progress of science and technology heavily depends on the wide variety of functions of materials and the proper choice of routes by which new substances are processed. An ability to integrate various strands of knowledge with keen creativity is vital for the future development of materials engineering. Fundamental knowledge also remains important in each specific area of metallic engineering, industrial inorganic chemistry, synthetic organic chemistry, and chemical engineering. It is necessary to understand and control the macroscopic properties and functions of a material from a microscopic interpretation based on elementary constituents such as molecules, atoms, ions, and electrons, with their bonds and associated structures. The present department course is composed of two divisions: Division of Advanced Materials Engineering and the Division of Environmental Chemistry and Chemical Engineering. The course encourages students to study integrated concepts from fundamentals to applications concerning advanced materials engineering, namely; physical properties and chemical activities, production processes, and analysis / synthesis of new functional materials. The final goal is to educate students to outstandingly become researchers and engineers responsible for the future materials-engineering world.

66. Semiconductor Materials One area of materials engineering is called process engineering . It is perhapsbest illustrated by the production of integrated circuit devices. http://www.engr.sjsu.edu/WofMatE/Semiconductors.htm

Exploring Materials Engineering Semiconductor Materials Whereas polymers are highly visible engineering materials with a major impact on contemporary society, semiconductors are relatively invisible but have a comparable social impact. Technology has clearly revolutionized society, but solid-state electronics is revolutionizing technology itself. A relatively small group of elements and compounds has an important electrical property, semi-conduction , in which they are neither good electrical conductors nor good electrical insulators. Instead, their ability to conduct electricity is intermediate. These materials are called semiconductors , and in general, they do not fit into any of the four structural materials categories based on atomic bonding. Metals are inherently good electrical conductors. Ceramics and polymers (non-metals) are generally poor conductors but good insulators. The three semiconducting elements (Si, Ge, and Sn) from column IVA of the periodic table serve as a kind of boundary between metallic and nonmetallic elements. Silicon (Si) and germanium (Ge), widely used elemental semiconductors, are excellent examples of this class of materials. [Another important semiconductor material is GaAs, a compound of the group IIIA element Ga; and the group V element, As.] Taken from Introduction to Materials Science for Engineers , James F. Shackelford

67. VDI - VDI Society For Chemical And Process Engineering The GVC handles questions on chemical and process engineering in the overallareas of science and technology, industry and Solid materials processing http://www.vdi.de/vdi/english/organisation/schnellauswahl/fgkf/gvc/04802/index.p

VDI Society for Chemical and Process Engineering VDI Technical Divisions VDI Society for Chemical and Process Engineering (GVC) The organization for engineers in the field of chemical and process engineering and their colleagues in related fields is the VDI Society for Chemical and Process Engineering (GVC). It handles all technical and professional aspects of this specialist branch of engineering. Today process engineering is represented as an independent study programme (or at least an intensifying course in the mechanical engineering programme) at a large number of technical colleges and universities in Germany. The GVC handles questions on chemical and process engineering in the overall areas of science and technology, industry and public life. Historical Development of the GVC The GVC was originally the "Working Group for Consumer Products Technology", and was founded in 1934 with Prof. Dr. phil. Dr. -Ing. E.h. Arnold Eucken as first Chairman. The group was renamed several times: 1938 - "Technical Committee Process Engineering", 1953 - "Technical Group Process Engineering", and 1960 - "Society for Process Engineering in the VDI (VTG)". The restructuring of the VDI into societies and the wide-reaching similarities between chemical and process engineering gave rise to the name being changed yet again to the "VDI Society for Chemical and Process Engineering" in March 1974. In the course of this restructuring process, the VDI technical group "Food Engineering" also joined the GVC in 1975.

68. Predictive Process Engineering Program - Manufacturing Systems Integration Divis Predictive process engineering. Program Manager Kevin Jurrens The absenceof materials characterization data and an appropriate materials model http://www.mel.nist.gov/msid/ppe.htm

Predictive Process Engineering Program Manager: Kevin Jurrens Total FTE: 7.14 Goal: By 2005, to support the industry need for first part correct manufacturing, establish an industry-accepted and widely adopted integration framework for sharing predictive knowledge about machining processes and resources with engineering and control systems using a standard semantic-based process representation and validated physics-based models for milling and turning. Program Projects (2002): Design/Process Planning Integration (DPPI) Incorporate Process Models into Adaptive Control Lapping and Polishing Materials Data and Metrology for Machining Simulation Process Specification Language (PSL Needs Addressed: A second barrier to reducing manufacturing process inefficiencies is the lack of simple mechanisms to enable exchange of process information among manufacturing systems. Market analysts at Gartner Group Inc. estimate the costs associated with the exchange of process information among manufacturing applications in U.S. industry at approximately $2 billion per year. Through the availability of standards and methodologies to provide a rigorous foundation for representation, exchange, and integration of process-related data, an estimated 15 % to 20 % cost reduction could be achieved, which translates into a savings of $300 million to $400 million per year. U.S. manufacturers and industry groups identified these problem areas through numerous public forums and publications. In particular, the 1998 Integrated Manufacturing Technology Roadmap (IMTR) identified a number of industry priorities and critical capabilities that provide direct support for this program. Specifically, the IMTR identifies science-based manufacturing, first part correct, intelligent process advisors, and robust process models as key industry needs.

69. Journal Of Manufacturing Processes: Composites Manufacturing: Materials, Product Composites Manufacturing materials, Products, and process engineering. Journal ofManufacturing processes, 2002. new. Save a personal copy of this article http://www.findarticles.com/p/articles/mi_qa3963/is_200201/ai_n9058962

@import url(/css/us/style1.css); @import url(/css/us/searchResult1.css); @import url(/css/us/articles.css); @import url(/css/us/artHome1.css); Home Advanced Search IN free articles only all articles this publication Automotive Sports FindArticles Journal of Manufacturing Processes Content provided in partnership with 10,000,000 articles Not found on any other search engine. Featured Titles for Academy of Marketing Science Review Accounting Historians Journal, The Accounting History AgExporter ... View all titles in this topic Hot New Articles by Topic Automotive Sports Top Articles Ever by Topic Automotive Sports Composites Manufacturing: Materials, Products, and Process Engineering Journal of Manufacturing Processes Save a personal copy of this article and quickly find it again with Furl.net. It's free! Save it. Composites Manufacturing: Materials, Product, and Process Engineering Sanjay K. Mazumdar, author (C)2001 CRC Press, hardcover, 416 pp., $99.95 ISBN: 0849305853 More and more companies manufacture reinforced composite products. To meet the market need, researchers and industries are developing manufacturing methods without a reference that thoroughly covers the manufacturing guidelines. This book presents a fundamental classification of processes, where a process fits within the overall scheme, and which process is best suited for a particular component. Continue article Advertisement Save Print Send Link ... Subscribe IN free articles only all articles this publication Automotive Sports About Us Terms of Service Advertise with Us LookSmart Solutions:

70. Process Engineering: Green Materials: Stuart Nathan Looks At Some Of The Advance Access the article, Green materials Stuart Nathan looks at some of the advancesin processing techniques which are making polymer production more http://www.findarticles.com/p/articles/mi_go2602/is_200306/ai_n9096363

@import url(/css/us/style1.css); @import url(/css/us/searchResult1.css); @import url(/css/us/articles.css); @import url(/css/us/artHome1.css); Home Advanced Search IN free articles only all articles this publication Automotive Sports FindArticles Process Engineering June 2003 Content provided in partnership with 10,000,000 articles Not found on any other search engine. Featured Titles for AI Magazine Advanced Battery Technology America's Network BT Catalyst ... View all titles in this topic Hot New Articles by Topic Automotive Sports Top Articles Ever by Topic Automotive Sports Save a personal copy of any page on the Web and quickly find it again with Furl.net. It's free. Get started now. Green materials: Stuart Nathan looks at some of the advances in processing techniques which are making polymer production more environmentally friendly. (Environment). Process Engineering June, 2003 by Stuart Nathan Plastics manufacturers are increasingly concerned with improving their environmental performance. Generally, their improvements are similar to those seen elsewhere in the process industries use less power, produce less waste, substitute harmful and hazardous materials for more innocuous alternatives where possible. However, some plastics makers and polymer scientists are taking a different approach. One aspect of environmentally friendly production is concerned with making sure that the plastic is easy to recycle, with minimal processing needed to return used materials to a virgin state, or as near as possible.

71. Journals - Professional Engineering Publishing, Magazines And On-line Engineerin JOURNAL OF process MECHANICAL engineering PART E The whole range of materialsengineering and technology is addressed, including metallic materials, http://www.pepublishing.com/frm_journal.asp

var SessionId = "E1FDADEE-8FF3-42A3-980A-FFB80C86A4E5"; INTERNATIONAL JOURNAL OF ENGINE RESEARCH JOURNAL OF STRAIN ANALYSIS FOR ENGINEERING DESIGN THE IMAGING SCIENCE JOURNAL PROCEEDINGS OF THE INSTITUTION OF MECHANICAL ENGINEER JOURNAL OF POWER AND ENERGY - PART A JOURNAL OF ENGINEERING MANUFACTURE - PART B JOURNAL OF MECHANICAL ENGINEERING SCIENCE - PART C JOURNAL OF AUTOMOBILE ENGINEERING - PART D JOURNAL OF PROCESS MECHANICAL ENGINEERING - PART E Editor: G L Quarini, University of Bristol, UK Subscription Information: 2001, Volume 215 (4 issues): £264.00 The Journal of Process Mechanical Engineering is a quarterly publication for engineers in industry and academe who are concerned with the process industries. The Journal publishes high-quality papers covering a broad area of mechanical engineering activities associated with the design and operation of process equipment. The impact of design on the overall characteristics of the industrial undertaking including maintainability, reliability, sustainability and waste management will remain an important feature of the Journal. The topics covered include: Design; pressure vessels and piping; equipment and components; ventilation and refrigeration; instrumentation and condition monitoring; process applications of thermodynamics and fluid mechanics; maintainability and reliability; hazard analysis; waste management and containment. JOURNAL OF RAIL AND RAPID TRANSIT - PART F JOURNAL OF AEROSPACE ENGINEERING - PART G JOURNAL OF ENGINEERING IN MEDICINE - PART H

72. Rapra Bookstore Dictionary of materials and process engineering, English–German. Hanser, 1995.By CG Goetzel and LK Goetzel. The quality of a dictionary may be judged by http://www.rapra.net/bookstore/static/g3.asp

Search by Subject Materials Products and Applications Manufacturing and Processing Properties, Analysis and Testing Environment and Health General Subscription Journals Rapra Review Reports Rapra Published Searches Dictionary of Materials and Process Engineering, English–German Hanser, 1995 By C.G. Goetzel and L.K. Goetzel The quality of a dictionary may be judged by its value as a helpful tool for professional use. The more complete its store of specific expressions, the more comprehensive is the information that it provides. A meaningful understanding of a foreign language text is helped if the terms of the dictionary extend to more general terminology. The authors, Professor Claus G Goetzel and Mrs Lilo K Goetzel, have been guided by this concept in the work at hand. They have succeeded in creating a dictionary of excellent quality. It encompasses a broad scope of materials, starting with metals, ceramics, and polymers to alloys and composites and includes their genesis, processing and application. Both authors have been working for decades as translators of technical books and reports as well as of articles for scientific and technical journals, with emphasis placed on the areas of powder metallurgy, metallography, development of new materials for aerospace applications as well as general materials science. Over the years a substantial number of technical terms was accumulated, with the collection initially intended for the authors’ personal use in their work. But it became apparent that with a thorough reworking the voluminous accumulation of terms could be of great benefit to the technical profession at large. An especially valuable feature of this book is the effort to interrelate the true sense of the individual terms with actual usage in both languages, German and English. The inclusion of important new terms and the carefully targeted explanations relative to their specific meaning does justice to the continuing expansion of the technical vocabulary.

73. Rapra Bookstore Dictionary of materials and process engineering, GermanEnglish. Hanser, 1997.By CG Goetzel and LK Goetzel. The quality of a dictionary may be judged by http://www.rapra.net/bookstore/static/g6.asp

Search by Subject Materials Products and Applications Manufacturing and Processing Properties, Analysis and Testing Environment and Health General Subscription Journals Rapra Review Reports Rapra Published Searches Dictionary of Materials and Process Engineering, German-English Hanser, 1997 By C.G Goetzel and L.K. Goetzel The quality of a dictionary may be judged by its value as a helpful tool for professional use. The more complete its store of specific expressions, the more comprehensive is the information that it provides. A meaningful understanding of a foreign language text is helped if the terms of the dictionary extend to more general terminology. The authors, Professor Claus G Goetzel and Mrs Lilo K Goetzel, have been guided by this concept in the work at hand. They have succeeded in creating a dictionary of excellent quality. It encompasses a broad scope of materials, starting with metals, ceramics, and polymers to alloys and composites and includes their genesis, processing and application. Both authors have been working for decades as translators of technical books and reports as well as of articles for scientific and technical journals, with emphasis placed on the areas of powder metallurgy, metallography, development of new materials for aerospace applications as well as general materials science. Over the years a substantial number of technical terms was accumulated, with the collection initially intended for the authors’ personal use in their work. But it became apparent that with a thorough reworking the voluminous accumulation of terms could be of great benefit to the technical profession at large. An especially valuable feature of this book is the effort to interrelate the true sense of the individual terms with actual usage in both languages, German and English. The inclusion of important new terms and the carefully targeted explanations relative to their specific meaning does justice to the continuing expansion of the technical vocabulary.

74. Materials Process Engineering Chair materials process engineering Chair. Preparation and processing are aiming atthe new functional materials of metals and ceramics on the basis of physical http://www.muroran-it.ac.jp/mat/cgi/index.cgi?mode=chair&cid=1&lang=en

75. Materials Ireland: Process Development Potentially any industrial sector that processes materials in their manufacture can materials Technology; process engineering; Manufacturing engineering http://www.ul.ie/~mirc/services/process.htm

Process Development The Materials Ireland Research Centre, University of Limerick offers a range of engineering services to the industrial sector. One such service is the capability to assist with new process development in the area of materials manufacture or improvement of existing manufacturing processes. The process development service includes process research and innovation, scale-up, design, construction and operation of pilot plant or laboratory units, technology transfer and optimisation of manufacturing processes. The process development service offered by the MIRC-UL applies across the complete range of materials including metals, ceramics, glass, polymers, adhesives and composites. Potentially any industrial sector that processes materials in their manufacture can benefit from the service: Ceramics and Glass industriesMedical Devices and Healthcare Automotive Aerospace Minerals Processing Chemical Processing Electronics Pharmaceuticals Metallurgical Coatings Materials Technology Process Engineering Manufacturing Engineering Examples of how we have helped companies can be found through many of the projects illustrated

76. UD School Of Engineering - Chemical Engineering - SAMPE series featuring speakers in the materials and process engineering fields.Because material and process fields consist of so many different aspects of http://engineering.udayton.edu/programs/chemical/opportunities_sampe.asp

ABOUT THE DEPARTMENT ACADEMICS OPPORTUNITIES FACULTY AND STAFF ... Department Home SAMPE The goal of the University of Dayton student chapter of Society for the Advancement of Material and Process Engineering (SAMPE) is to provide an organization for students in the materials and processing related fields to exchange ideas and interact with the professional field. The UD chapter of SAMPE coordinates facilities tours of local industries and organizes a seminar series featuring speakers in the materials and process engineering fields. Because material and process fields consist of so many different aspects of engineering, students from all departments are invited to become members and participate in activities held by the organization. Membership in SAMPE includes a subscription to SAMPE Journal, a bi-monthly publication that includes technical articles, industry and international technical news, product and new literature announcements, book reviews, technical events calendars, and local SAMPE information. To obtain a registration form online, visit SAMPE For more information on SAMPE, contact 2004-05 student chapter president

77. Laboratory For Energy And Materials Cycles Paul Scherrer Institut, PSI Laboratory for Energy and materials Cycles The Thermal process engineering group (TPE) is developing new alternative http://lem.web.psi.ch/TPE/tpe.html

78. Materials Science And Engineering The Department of materials Science and engineering offers the following Society for the Advancement of materials and process engineering (SAMPE). http://www.washington.edu/students/gencat/academic/material_sci.html

Search Directories Reference Tools UW Home ... Degree Programs Materials Science and Engineering 302 Roberts Materials science and engineering is an interdisciplinary field that addresses the structure, processing, and property relationships in materials for engineering applications. Basic principles of chemistry and physics are applied to provide an understanding of the structure of materials and the manner in which the structure determines the properties. Scientific processing methods are then applied to yield the necessary properties, which then can be integrated with, and designed to accommodate the needs of, modern technology. Advances in materials enable technological progress in many fields. Historically, this connection between materials and technology has been so intimate that major periods in civilization have been named after the dominant material used in that era (e.g., Bronze Age, Iron Age). In the past few decades, at the core of the progress in such diverse fields as transportation, communication, electronics, energy and environment are significant advances in materials. Materials science and engineering is a broad and growing discipline. Materials Science and Engineering at the University of Washington has recently experienced rapid expansion into new research areas, including polymers, hybrids, biomaterials, biomimetics, nanomaterials, photonic and magnetic materials. These areas have applications in current and emerging industries, and complement existing strength in ceramics, metals, electronic materials, and composites.

79. Process Engineering & Manufacturing | Chemical Processing Magazine Information on a range of chemical engineering topics, from manufacturing andautomation Dielectric constants of more than 200 materials are included. http://www.chemicalprocessing.com/

login register Search this site Friday, September 23, 2005 HOME WHITE PAPERS Fluid Handling Security ... E-mail Newsletter Resource Centers Software Control Systems Instrumentation Simulation ... Filtration Site Resources Newsletters Current Issue Issue Archive Events Calendar ... Inquire On-line Voices Rosenzweig Dierking Spear Compliance Adviser ... Plant InSites Poll Your browser does not support iframes. Iframes are required in order to participate in the poll. Leveraging automation to maximize boiler efficiencies ChemicalProcessing.com As a boiler ages, it will have reduced reliability, higher maintenance costs and lower performance. A control system upgrade can provide important benefits. Smaller, smarter systems streamline sampling ChemicalProcessing.com An emerging miniaturized, modular approach for sampling systems provides substantial savings in both capital and operating costs. EPA pushes material-management challenges ChemicalProcessing.com The agency is striving to increase cooperative projects with industry to conserve resources. Site Highlights: Editor's top picks Top 10 white paper downloads These are the 10 most downloaded white papers from our web site. See what your peers are reading.

80. Engineering Conferences International Professor Ken Marsh, Dept. of Chemical and process engineering, University of Professor John Chen, Department of Chemical and materials engineering, http://www.engconfintl.org/6apbody.html

General Announcement and Call for Abstracts Deadline extended to September 19, 2005 Process Intensification and Process Innovation - (PI) II Cleaner, Sustainable, Efficient Technologies for the Future September 24-29, 2006 Christchurch, New Zealand About this conference Keynote Speakers The proposed conference will focus on the following areas of intensification with an invited keynote speaker for each area Bioprocessing and intensification - Dr Roshan Jachuk Reaction and Separation - Professor Andrew Livingston , Department of Chemical Engineering and Chemical Technology, Imperial College, London, England Novel Reactors - Professor Xiong-Wei Ni , COBRA, Department of Chemical Engineering, Heriot Watt Univeristy, Edinburgh, Scotland Materials - Professor Ken Seddon , QUILL, Queens University of Belfast, Northern Ireland AIChE is a technical co-sponsor of this conference. Related Conference CHEMECA 2006 17 - 21 September 2006, Auckland, New Zealand Conference Chairs Dr. Laurence Weatherley , Dept. of Chemical and Petroleum Engineering, The University of Kansas, USA (Tel: +1-785-864-3553, Fax: +1-785-864-4967, E-mail: lweather@ku.edu

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