| Research Domain:microstructured materials (polymers, ceramics and composites) |
Country:[CN] |
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" The field of microstructured materials (polymers, ceramics and composites) is one recognized by the National Research Council as a research frontier for chemical engineers. The chemical engineer, with training in chemistry, reaction engineering, transport phenomena, and thermodynamics, is ideally suited to make major contributions in brining new technologies for the manufacture of advanced materials to the marketplace. Our research interests in advanced materials focus primarily on the relationship between processing and structure in polymeric materials and composites. " |
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| Research Domain:chemical engineering |
Country:[CN] |
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for the development of the metathesis method in organic synthesis. |
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| Research Domain:chemical engineering, chemical products, patent infringement, hazardous materials and environmental technology. |
Country:[CN] |
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Dr. Funk has over 20 years experience in R&D, chemicals, and advanced engineering with Exxon and Honeywell. He is the author of 6 patents and 70 technical publications. He has a BS in Engineering Science from Yale and a PhD in Chemical Engineering from University of California, Berkeley. Since 1992 Dr. Funk is a Visiting Professorship of Chemical Engineering at University of Illinois. |
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| Research Domain:experimental |
Country:[CN] |
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" Almost all engineering processes involve the transport of material across an interface. These interfacial regions are characterized by changes of composition or density over length scales comparable to molecular dimensions. Similarly, the composition and structure of a single phase can vary markedly over small distances. Examples are liquid crystals, microemulsions and micelles, some polymeric solutions, vesicles, emulsions, and protein dispersions. The physical properties of such complex fluids make them useful in a multitude of applications. The best use of these materials, however, requires knowledge of the arrangement of the material structure on a molecular scale. With the goal of developing such an understanding, we are studying several microemulsions, micelles, and vesicular dispersions as well as concentrated colloidal suspensions. The main focus of our work is experimental, but substantial theoretical and computational efforts are also underway. " |
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| Research Domain:The structure, rheology and phase behavior of complex fluids |
Country:[CN] |
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" Our research interests lie at the intersection of three major themes: The structure, rheology and phase behavior of complex fluids, such as colloidal and biopolymer systems; Cellular mechanics and movement, including cell rheology and the behavior of cytoskeletal biopolymers and structures; and Interfacial phenomena as they relate to understanding and controlling colloidal interactions and stability. In each of these areas, macroscopic response is strongly influenced by the intimate relationship between microscopic structure, interactions, dynamics and mechanics. By applying new tools based on single-polymer visualization, microrheology and optical trapping, we have an unprecedented ability to guide the assembly, deform structures, measure stress and study dynamics at a microscopic scale to better understand and control material and biological properties and responses. " |
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| Research Domain:Systems Biology and Engineering |
Country:[CN] |
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" Our current research in “Systems Biology and Engineering” is built on two decades of accomplishments in biotechnology and the application of knowledge-based expert systems for process fault diagnosis. In biotechnology, our research has resulted in a better understanding of microscopic and macroscopic variables that influence the kinetics of genetically engineered microorganisms. We have investigated different promoters, specialized ribosome systems, microbial hosts, and bioreactor conditions, for the improved production of active proteins. We have collaborated with the Pasteur Institute in Paris to examine the effects of gene sequence on inclusion body formation and also collaborated with DuPont to construct genetically engineered cells that emit light when exposed to pollutants.
A second area of major research contributions is in the application of knowledge-based expert systems for on-line fault diagnosis. In a joint project with Foxboro and DuPont, our research group pioneered the first industrial application of an expert system (FALCON), for fault diagnosis in a commercial-scale process. Dynamic simulations and the integration of qualitative domain knowledge with quantitative knowledge from mathematical models were central to this project. A common underlying theme in our work in both biotechnology and fault diagnosis has been the use of dynamic mathematical models, qualitative and quantitative domain knowledge, and artificial intelligence approaches for data interpretation and knowledge integration.
The introduction of a gene into an organism perturbs it at many levels of cellular hierarchy. Genomic, Transcriptomic, Proteomic and Metabolic data provide insight into the regulatory and metabolic effects of such gene manipulations at the whole cell level. Our current research combines modeling approaches with knowledge-based data analysis strategies to convert the massive amounts of such bioinformatic data into knowledge. " |
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| Research Domain:electrochemistry,rusty and preserve,electrochemical power source |
Country:[CN] |
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曹楚南(Cao Chunan)
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1930年8月出生,江蘇常熟人。 52年畢業上海同濟大學化學系 52年分配在上海物理化學研究所工作 1953年調至中國科學院長春應用化學研究所工作, 82年晉升為研究員 86年調至中國科學院金屬腐蝕與防護研究所任研究員 90年批準為博士生導師 94年調至浙江大學化學系任教 95年5月轉聘為教授 91年當選為中國科學院學部委員(院士)現任中國腐蝕與防護學會理事長,腐蝕電化學專業委員會名譽主任,中國化學會電化學委員會副主任。
研究領域: 電化學, 腐蝕與防護, 化學電源 |
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| Research Domain:natural organic chemistry,bio-organic chemistry,pharmacochemistry,organic analysis |
Country:[CN] |
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《化學學報》、《高等學校化學學報》等刊物編委 |
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| Research Domain:Pharmaceutical Technological |
Country:[CN] |
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(S)-3-Hydroxypyrrolidine hydrochloride
(R)-3-Hydroxypyrrolidine hydrochloride
N-Boc-3-Pyrrolidinone
(R)-3-Amino-N-Boc-pyrrolidine
D-Prolinamide
(R)-N-Boc-3-Hydroxypiperidine
N-Boc-4-piperidinemethanol
(R)-N-Boc-3-aminopiperidineN-Boc-4-methylaminopieridine
(R)-4-N-Boc-2-methylpiperazine
(S)-N-Boc-3-piperazinecarboxylic acid ester |
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| Research Domain:Materials for Optical Limiting |
Country:[CN] |
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Complexes containing metal-metal bonds are of interest for both their chemical reactivity and their physical properties. We are currently focussing on the physical properties of mixed-metal Group 6-Group 9 and high-nuclearity ruthenium clusters, specifically in their potential for use in optical limiting applications. Results from our clusters are competitive with those of the other "hot" optical limiting materials (phthalocyanines and fullerenes), but our mixed-metal clusters possess the additional virtue of easy tailoring of response by molecular structure modification. To fully exploit such materials, processability needs to be built in. We are consequently now working on incorporating our tailored polymetallic clusters into polymeric supports via the polymer backbone to afford processable polymetallic polymers.
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