Cross-cutting analysis tools Preliminary report J. Murray Gibson Friday morning 03/05/2010.

Slides:

Advertisements

Similar presentations

The Prime Ministers Chief Science Advisor Sir Peter Gluckman Waikato Management School Friday 10 May 2013 Briefing for scientific community National Science.

Advertisements

MATERIALS FOR ENERGY CMAST (Computational MAterials Science & Technology) Virtual Lab Computational Materials Science Hydrogen.

C1 - The Impact of CAD on the Design Process.  Consider CAD drawing, 2D, 3D, rendering and different types of modelling.

ASCR Data Science Centers Infrastructure Demonstration S. Canon, N. Desai, M. Ernst, K. Kleese-Van Dam, G. Shipman, B. Tierney.

Aug 9-10, 2011 Nuclear Energy University Programs Materials: NEAMS Perspective James Peltz, Program Manager, NEAMS Crosscutting Methods and Tools.

Nature provides us of many examples of self- assembled materials, from soft and flexible cell- membranes to hard sea shells. Such materials.

 delivers evidence that a solution developed achieves the purpose for which it was designed.  The purpose of evaluation is to demonstrate the utility,

Nanofabrication Breakout Session Results. Vision Elements Ability to fabricate, by directed or self assembly methods, functional structures or devices.

INTRODUCTION AND BACKGROUND Sales of oxidation catalysts account for about 18% of total world sales of catalysts in the process industries. It is an enormous.

Carbon Sequestration is the process of trapping CO 2 underground in order to prevent its release into the atmosphere to reduce our impact on the climate.

Dr. Jie Zou PHY 1151G Department of Physics1 Chapter 17 Phases and Phase Changes.

Nanoscience at UMCP. Department of Chemistry and Biochemistry Faculty: Jeff Davis, Bryan Eichhorn, Doug English, Lyle Isaacs, Jason Kahn, Janice Reutt-Robey,

Introduction to the School of Chemistry University of Leeds Professor S.K. Scott

Engineering Systems of.

Crosscutting Concepts and Disciplinary Core Ideas February24, 2012 Heidi Schweingruber Deputy Director, Board on Science Education, NRC/NAS.

By: Lea Versoza. Chemistry  A branch of physical science, is the study of the composition, properties and behavior of matter.  Is concerned with atoms.

Multimedia Production Team

ISBE An infrastructure for European (systems) biology Martijn J. Moné Seqahead meeting “ICT needs and challenges for Big Data in the Life Sciences” Pula,

P. 1 basic research needs workshop for Carbon Capture: Beyond 2020 Plenary Midpoint Session March 4, Potential scientific impactPotential impact.

Department of Chemistry A state-of-the-art instrumental park is available to purify and characterize the synthesized molecules The research activities.

InsilicoCell: an integrated platform for biological model development and analysis Thai Quang Tung Korea Institute of Science and Technology Information.

GTL Facilities Computing Infrastructure for 21 st Century Systems Biology Ed Uberbacher ORNL & Mike Colvin LLNL.

Basic Energy Sciences The Charge The Objective The Context The Message The Vehicle The Recommendations New Science for a Secure and Sustainable Energy.

Instrumentation and Metrology for Nanocharacterization.

ITR: Collaborative research: software for interpretation of cosmogenic isotope inventories - a combination of geology, modeling, software engineering and.

 Energy ◦ The ability to do work or cause change ◦ Occurs in various forms ◦ Can be converted to another form ◦ Forms important to biological systems.

THE NATURE OF SOLIDS by Mike, Marc & Alex. A Model for Solids - Atoms, Ions or molecules are packed tightly together - dense and not easy to compress.

P. 1 basic research needs workshop for Carbon Capture: Beyond 2020 Plenary Closing Session March 5, 2010 Cross-cutting Analysis Tools: panel members *

Techniques for Synthesis of Nano-materials

Writing Chemical Equations

Chapter 8 Solids, Liquids, and Gases Sections 1 and 2 Notes.

ACCELERATED UNDERSTANDING BIGDATA AND VISUALIZATION: WHAT IS IT?

Chemical Reactions and Enzymes. What is a Chemical Reaction? A process occurs when molecules interact to produce new chemical compounds Examples: CH 4.

Copyright©2004 by Houghton Mifflin Company. All rights reserved. 1 Introductory Chemistry: A Foundation FIFTH EDITION by Steven S. Zumdahl University of.

Kinetic Molecular Theory. What do we assume about the behavior of an ideal gas?   Gas molecules are in constant, random motion and when they collide.

1 Investigative Tools--Theory, Modeling, and Simulation Rational You ITRI-IEK-NEMS 2001/08/06 Source: IWGN (1999/09)

Futures Lab: Biology Greenhouse gasses. Carbon-neutral fuels. Cleaning Waste Sites. All of these problems have possible solutions originating in the biology.

Nanoscale Science and Engineering. Nanoscale Science and Engineering embodies fundamental research and technology development of materials, structures,

Catawba County Board of Commissioners Retreat June 11, 2007 It is a great time to be an innovator 2007 Technology Strategic Plan *

StOCNET : Suite of programs for analysis of empirical network data, with the purpose of statistical inference: interpret data by applying probability models.

Studies of the Properties of Polymer Nanocomposites Mechanical Properties  Tensile Measurements  Dynamic Mechanical Analysis (DMA) Morphology  Scanning.

World Climate Research Programme Joint Scientific Committee – 31 Antalya, Turkey.

”Petru Poni” Institute of Macromolecular Chemistry Grigore Ghica Voda Alley No 41 A, Iasi, Romania Project No 254/ Code Project: PNII- RU-TE

Role of Theory Model and understand catalytic processes at the electronic/atomistic level. This involves proposing atomic structures, suggesting reaction.

INFSO-RI Enabling Grids for E-sciencE Construction of a Mathematical Model of a Cell as a Challenge for Science in the 21 Century.

Systems Analyst (Module V) Ashima Wadhwa. The Systems Analyst - A Key Resource Many organizations consider information systems and computer applications.

Dynamics theory and experiment 1. Atomic motion and energy flow in the reacting molecules. 2. Atomic motion and energy flow in the reacting surface/substrate.

RATES OF REACTION. Rates of Reaction The rate of a chemical reaction is the speed at which the reaction occurs (i.e. speed at which the reactants are.

Water. Interesting video of water NOTES Water is truly unique:

Physical and Chemical Properties of Matter 6 th Grade Integrated Science Ms. Mathieson.

A Computational Study of RNA Structure and Dynamics Rhiannon Jacobs and Harish Vashisth Department of Chemical Engineering, University of New Hampshire,

Project idea SUSCHEM BROKERAGE EVENT 2012 PROJECT TITLE CO 2 capture using “poly(ionic liquid)s” with high surface area CONTACT Germán Cabañero New Materials.

Molecular Modeling and Visualization Tools in Science Education ChemSenseChemViz Molecular Workbench Virtual Molecular Dynamics Lab NARST Convention Philadelphia,

Overview of CATIA V5.

Chemistry 9701.

Andrew R. Barron Applications of Connexions in Teaching

Chemical Kinetics Relationship between reaction rate and the variables that exert influence on them. Mechanism of chemical reaction.

NSF NSEC Grant DMR PI: Dr. Richard W. Siegel

Interfacial Electron Transfer One Molecule at a Time Oliver L.A. Monti

Interfacial Electron Transfer One Molecule at a Time Oliver L.A. Monti

VLT Meeting, Washington DC, August 25, 2005

States Of Matter K 2.1 Solids.

Published monthly, ACS Nano is an international forum for the communication of comprehensive articles on nanoscience and nanotechnology research at the.

Advances in Scanning Probe Microscopy

Ch. 13 Clicker Review.

Multiscale Modeling and Simulation of Nanoengineering:

Dmitri V. Talapin, Department of Chemistry, University of Chicago

Curitiba: cities and self organisation

GhoSST (formerly STSP)

Presentation transcript:

Cross-cutting analysis tools Preliminary report J. Murray Gibson Friday morning 03/05/2010

List of possible PRD’s In-situ and time resolved characterization Measure mechanisms and kinetics of capture and release in complex materials Characterize dynamics of molecular interactions at interfaces and surfaces Develop an infrastructure of methods to link observables to structure for complex, including non-crystalline, materials

In-situ and time resolved characterization Characterize the state of materials under gas, temperature, other conditions relevant to capture and release conditions. Links to user facilities. Also characterization to support synthesis. Follow development of self- assembly, such as nanostructures, during synthesis. Other examples? – Alex, Yves

Measure mechanisms and kinetics of capture and release in complex materials Develop methods for kinetics and mechanisms of capture and release in complex materials. Characterize the chemical processes in sufficient detail to understand mechanistic pathways. – Wendy

Characterize dynamics of molecular interactions at interfaces and surfaces Characterize dynamics of molecular interactions at interfaces. Develop spectroscopic, structural, physical and computational methods to determine the detailed interaction of gas molecules (e.g., H2, CO2, N2, CH4, NOx, SOx) with nanopores or surfaces of guest materials (organic, inorganic or hybrid) in various forms (crystalline, amorphous). – Yves, Alex

Develop an infrastructure of methods to link observables to structure for complex, including non-crystalline, materials Develop an infrastructure of methods to link observables to structure for complex, including non-crystalline, materials. Develop the conceptual tools to integrate multiple techniques and computational information into one ‘best fit’ for a complex structure. Implement these with a cyber infrastructure to make expertise in multiple methods accessible to guide real world synthesis. This can link to user facilities. – Philip

Other observations Several of these involve close interaction between experiment and theory/computation. This is an underlying need in all of the characterization science for complex materials. There may be cross-cutting needs in innovative synthesis methods. We aren’t sure it is in our mandate. But it isn’t clear that it is being captured appropriately in the individual groups. An example is the ability to nanostructure capture materials in membranes, solid sorbents and even in solvated NP liquids.