Condensed Matter Physics and Materials Science: David M

Slides:

Advertisements

Similar presentations

Simulazione di Biomolecole: metodi e applicazioni giorgio colombo

Advertisements

Wave function approaches to non-adiabatic systems

Crystallography, Birkbeck MOLECULAR SIMULATIONS ALL YOU (N)EVER WANTED TO KNOW Julia M. Goodfellow Dynamic Processes: Lecture 1 Lecture Notes.

Molecular dynamics modeling of thermal and mechanical properties Alejandro Strachan School of Materials Engineering Purdue University

Transfer FAS UAS SAINT-PETERSBURG STATE UNIVERSITY COMPUTATIONAL PHYSICS Introduction Physical basis Molecular dynamics Temperature and thermostat Numerical.

Software Demonstration and Course Description P.N. Lai.

Teaching Courses in Scientific Computing 30 September 2010 Roger Bielefeld Director, Advanced Research Computing.

CVEN 5838 Aug 28, 2008 Lecture 2 Reservoir Capacity Yield Analysis (how to size a reservoir and measure its performance)

Jeffery Loo NLM Associate Fellow ’03 – ’05 chemicalinformaticsforlibraries.

NSF and Environmental Cyberinfrastructure Margaret Leinen Environmental Cyberinfrastructure Workshop, NCAR 2002.

Module on Computational Astrophysics Professor Jim Stone Department of Astrophysical Sciences and PACM.

Universality in ultra-cold fermionic atom gases. with S. Diehl, H.Gies, J.Pawlowski S. Diehl, H.Gies, J.Pawlowski.

Computational Physics Quantum Monte Carlo methods Dr. Guy Tel-Zur.

Quantum Calculations B. Barbiellini Thematics seminar April 21,2005.

Objectives of this course

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

The educational-oriented pack of computer programs to simulate solar cell behavior Aleksy Patryn 1 Stanisław M. Pietruszko 2  Faculty of Electronics,

Algorithms and Software for Large-Scale Simulation of Reactive Systems _______________________________ Ananth Grama Coordinated Systems Lab Purdue University.

High Performance Computing on Condensed Matter Physics Dr. D. Baba Basha College of Computer & Information Science Majmaah University.

The Nuts and Bolts of First-Principles Simulation Durham, 6th-13th December : DFT Plane Wave Pseudopotential versus Other Approaches CASTEP Developers’

Future role of DMR in Cyber Infrastructure D. Ceperley NCSA, University of Illinois Urbana-Champaign N.B. All views expressed are my own.

Physics Steven Gottlieb, NCSA/Indiana University Lattice QCD: focus on one area I understand well. A central aim of calculations using lattice QCD is to.

2005 Materials Computation Center External Board Meeting The Materials Computation Center Duane D. Johnson and Richard M. Martin (PIs) Funded by NSF DMR.

Becerra-Fernandez, et al. -- Knowledge Management 1/e -- © 2004 Prentice Hall Epilogue The Future of Knowledge Management.

U N I V E R S I T Y O F S O U T H F L O R I D A Database-centric Data Analysis of Molecular Simulations Yicheng Tu *, Sagar Pandit §, Ivan Dyedov *, and.

Note! The following is excerpted from a lecture found on-line. The original author is Professor Peter Y. Yu Department of Physics University of California.

Cyber-Infrastructure for Materials Simulation at the Petascale Trends/opportunities Recommendations for CI support David Ceperley National Center for Supercomputing.

1 Computational Challenges in Warm Dense Matter, Los Angeles, CA. Tuesday, May 22, 2012, 4:30 PM Perspectives on plasma simulation techniques from the.

Understanding Molecular Simulations Introduction

Comp. Mat. Science School 2001 Lecture 21 Density Functional Theory for Electrons in Materials Richard M. Martin Bands in GaAs Prediction of Phase Diagram.

GEOSCIENCE NEEDS & CHALLENGES Dogan Seber San Diego Supercomputer Center University of California, San Diego, USA.

Javier Junquera Introduction to atomistic simulation methods in condensed matter Alberto García Pablo Ordejón.

Calculating Potential Energy Curves With Quantum Monte Carlo Andrew D Powell, Richard Dawes Department of Chemistry, Missouri University of Science and.

Smoothing, Sampling, and Simulation Vasileios Hatzivassiloglou University of Texas at Dallas.

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

Generalized van der Waals Partition Function

Advanced methods of molecular dynamics 1.Monte Carlo methods 2.Free energy calculations 3.Ab initio molecular dynamics 4.Quantum molecular dynamics 5.Trajectory.

Composition of the Earth’s core from ab-initio calculation of chemical potentials Department of Earth Sciences & Department of Physics and Astronomy, Thomas.

Comp. Mat. Science School Electrons in Materials Density Functional Theory Richard M. Martin Electron density in La 2 CuO 4 - difference from sum.

RF Superconducting Materials Workshop at Fermilab, May 23 & 24, 2007 Advanced Nb oxide surface modification by cluster ion beams Zeke Insepov, Jim Norem.

Sub-fields of computer science. Sub-fields of computer science.

Authors: Christos Stergiou Andreas P. Plageras Kostas E. Psannis

Microstructure Imaging Sequence Simulation Toolbox

Engineering (Richard D. Braatz and Umberto Ravaioli)

Introduction: Computer programming

Joslynn Lee – Data Science Educator

Analysis of Computing Options at ISU

An Artificial Intelligence Approach to Precision Oncology

Overview of Molecular Dynamics Simulation Theory

Tohoku University, Japan

Industrial Best Practice in Modelling and Simulation

for the Offline and Computing groups

Integrated Computational Materials Engineering

Recap: introduction to e-science

Campus Cyberinfrastructure

High Performance Computing on Condensed Matter Physics

Ray-Cast Rendering in VTK-m

Theoretical and Computational Biophysics Group

The Materials Computation Center. Duane D. Johnson and Richard M

How might a Fermi surface die?

Algorithms and Software for Large-Scale Simulation of Reactive Systems

Prof. Sanjay. V. Khare Department of Physics and Astronomy,

Masoud Aryanpour & Varun Rai

CS385T Software Engineering Dr.Doaa Sami

Welcome to ECT*.

Energy Resources Engineering Department Stanford University, CA, USA

Algorithms and Software for Large-Scale Simulation of Reactive Systems

Quantum Computing Hakem Alazmi Jhilakshi Sharma Linda Vu.

A Closure Theory for Non-linear Evolution of Power Spectrum

Materials Computation Center, University of Illinois

Presentation transcript:

Condensed Matter Physics and Materials Science: David M Condensed Matter Physics and Materials Science: David M. Ceperley, Duane J. Johnson, Jeongnim Kim Solving electronic structure problem is a key step Understand fundamental properties of condensed matter and molecular systems Predict and design new materials and devices Perform multi-scale and multi-physics simulations of complex systems Very strong economic and intellectual interest Materials by design: how do we make better batteries, solar cells, strong alloys, materials for alternative energies? Can we make predictions when experiment is difficult, costly or impossible? What is the microscopic origin of superconductivity, magnetism,…? The kernel for these questions: the solution of the many-body Schrödinger equation to high accuracy (0.01 eV for example) and the computation of thermodynamic properties. NCSA Strategic Planning Presentation (April 20,2010)

Bottlenecks/Issues to Achieving Objectives Need large-scale HPC resources, e.g., DMC simulations of liquid H2O Free-energy calculations of hydrogen-helium mixtures Need efficient software on the current and future architectures Parallel computing on large-scale SMP clusters Heterogeneous computing, e.g. GPU clusters Need collaborative environments The ES problem requires multi-scale approaches: not a single theoretical framework nor code can handle the complexity and the length- and time-scale of the problems. Data exchanges between codes and applications are essential. New discoveries demand modern tools to analyze, archive and mine exploding simulation data. NCSA Strategic Planning Presentation (April 20,2010)

Cyberinfrastructure Challenges in Reaching the Objectives: H2 storage H2 binding energy to benzene Motivations: search for carbon-based hydrogen storage media Challenges: accurate prediction of small binding energies of H2 Ingredients and stages Structural model from experiments and simple theories Mean-field electronic structure method to build an optimal many-body wavefunction for quantum Monte Carlo Diffusion Monte Carlo calculations Stochastic optimization to determine the bond length and binding energy Beaudet et. al. JCP 129, 164711 (2008) 1.53(1) mHa 6.33(15) Bohr R High-performance ES software Data standards for multiple applications Data analysis and mining tools Knowledge and education tools NCSA Strategic Planning Presentation (April 20,2010)

Cyberinfrastructure Challenges in Reaching the Objectives: Free energy of H/He mixtures Motivations: model the interior of Jupiter and Saturn Challenges: accurate prediction of EOS and phase diagram of H/He mixtures Ingredients and stages Born-Oppenheimer MD at various He concentrations, temperatures and pressures Coupled ion-electron Monte Calro (CIEMC) calculations Free-energy integration with CIEMC Three views of the interior of Saturn Taken from: Fortney J. J., Science 305, 1414 (2004). High-performance ES software Data standards for multiple applications Data analysis and mining tools Knowledge and education tools M. Morales et. al., PNAS 106:1324-1329 (2009) NCSA Strategic Planning Presentation (April 20,2010)

Challenges in Reaching the Objectives for the ES community in the US The US has developed many of the ES methods and numerical algorithms in the last decades and has led the development of HPC software. Recent Gordon Bell winners include Qbox, DCA++, WL-LSMS. But, development of production codes has moved to Europe and Asia and very few open-source community codes are originated from the US research institutions. Why can we capitalize what we have achieved ? Individual University groups are typically too small. Code development is not usually considered a first rate research, so non-tenured faculty are not advised to go this route. Corporate research has vanished. No supports to maintain software. NCSA Strategic Planning Presentation (April 20,2010)

Strategic Planning Process We need a coordinated national program to Develop algorithms and quality software on all computing platforms Develop data standards and collaboration tools Maintain software for the current and future architectures Train developers and users Payoffs in terms of both basic and applied science are potentially very large. NCSA Strategic Planning Presentation (April 20,2010)

Strategic Planning Process NCSA Strategic Planning Presentation (April 20,2010)

Reference slide (Discipline or Topic Reports, Papers, Committee & Workshop Reports, People Consulted……. ) NCSA Strategic Planning Presentation (April 20,2010)