Computational Materials Science with the WIEN2k code
Size: px
Start display at page:

Download "Computational Materials Science with the WIEN2k code"

Transcription

1 Computational Materials Science with the WIEN2k code P. Blaha Institute of Materials Chemistry TU Wien

2 Computational Materials Science describe materials by quantummechanical simulations(ab initio) simulate: infinite ( perfect ) bulk solids impurities, vacancies in solids surfaces nanostructures atomic and electronic structure stability, phase transitions, mechanical properties, magnetism, chemical bonding,. spectroscopies (IR, Raman, XPS, XAS, XES, EELS,Mössbauer, NMR, STM)

3 Method: DFT calculations numerical solution of a Schrödinger-like equation (Kohn-Sham) k k k V ( r) i ei i 2 expansion into augmented plane waves basisfunctions f Kn : variational principle 1 2 k = C f K n k n k < E n n APWs / atom < H > < E >= < > C k n > =0 generalized eigenvalue problem H C=E S C Setup and diagonalization of (real or complex) matrices of size to (up to 50 Gb memory, only 10% of e i )

4 Loops: loop 1: different structures (atomic positions) loop 2: scf-cycle (solve [-½ 2 +V] =E new V iterate) loop 3: k-loop (solve H =E for different k-points) loop 4: setup + diagonalization of H C = E S C largest effort, highest optimization, best parallelization, scaling of time and memory F90, mpi, Scalapack, blas processors loop over APWs in parallel (via scripts, slow network, common NFS) sequential (efficient multi-secant BROYDEN-mixing; L.Marks PRB 78, ) coarse grain parallel (different jobs) or sequential (forces new positions)

5 WIEN2k software package An Augmented Plane Wave Plus Local Orbital Program for Calculating Crystal Properties Peter Blaha Karlheinz Schwarz Georg Madsen Dieter Kvasnicka Joachim Luitz November 2001 Vienna, AUSTRIA Vienna University of Technology developed over more than 25 years 1400 registered groups 2000 mailinglist users Europe: A, B, CH, CZ, D, DK, ES, F, FIN, GR, H, I, IL, IRE, N, NL, PL, RO, S, SK, SL, SI, UK, ETH Zürich, MPI Stuttgart, FHI Berlin, DESY, TH Aachen, ESRF, Prague, IJS Ljubjlana, Paris, Chalmers, Cambridge, Oxford America: ARG, BZ, CDN, MX, USA (MIT, NIST, Berkeley, Princeton, Harvard, Argonne NL, Los Alamos NL, Oak Ridge NL, Penn State, Purdue, Georgia Tech, Lehigh, John Hopkins, Chicago, Stony Brook, SUNY, UC St.Barbara, UCLA) far east: AUS, China, India, JPN, Korea, Pakistan, Singapore,Taiwan (Beijing, Tokyo, Osaka, Kyoto, Sendai, Tsukuba, Hong Kong) 55 industries (Canon, Eastman, Exxon, Fuji, Hitachi, IBM, Idemitsu Petrochem., Kansai, Komatsu, Konica-Minolta, A.D.Little, Mitsubishi, Mitsui Mining, Motorola, NEC, Nippon Steel, Norsk Hydro, Osram, Panasonic, Samsung, Seiko Epson, Siemens, Sony, Sumitomo,TDK,Toyota).

6 w2web GUI (graphical user interface) Structure generator spacegroup selection import cif file step by step initialization symmetry detection automatic input generation SCF calculations Magnetism (spin-polarization) Spin-orbit coupling Forces (automatic geometry optimization) Guided Tasks Energy band structure DOS Electron density X-ray spectra Optics command line possible!

7 current hardware: SFB Aurora IBM Cluster 72 x Dual Xeon 3.6 GHz, 1MB L2 Infiniband Switch (installed 2005) SUN Cluster 72 x Quad-Opterons 2.4 GHz Infiniband Switch (installed 2006) WIEN2k on IBM-BlueGene (2000 processors)

8 Timing and parallel performance: Task Time (s) r, V eff 151 H, S setup 1176 full diagonalization 2454 iterative diag x3 super-cell of a h-bn/ni(111) surface model with 99 atoms/cell (N bas = 16900, 1 scf-cycle on 4 cores) iterative block-davidson diagonalization with improved preconditioner [formally H -1 instead of diag(h-es) -1 ; but only factorization of H required] hand-coded mpi (setup) scalapack (diagonalization) (limitations due to stacked Infiniband switch)

9 h-bn / Rh(111) nanomesh STM Experiment: M.Corso et al., Science 303, 217(2004) partial double layer model Theory: R.Laskowski et al., PRL 98, (2007): Corrugated single layer model 12x12 Rh, 13x13 BN, 1108 atoms/cell, HC=ESC (50000x50000, 50 GB memory) 64 cpus, 2h/scf-cycle (was 20h!!) 3 month of computing time N corrugation Theoretical model was confirmed later! H. Dill, et. al.: Science 319, S. 1824(2008)

10 Thank you for your attention!

Similar documents

Materials Science with WIEN2k on vsc1 and vsc2

Materials Science with WIEN2k on vsc1 and vsc2 Materials Science with WIEN2k on vsc1 and vsc2 P. Blaha Institute of Materials Chemistry TU Wien pblaha@theochem.tuwien.ac.at http://www.wien2k.at Computational Materials Science describe materials by

More information

Iterative Diagonalization in Augmented Plane Wave Based Methods in Electronic Structure Calculations

Iterative Diagonalization in Augmented Plane Wave Based Methods in Electronic Structure Calculations * 0. Manuscript Click here to view linked References 1 1 1 1 0 1 0 1 0 1 0 1 0 1 Iterative Diagonalization in Augmented Plane Wave Based Methods in Electronic Structure Calculations P. Blaha a,, H. Hofstätter

More information

CHAPTER 3 WIEN2k. Chapter 3 : WIEN2k 50

CHAPTER 3 WIEN2k. Chapter 3 : WIEN2k 50 CHAPTER 3 WIEN2k WIEN2k is one of the fastest and reliable simulation codes among computational methods. All the computational work presented on lanthanide intermetallic compounds has been performed by

More information

Chapter 3. The (L)APW+lo Method. 3.1 Choosing A Basis Set

Chapter 3. The (L)APW+lo Method. 3.1 Choosing A Basis Set Chapter 3 The (L)APW+lo Method 3.1 Choosing A Basis Set The Kohn-Sham equations (Eq. (2.17)) provide a formulation of how to practically find a solution to the Hohenberg-Kohn functional (Eq. (2.15)). Nevertheless

More information

Country

Country Total A 36,3 31,1 B 33,8 36,9 37,4 D 41,4 D-W 41,6 37,7 40,7 42,4 D-E 28,2 36,9 36,8 DK 55,8 49,1 48,8 E 33,2 39,5 33,2 28,9 F 44,4 33,1 36,3 FIN 62,2 30,9 50,6 54,6 GB 26,1 26,2 27,1 GR 14,5 I 34,5 32,1

More information

Country

Country Total EU-12 89,6 89,4 85,7 82,9 85,9 86,9 87,4 EU-15 89,6 85,7 83,1 86,2 87,0 87,5 EU-25 87,9 A 95,1 90,2 88,0 90,8 88,2 93,7 B 80,7 91,1 84,6 84,3 86,3 89,6 85,8 D 95,1 94,1 86,1 86,3 88,0 86,4 89,4 D-W

More information

ELSI: A Unified Software Interface for Kohn-Sham Electronic Structure Solvers

ELSI: A Unified Software Interface for Kohn-Sham Electronic Structure Solvers ELSI: A Unified Software Interface for Kohn-Sham Electronic Structure Solvers Victor Yu and the ELSI team Department of Mechanical Engineering & Materials Science Duke University Kohn-Sham Density-Functional

More information

Density functional theory (DFT) and the concepts of the augmented-plane-wave plus local orbital (L)APW+lo method

Density functional theory (DFT) and the concepts of the augmented-plane-wave plus local orbital (L)APW+lo method Density functional theory (DFT) and the concepts of the augmented-plane-wave plus local orbital (L)APW+lo method Karlheinz Schwarz Institute for Material Chemistry TU Wien Vienna University of Technology

More information

COMPUTATIONAL TOOL. Fig. 4.1 Opening screen of w2web

COMPUTATIONAL TOOL. Fig. 4.1 Opening screen of w2web CHAPTER -4 COMPUTATIONAL TOOL Ph.D. Thesis: J. Maibam CHAPTER: 4 4.1 The WIEN2k code In this work, all the calculations presented are performed using the WIEN2k software package (Blaha et al., 2001). The

More information

Large scale applications:

Large scale applications: Large scale applications: * Verwey transition (magnetite, YBaFe 2 O 5 ) * Boron nitride BN on transition metal (111) surfaces * Misfit layer compounds PbS 1.14 TaS 2 Karlheinz Schwarz Institut für Materialchemie

More information

The Linearized Augmented Planewave (LAPW) Method

The Linearized Augmented Planewave (LAPW) Method The Linearized Augmented Planewave (LAPW) Method David J. Singh Oak Ridge National Laboratory E T [ ]=T s [ ]+E ei [ ]+E H [ ]+E xc [ ]+E ii {T s +V ks [,r]} I (r)= i i (r) Need tools that are reliable

More information

Electronic structure calculations with GPAW. Jussi Enkovaara CSC IT Center for Science, Finland

Electronic structure calculations with GPAW. Jussi Enkovaara CSC IT Center for Science, Finland Electronic structure calculations with GPAW Jussi Enkovaara CSC IT Center for Science, Finland Basics of density-functional theory Density-functional theory Many-body Schrödinger equation Can be solved

More information

CRYSTAL in parallel: replicated and distributed (MPP) data. Why parallel?

CRYSTAL in parallel: replicated and distributed (MPP) data. Why parallel? CRYSTAL in parallel: replicated and distributed (MPP) data Roberto Orlando Dipartimento di Chimica Università di Torino Via Pietro Giuria 5, 10125 Torino (Italy) roberto.orlando@unito.it 1 Why parallel?

More information

Density functional theory (DFT) and the concepts of the augmented-plane-wave plus local orbital (L)APW+lo method

Density functional theory (DFT) and the concepts of the augmented-plane-wave plus local orbital (L)APW+lo method Density functional theory (DFT) and the concepts of the augmented-plane-wave plus local orbital (L)APW+lo method Karlheinz Schwarz Institute for Material Chemistry TU Wien Vienna University of Technology

More information

FULL POTENTIAL LINEARIZED AUGMENTED PLANE WAVE (FP-LAPW) IN THE FRAMEWORK OF DENSITY FUNCTIONAL THEORY

FULL POTENTIAL LINEARIZED AUGMENTED PLANE WAVE (FP-LAPW) IN THE FRAMEWORK OF DENSITY FUNCTIONAL THEORY FULL POTENTIAL LINEARIZED AUGMENTED PLANE WAVE (FP-LAPW) IN THE FRAMEWORK OF DENSITY FUNCTIONAL THEORY C.A. Madu and B.N Onwuagba Department of Physics, Federal University of Technology Owerri, Nigeria

More information

Basic introduction of NWChem software

Basic introduction of NWChem software Basic introduction of NWChem software Background NWChem is part of the Molecular Science Software Suite Designed and developed to be a highly efficient and portable Massively Parallel computational chemistry

More information

VASP: running on HPC resources. University of Vienna, Faculty of Physics and Center for Computational Materials Science, Vienna, Austria

VASP: running on HPC resources. University of Vienna, Faculty of Physics and Center for Computational Materials Science, Vienna, Austria VASP: running on HPC resources University of Vienna, Faculty of Physics and Center for Computational Materials Science, Vienna, Austria The Many-Body Schrödinger equation 0 @ 1 2 X i i + X i Ĥ (r 1,...,r

More information

exciting in a nutshell

exciting in a nutshell http://exciting-code.org exciting in a nutshell Pasquale Pavone Humboldt-Universität zu Berlin http://exciting-code.org exciting in a (coco)nutshell Pasquale Pavone Humboldt-Universität zu Berlin Outline

More information

Parallel Eigensolver Performance on High Performance Computers

Parallel Eigensolver Performance on High Performance Computers Parallel Eigensolver Performance on High Performance Computers Andrew Sunderland Advanced Research Computing Group STFC Daresbury Laboratory CUG 2008 Helsinki 1 Summary (Briefly) Introduce parallel diagonalization

More information

ELECTRONIC STRUCTURE AND CHEMICAL BONDING IN LAVES PHASES Al 2 Ca, Be 2 Ag AND Be 2 Ti. D. Shapiro, D. Fuks, A. Kiv

ELECTRONIC STRUCTURE AND CHEMICAL BONDING IN LAVES PHASES Al 2 Ca, Be 2 Ag AND Be 2 Ti. D. Shapiro, D. Fuks, A. Kiv Computer Modelling and New Technologies, 2009, Vol.13, No.1, 7 16 Transport and Telecommunication Institute, Lomonosova 1, LV-1019, Riga, Latvia ELECTRONIC STRUCTURE AND CHEMICAL BONDING IN LAVES PHASES

More information

Quantum Chemical Calculations by Parallel Computer from Commodity PC Components

Quantum Chemical Calculations by Parallel Computer from Commodity PC Components Nonlinear Analysis: Modelling and Control, 2007, Vol. 12, No. 4, 461 468 Quantum Chemical Calculations by Parallel Computer from Commodity PC Components S. Bekešienė 1, S. Sėrikovienė 2 1 Institute of

More information

A Package for calculating elastic tensors of cubic Phases by using second-order derivative with WIEN2k Package

A Package for calculating elastic tensors of cubic Phases by using second-order derivative with WIEN2k Package IR E L A S T + W I E N 2k A Package for calculating elastic tensors of cubic Phases by using second-order derivative with WIEN2k Package User s guide, Cubic-elastic_13.2 (Release 27.08.2013) Morteza Jamal

More information

A Green Function Method for Large Scale Electronic Structure Calculations. Rudolf Zeller

A Green Function Method for Large Scale Electronic Structure Calculations. Rudolf Zeller A Green Function Method for Large Scale Electronic Structure Calculations Rudolf Zeller Institute for Advanced Simulation, Forschungszentrum Jülich Electronic structure calculations (density functional

More information

Parallelization of the Molecular Orbital Program MOS-F

Parallelization of the Molecular Orbital Program MOS-F Parallelization of the Molecular Orbital Program MOS-F Akira Asato, Satoshi Onodera, Yoshie Inada, Elena Akhmatskaya, Ross Nobes, Azuma Matsuura, Atsuya Takahashi November 2003 Fujitsu Laboratories of

More information

Cluster Computing: Updraft. Charles Reid Scientific Computing Summer Workshop June 29, 2010

Cluster Computing: Updraft. Charles Reid Scientific Computing Summer Workshop June 29, 2010 Cluster Computing: Updraft Charles Reid Scientific Computing Summer Workshop June 29, 2010 Updraft Cluster: Hardware 256 Dual Quad-Core Nodes 2048 Cores 2.8 GHz Intel Xeon Processors 16 GB memory per

More information

WRF performance tuning for the Intel Woodcrest Processor

WRF performance tuning for the Intel Woodcrest Processor WRF performance tuning for the Intel Woodcrest Processor A. Semenov, T. Kashevarova, P. Mankevich, D. Shkurko, K. Arturov, N. Panov Intel Corp., pr. ak. Lavrentieva 6/1, Novosibirsk, Russia, 630090 {alexander.l.semenov,tamara.p.kashevarova,pavel.v.mankevich,

More information

Parallel Eigensolver Performance on High Performance Computers 1

Parallel Eigensolver Performance on High Performance Computers 1 Parallel Eigensolver Performance on High Performance Computers 1 Andrew Sunderland STFC Daresbury Laboratory, Warrington, UK Abstract Eigenvalue and eigenvector computations arise in a wide range of scientific

More information

Direct Self-Consistent Field Computations on GPU Clusters

Direct Self-Consistent Field Computations on GPU Clusters Direct Self-Consistent Field Computations on GPU Clusters Guochun Shi, Volodymyr Kindratenko National Center for Supercomputing Applications University of Illinois at UrbanaChampaign Ivan Ufimtsev, Todd

More information

Table of Contents. Table of Contents Spin-orbit splitting of semiconductor band structures

Table of Contents. Table of Contents Spin-orbit splitting of semiconductor band structures Table of Contents Table of Contents Spin-orbit splitting of semiconductor band structures Relavistic effects in Kohn-Sham DFT Silicon band splitting with ATK-DFT LSDA initial guess for the ground state

More information

Solution Behavior and Structural Properties of Cu(I) Complexes Featuring m-terphenyl Isocyanides

Solution Behavior and Structural Properties of Cu(I) Complexes Featuring m-terphenyl Isocyanides Supporting Information for the Paper Entitled: Solution Behavior and Structural Properties of Cu(I) Complexes Featuring m-terphenyl Isocyanides Brian J. Fox, Queena Y. Sun, Antonio G. DiPasquale, Alexander

More information

Photoelectron Interference Pattern (PEIP): A Two-particle Bragg-reflection Demonstration

Photoelectron Interference Pattern (PEIP): A Two-particle Bragg-reflection Demonstration Photoelectron Interference Pattern (PEIP): A Two-particle Bragg-reflection Demonstration Application No. : 2990 Beamlime: BL25SU Project Leader: Martin Månsson 0017349 Team Members: Dr. Oscar Tjernberg

More information

Computational Nanoscience: Do It Yourself!

Computational Nanoscience: Do It Yourself! John von Neumann Institute for Computing (NIC) Computational Nanoscience: Do It Yourself! edited by Johannes Grotendorst Stefan Blugel Dominik Marx Winter School, 14-22 February 2006 Forschungszentrum

More information

Symmetry Assumptions, Kramers Kronig Transformation and Analytical Continuation in Ab Initio Calculations of Optical Conductivities

Symmetry Assumptions, Kramers Kronig Transformation and Analytical Continuation in Ab Initio Calculations of Optical Conductivities Physica Scripta. Vol. T09, 70 74, 2004 Symmetry Assumptions, Kramers Kronig Transformation and Analytical Continuation in Ab Initio Calculations of Optical Conductivities Helmut Rathgen and Mikhail I.

More information

Basic introduction of NWChem software

Basic introduction of NWChem software Basic introduction of NWChem software Background! NWChem is part of the Molecular Science Software Suite! Designed and developed to be a highly efficient and portable Massively Parallel computational chemistry

More information

Accelerating Linear Algebra on Heterogeneous Architectures of Multicore and GPUs using MAGMA and DPLASMA and StarPU Schedulers

Accelerating Linear Algebra on Heterogeneous Architectures of Multicore and GPUs using MAGMA and DPLASMA and StarPU Schedulers UT College of Engineering Tutorial Accelerating Linear Algebra on Heterogeneous Architectures of Multicore and GPUs using MAGMA and DPLASMA and StarPU Schedulers Stan Tomov 1, George Bosilca 1, and Cédric

More information

Q-Chem 4.0: Expanding the Frontiers. Jing Kong Q-Chem Inc. Pittsburgh, PA

Q-Chem 4.0: Expanding the Frontiers. Jing Kong Q-Chem Inc. Pittsburgh, PA Q-Chem 4.0: Expanding the Frontiers Jing Kong Q-Chem Inc. Pittsburgh, PA Q-Chem: Profile Q-Chem is a high performance quantum chemistry program; Contributed by best quantum chemists from 40 universities

More information

Electronic structure, atomic forces and structural relaxations by WIEN2k

Electronic structure, atomic forces and structural relaxations by WIEN2k Electronic structure, atomic forces and structural relaxations by WIEN2k Peter Blaha Institute of Materials Chemistry TU Vienna, Austria Outline: APW-based methods (history and state-of-the-art) WIEN2k

More information

Electronic structure of Ce 2 Rh 3 Al 9

Electronic structure of Ce 2 Rh 3 Al 9 Materials Science-Poland, Vol. 24, No. 3, 2006 Electronic structure of Ce 2 Rh 3 Al 9 J. GORAUS 1*, A. ŚLEBARSKI 1, J. DENISZCZYK 2 1 Institute of Physics, University of Silesia, ul. Bankowa 12, 40-007

More information

Due: since the calculation takes longer than before, we ll make it due on 02/05/2016, Friday

Due: since the calculation takes longer than before, we ll make it due on 02/05/2016, Friday Homework 3 Due: since the calculation takes longer than before, we ll make it due on 02/05/2016, Friday Email to: jqian@caltech.edu Introduction In this assignment, you will be using a commercial periodic

More information

Computationally Efficient Analysis of Large Array FTIR Data In Chemical Reaction Studies Using Distributed Computing Strategy

Computationally Efficient Analysis of Large Array FTIR Data In Chemical Reaction Studies Using Distributed Computing Strategy 575f Computationally Efficient Analysis of Large Array FTIR Data In Chemical Reaction Studies Using Distributed Computing Strategy Ms Suyun Ong, Dr. Wee Chew, * Dr. Marc Garland Institute of Chemical and

More information

Comparison of various abinitio codes used in periodic calculations

Comparison of various abinitio codes used in periodic calculations Comparison of various abinitio codes used in periodic calculations 1 Prof.P. Ravindran, Department of Physics, Central University of Tamil Nadu, India & Center for Materials Science and Nanotechnology,

More information

Speed-up of ATK compared to

Speed-up of ATK compared to What s new @ Speed-up of ATK 2008.10 compared to 2008.02 System Speed-up Memory reduction Azafulleroid (molecule, 97 atoms) 1.1 15% 6x6x6 MgO (bulk, 432 atoms, Gamma point) 3.5 38% 6x6x6 MgO (k-point sampling

More information

Band calculations: Theory and Applications

Band calculations: Theory and Applications Band calculations: Theory and Applications Lecture 2: Different approximations for the exchange-correlation correlation functional in DFT Local density approximation () Generalized gradient approximation

More information

One Optimized I/O Configuration per HPC Application

One Optimized I/O Configuration per HPC Application One Optimized I/O Configuration per HPC Application Leveraging I/O Configurability of Amazon EC2 Cloud Mingliang Liu, Jidong Zhai, Yan Zhai Tsinghua University Xiaosong Ma North Carolina State University

More information

All electron optimized effective potential method for solids

All electron optimized effective potential method for solids All electron optimized effective potential method for solids Institut für Theoretische Physik Freie Universität Berlin, Germany and Fritz Haber Institute of the Max Planck Society, Berlin, Germany. 22

More information

Electron transport through molecular junctions and FHI-aims

Electron transport through molecular junctions and FHI-aims STM m metallic surface Electron transport through molecular junctions and FHI-aims Alexei Bagrets Inst. of Nanotechnology (INT) & Steinbuch Centre for Computing (SCC) @ Karlsruhe Institute of Technology

More information

NOT FOR DISTRIBUTION REVIEW COPY. Na 2 IrO 3 as a molecular orbital crystal

NOT FOR DISTRIBUTION REVIEW COPY. Na 2 IrO 3 as a molecular orbital crystal Na 2 IrO 3 as a molecular orbital crystal I. I. Mazin, 1 Harald O. Jeschke, 2 Kateryna Foyevtsova, 2 Roser Valentí, 2 and D. I. Khomskii 3 1 Code 6393, Naval Research Laboratory, Washington, DC 237, USA

More information

for XPS surface analysis

for XPS surface analysis Thermo Scientific Avantage XPS Software Powerful instrument operation and data processing for XPS surface analysis Avantage Software Atomic Concentration (%) 100 The premier software for surface analysis

More information

Core loss spectra (EELS, XAS)

Core loss spectra (EELS, XAS) Core loss spectra (EELS, XAS) Kevin Jorissen University of Washington (USA) WIENk 013 Penn State 1. Concepts WIENk calculates ELNES / XANES EELS : Electron Energy Loss Spectroscopy XAS: X-ray Absorption

More information

A Data Communication Reliability and Trustability Study for Cluster Computing

A Data Communication Reliability and Trustability Study for Cluster Computing A Data Communication Reliability and Trustability Study for Cluster Computing Speaker: Eduardo Colmenares Midwestern State University Wichita Falls, TX HPC Introduction Relevant to a variety of sciences,

More information

Pseudopotentials: design, testing, typical errors

Pseudopotentials: design, testing, typical errors Pseudopotentials: design, testing, typical errors Kevin F. Garrity Part 1 National Institute of Standards and Technology (NIST) Uncertainty Quantification in Materials Modeling 2015 Parameter free calculations.

More information

Making electronic structure methods scale: Large systems and (massively) parallel computing

Making electronic structure methods scale: Large systems and (massively) parallel computing AB Making electronic structure methods scale: Large systems and (massively) parallel computing Ville Havu Department of Applied Physics Helsinki University of Technology - TKK Ville.Havu@tkk.fi 1 Outline

More information

Theory, Interpretation and Applications of X-ray Spectra*

Theory, Interpretation and Applications of X-ray Spectra* REU Seminar University of Washington 27 July, 2015 Theory, Interpretation and Applications of X-ray Spectra* J. J. Rehr et al. A theoretical horror story Starring Fernando Vila & Anatoly Frenkel with J.

More information

Core-Level spectroscopy. Experiments and first-principles calculations. Tomoyuki Yamamoto. Waseda University, Japan

Core-Level spectroscopy. Experiments and first-principles calculations. Tomoyuki Yamamoto. Waseda University, Japan Core-Level spectroscopy Experiments and first-principles calculations Tomoyuki Yamamoto Waseda University, Japan 22 nd WIEN2k workshop Jun. 26 th, 2015@Singapore Outline What is core-level spectroscopy

More information

Massively parallel electronic structure calculations with Python software. Jussi Enkovaara Software Engineering CSC the finnish IT center for science

Massively parallel electronic structure calculations with Python software. Jussi Enkovaara Software Engineering CSC the finnish IT center for science Massively parallel electronic structure calculations with Python software Jussi Enkovaara Software Engineering CSC the finnish IT center for science GPAW Software package for electronic structure calculations

More information

Quantum Modeling of Solids: Basic Properties

Quantum Modeling of Solids: Basic Properties 1.021, 3.021, 10.333, 22.00 : Introduction to Modeling and Simulation : Spring 2011 Part II Quantum Mechanical Methods : Lecture 5 Quantum Modeling of Solids: Basic Properties Jeffrey C. Grossman Department

More information

Half-metallicity in Rhodium doped Chromium Phosphide: An ab-initio study

Half-metallicity in Rhodium doped Chromium Phosphide: An ab-initio study Half-metallicity in Rhodium doped Chromium Phosphide: An ab-initio study B. Amutha 1,*, R. Velavan 1 1 Department of Physics, Bharath Institute of Higher Education and Research (BIHER), Bharath University,

More information

Some notes on efficient computing and setting up high performance computing environments

Some notes on efficient computing and setting up high performance computing environments Some notes on efficient computing and setting up high performance computing environments Andrew O. Finley Department of Forestry, Michigan State University, Lansing, Michigan. April 17, 2017 1 Efficient

More information

Bonding of hexagonal BN to transition metal surfaces: An ab initio density-functional theory study

Bonding of hexagonal BN to transition metal surfaces: An ab initio density-functional theory study PHYSICAL REVIEW B 78, 4549 8 Bonding of hexagonal BN to transition metal surfaces: An ab initio density-functional theory study Robert Laskowski, Peter Blaha, and Karlheinz Schwarz Institute of Materials

More information

ELECTRONIC AND MAGNETIC PROPERTIES OF BERKELIUM MONONITRIDE BKN: A FIRST- PRINCIPLES STUDY

ELECTRONIC AND MAGNETIC PROPERTIES OF BERKELIUM MONONITRIDE BKN: A FIRST- PRINCIPLES STUDY ELECTRONIC AND MAGNETIC PROPERTIES OF BERKELIUM MONONITRIDE BKN: A FIRST- PRINCIPLES STUDY Gitanjali Pagare Department of Physics, Sarojini Naidu Govt. Girls P. G. Auto. College, Bhopal ( India) ABSTRACT

More information

Preconditioned Parallel Block Jacobi SVD Algorithm

Preconditioned Parallel Block Jacobi SVD Algorithm Parallel Numerics 5, 15-24 M. Vajteršic, R. Trobec, P. Zinterhof, A. Uhl (Eds.) Chapter 2: Matrix Algebra ISBN 961-633-67-8 Preconditioned Parallel Block Jacobi SVD Algorithm Gabriel Okša 1, Marián Vajteršic

More information

Introduction of XPS Absolute binding energies of core states Applications to silicene

Introduction of XPS Absolute binding energies of core states Applications to silicene Core level binding energies in solids from first-principles Introduction of XPS Absolute binding energies of core states Applications to silicene arxiv:1607.05544 arxiv:1610.03131 Taisuke Ozaki and Chi-Cheng

More information

The Augmented Spherical Wave Method

The Augmented Spherical Wave Method Introduction Institut für Physik, Universität Augsburg Electronic Structure in a Nutshell Outline 1 Fundamentals Generations 2 Outline 1 Fundamentals Generations 2 Outline Fundamentals Generations 1 Fundamentals

More information

Parallelization of the QC-lib Quantum Computer Simulator Library

Parallelization of the QC-lib Quantum Computer Simulator Library Parallelization of the QC-lib Quantum Computer Simulator Library Ian Glendinning and Bernhard Ömer VCPC European Centre for Parallel Computing at Vienna Liechtensteinstraße 22, A-19 Vienna, Austria http://www.vcpc.univie.ac.at/qc/

More information

Supporting Information

Supporting Information Supporting Information The Origin of Active Oxygen in a Ternary CuO x /Co 3 O 4 -CeO Catalyst for CO Oxidation Zhigang Liu, *, Zili Wu, *, Xihong Peng, ++ Andrew Binder, Songhai Chai, Sheng Dai *,, School

More information

Modeling and visualization of molecular dynamic processes

Modeling and visualization of molecular dynamic processes JASS 2009 Konstantin Shefov Modeling and visualization of molecular dynamic processes St-Petersburg State University Physics faculty Department of Computational Physics Supervisor PhD Stepanova Margarita

More information

Band Structure Calculations; Electronic and Optical Properties

Band Structure Calculations; Electronic and Optical Properties ; Electronic and Optical Properties Stewart Clark University of Outline Introduction to band structures Calculating band structures using Castep Calculating optical properties Examples results Some applications

More information

NHM Tutorial Part I. Brief Usage of the NHM

NHM Tutorial Part I. Brief Usage of the NHM 1 / 22 NHM Tutorial Part I. Brief Usage of the NHM Syugo HAYASHI (Forecast Research Department / Meteorological Research Institute) 2 / 18 Overall Index (Tutorial_0~3) 0. What is the NHM? NHM_Tutorial_0.ppt

More information

This work was performed under the auspices of the U.S. Department of Energy by Lawrence Livermore National Laboratory under contract

This work was performed under the auspices of the U.S. Department of Energy by Lawrence Livermore National Laboratory under contract This work was performed under the auspices of the U.S. Department of Energy by under contract DE-AC52-7NA27344. Lawrence Livermore National Security, LLC The ITER tokamak Tungsten (W) is attractive as

More information

FEAST eigenvalue algorithm and solver: review and perspectives

FEAST eigenvalue algorithm and solver: review and perspectives FEAST eigenvalue algorithm and solver: review and perspectives Eric Polizzi Department of Electrical and Computer Engineering University of Masachusetts, Amherst, USA Sparse Days, CERFACS, June 25, 2012

More information

ab initio Electronic Structure Calculations

ab initio Electronic Structure Calculations ab initio Electronic Structure Calculations New scalability frontiers using the BG/L Supercomputer C. Bekas, A. Curioni and W. Andreoni IBM, Zurich Research Laboratory Rueschlikon 8803, Switzerland ab

More information

INITIAL INTEGRATION AND EVALUATION

INITIAL INTEGRATION AND EVALUATION INITIAL INTEGRATION AND EVALUATION OF SLATE PARALLEL BLAS IN LATTE Marc Cawkwell, Danny Perez, Arthur Voter Asim YarKhan, Gerald Ragghianti, Jack Dongarra, Introduction The aim of the joint milestone STMS10-52

More information

Large Scale Electronic Structure Calculations

Large Scale Electronic Structure Calculations Large Scale Electronic Structure Calculations Jürg Hutter University of Zurich 8. September, 2008 / Speedup08 CP2K Program System GNU General Public License Community Developers Platform on "Berlios" (cp2k.berlios.de)

More information

Using Web-Based Computations in Organic Chemistry

Using Web-Based Computations in Organic Chemistry 10/30/2017 1 Using Web-Based Computations in Organic Chemistry John Keller UAF Department of Chemistry & Biochemistry The UAF WebMO site Practical aspects of computational chemistry theory and nomenclature

More information

Performance Evaluation of Some Inverse Iteration Algorithms on PowerXCell T M 8i Processor

Performance Evaluation of Some Inverse Iteration Algorithms on PowerXCell T M 8i Processor Performance Evaluation of Some Inverse Iteration Algorithms on PowerXCell T M 8i Processor Masami Takata 1, Hiroyuki Ishigami 2, Kini Kimura 2, and Yoshimasa Nakamura 2 1 Academic Group of Information

More information

Supporting Online Material

Supporting Online Material Supporting Online Material Materials and methods The binding energy per one sulfur atom in the GB with respect to the atomic gas state of sulfur, Eb GB, is calculated as follows. Eb GB N S = Etot GB (N

More information

Electronic, magnetic and spectroscopic properties of free Fe clusters

Electronic, magnetic and spectroscopic properties of free Fe clusters Electronic, magnetic and spectroscopic properties of free Fe clusters O. Šipr 1, M. Košuth 2, J. Minár 2, S. Polesya 2 and H. Ebert 2 1 Institute of Physics, Academy of Sciences of the Czech Republic,

More information

Introduction of XPS Absolute binding energies of core states Applications to silicone Outlook

Introduction of XPS Absolute binding energies of core states Applications to silicone Outlook Core level binding energies in solids from first-principles Introduction of XPS Absolute binding energies of core states Applications to silicone Outlook TO and C.-C. Lee, Phys. Rev. Lett. 118, 026401

More information

Supporting Information

Supporting Information Supporting Information Yi et al..73/pnas.55728 SI Text Study of k z Dispersion Effect on Anisotropy of Fermi Surface Topology. In angle-resolved photoemission spectroscopy (ARPES), the electronic structure

More information

Self-compensating incorporation of Mn in Ga 1 x Mn x As

Self-compensating incorporation of Mn in Ga 1 x Mn x As Self-compensating incorporation of Mn in Ga 1 x Mn x As arxiv:cond-mat/0201131v1 [cond-mat.mtrl-sci] 9 Jan 2002 J. Mašek and F. Máca Institute of Physics, Academy of Sciences of the CR CZ-182 21 Praha

More information

Schwarz-type methods and their application in geomechanics

Schwarz-type methods and their application in geomechanics Schwarz-type methods and their application in geomechanics R. Blaheta, O. Jakl, K. Krečmer, J. Starý Institute of Geonics AS CR, Ostrava, Czech Republic E-mail: stary@ugn.cas.cz PDEMAMIP, September 7-11,

More information

Size- and site-dependence of XMCD spectra of iron clusters from ab-initio calculations

Size- and site-dependence of XMCD spectra of iron clusters from ab-initio calculations Size- and site-dependence of XMCD spectra of iron clusters from ab-initio calculations O. Šipr 1 and H. Ebert 2 1 Institute of Physics, Academy of Sciences of the Czech Republic, Cukrovarnická 10, 162

More information

Exercises: In the following you find some suggestions for exercises, which teach you various tasks one may perform with WIEN2k.

Exercises: In the following you find some suggestions for exercises, which teach you various tasks one may perform with WIEN2k. Exercises: In the following you find some suggestions for exercises, which teach you various tasks one may perform with WIEN2k. New WIEN2k users should start with the first basic exercises (1-5), covering:

More information

Development of Transferable Materials Information and Knowledge Base for Computational Materials Science

Development of Transferable Materials Information and Knowledge Base for Computational Materials Science Chapter Epoch Making Simulation Development of Transferable Materials Information and Knowledge Base for Computational Materials Science Project Representative Shuhei Ohnishi Authors Shuhei Ohnishi CAMP

More information

Introduction to Hartree-Fock calculations in Spartan

Introduction to Hartree-Fock calculations in Spartan EE5 in 2008 Hannes Jónsson Introduction to Hartree-Fock calculations in Spartan In this exercise, you will get to use state of the art software for carrying out calculations of wavefunctions for molecues,

More information

The Munich SPRKKR-program package A spin polarised relativistic Korringa-Kohn-Rostoker code for calculating solid state properties

The Munich SPRKKR-program package A spin polarised relativistic Korringa-Kohn-Rostoker code for calculating solid state properties The Munich SPRKKR-program package A spin polarised relativistic Korringa-Kohn-Rostoker code for calculating solid state properties Ján Minár H. Ebert, M. Battocletti, D. Benea, S. Bornemann, J. Braun,

More information

SPARSE SOLVERS POISSON EQUATION. Margreet Nool. November 9, 2015 FOR THE. CWI, Multiscale Dynamics

SPARSE SOLVERS POISSON EQUATION. Margreet Nool. November 9, 2015 FOR THE. CWI, Multiscale Dynamics SPARSE SOLVERS FOR THE POISSON EQUATION Margreet Nool CWI, Multiscale Dynamics November 9, 2015 OUTLINE OF THIS TALK 1 FISHPACK, LAPACK, PARDISO 2 SYSTEM OVERVIEW OF CARTESIUS 3 POISSON EQUATION 4 SOLVERS

More information

EXPERIMENTAL VERIFICATION OF CALCULATED LATTICE. RELAXATIONS AROUND IMPURITIES IN CdTe

EXPERIMENTAL VERIFICATION OF CALCULATED LATTICE. RELAXATIONS AROUND IMPURITIES IN CdTe EXPERIMENTAL VERIFICATION OF CALCULATED LATTICE RELAXATIONS AROUND IMPURITIES IN CdTe HFI2004 H.-E. Mahnke 1*, H. Haas 1, V. Koteski 1,2, N. Novakovic 1,2, P. Fochuk 3, and O. Panchuk 3 1 HMI Berlin GmbH,

More information

Some surprising results of the Kohn-Sham Density Functional

Some surprising results of the Kohn-Sham Density Functional arxiv:1409.3075v1 [cond-mat.mtrl-sci] 10 Sep 2014 Some surprising results of the Kohn-Sham Density Functional L. G. Ferreira 1, M. Marques 2, L. K. Teles 2, R. R. Pelá 2 1 Instituto de Física, Universidade

More information

Fundamentals and applications of Density Functional Theory Astrid Marthinsen PhD candidate, Department of Materials Science and Engineering

Fundamentals and applications of Density Functional Theory Astrid Marthinsen PhD candidate, Department of Materials Science and Engineering Fundamentals and applications of Density Functional Theory Astrid Marthinsen PhD candidate, Department of Materials Science and Engineering Outline PART 1: Fundamentals of Density functional theory (DFT)

More information

Cyclops Tensor Framework: reducing communication and eliminating load imbalance in massively parallel contractions

Cyclops Tensor Framework: reducing communication and eliminating load imbalance in massively parallel contractions Cyclops Tensor Framework: reducing communication and eliminating load imbalance in massively parallel contractions Edgar Solomonik 1, Devin Matthews 3, Jeff Hammond 4, James Demmel 1,2 1 Department of

More information

A Quantum Chemistry Domain-Specific Language for Heterogeneous Clusters

A Quantum Chemistry Domain-Specific Language for Heterogeneous Clusters A Quantum Chemistry Domain-Specific Language for Heterogeneous Clusters ANTONINO TUMEO, ORESTE VILLA Collaborators: Karol Kowalski, Sriram Krishnamoorthy, Wenjing Ma, Simone Secchi May 15, 2012 1 Outline!

More information

All-electron density functional theory on Intel MIC: Elk

All-electron density functional theory on Intel MIC: Elk All-electron density functional theory on Intel MIC: Elk W. Scott Thornton, R.J. Harrison Abstract We present the results of the porting of the full potential linear augmented plane-wave solver, Elk [1],

More information

Efficient algorithms for symmetric tensor contractions

Efficient algorithms for symmetric tensor contractions Efficient algorithms for symmetric tensor contractions Edgar Solomonik 1 Department of EECS, UC Berkeley Oct 22, 2013 1 / 42 Edgar Solomonik Symmetric tensor contractions 1/ 42 Motivation The goal is to

More information

Before we start: Important setup of your Computer

Before we start: Important setup of your Computer Before we start: Important setup of your Computer change directory: cd /afs/ictp/public/shared/smr2475./setup-config.sh logout login again 1 st Tutorial: The Basics of DFT Lydia Nemec and Oliver T. Hofmann

More information

Wannier Function Based First Principles Method for Disordered Systems

Wannier Function Based First Principles Method for Disordered Systems Wannier Function Based First Principles Method for Disordered Systems Tom Berlijn Stony Brook University & Brookhaven National Laboratory Excitations in Condensed Matter: From Basic Concepts to Real Materials

More information

Improving the solar cells efficiency of metal Sulfide thin-film nanostructure via first principle calculations

Improving the solar cells efficiency of metal Sulfide thin-film nanostructure via first principle calculations Improving the solar cells efficiency of metal Sulfide thin-film nanostructure via first principle calculations Alwaleed Adllan Abusin, PhD Elzina Bala Africa City of Technology Agenda INTRODUCTION TO HIGH-PERFORMANCE

More information

GPU acceleration of Newton s method for large systems of polynomial equations in double double and quad double arithmetic

GPU acceleration of Newton s method for large systems of polynomial equations in double double and quad double arithmetic GPU acceleration of Newton s method for large systems of polynomial equations in double double and quad double arithmetic Jan Verschelde joint work with Xiangcheng Yu University of Illinois at Chicago

More information

Solving the Inverse Toeplitz Eigenproblem Using ScaLAPACK and MPI *

Solving the Inverse Toeplitz Eigenproblem Using ScaLAPACK and MPI * Solving the Inverse Toeplitz Eigenproblem Using ScaLAPACK and MPI * J.M. Badía and A.M. Vidal Dpto. Informática., Univ Jaume I. 07, Castellón, Spain. badia@inf.uji.es Dpto. Sistemas Informáticos y Computación.

More information

SESSION 2. (September 26, 2000) B. Lake Spin-gap and magnetic coherence in a high-temperature superconductor

SESSION 2. (September 26, 2000) B. Lake Spin-gap and magnetic coherence in a high-temperature superconductor SESSION 2 (September 26, 2000) Spin fluctuations and stripes - I S2-I G. Shirane Stripes in Sr doped La 2 CuO 4 insulators and superconductors S2-II B. Lake Spin-gap and magnetic coherence in a high-temperature

More information
2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback