A/Prof. Anthony G. Williams

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Title: A/Prof. Anthony G. Williams

1
Probing the Heart of Matter
A/Prof. Anthony G. Williams CSSMAdelaide
University 22 November 2001, Melbourne
2
Outline of Talk

Introduction and Context
Special Research Centre for the Subatomic
Structure of Matter (CSSM)
The Standard Model of Particle Physics
Quantum Chromodynamics (QCD)
Quarks and Gluons and the Origin of 98 of the
Mass of Tangible Matter
Lattice Gauge Theory and Lattice QCD
Orion Supercomputer
Centre for High-Performance Computing and
Applications (CHPCA)
Conclusions and Outlook

3
Introduction and Context

Strongly interacting matter makes up almost the
entire mass of the tangible universe, from the
protons and neutrons in the nuclei of atoms and
molecules to neutron stars.
The strong interaction fuels the sun and stars
and determines which nuclei are stable and hence
which elements can exist.
The underlying theory of the strong interaction
is called quantum chromodynamics (QCD) and has
quarks (like electrons) and gluons (like photons
but self-interacting) as its fundamental
constituents.
Quarks and gluons are bound so strongly together
that they can never appear as free particles.
This is called confinement.
When probed at increasingly higher energies the
interaction between them becomes progressively
weaker. This is called asymptotic freedom.
The quarks in your body represent only about 2
of your mass with the rest of your mass being
generated by the strong interaction itself.
The world's fastest supercomputers are being used
to improve our understanding of the strong
interaction and the unusual properties of quarks
and gluons.

4
Concepts

Strongly interacting matter is referred to as
hadronic matter and strongly interacting
particles are called hadrons, e.g., protons,
neutrons, and pions are all hadrons
Hadrons with 1/2 integer spin (e.g., 1/2, 3/2,
5/2,) are fermions and are called baryons.
Protons and neutrons are baryons.
Hadrons with integer spin (e.g., 0, 1, 2, ) are
bosons and are called mesons. The pion is a
meson.
Nuclei consist of protons and neutrons bound
together by the strong interaction.
The elements and hence all of chemistry is
determined by which nuclei are stable.

Boson Bose-Einstein statistics Fermion
Fermi-Dirac statistics
5
Scales

Typical atomic size is 10-10 m 1 Angstrom
Typical nuclear sizes are 10-14 m 10 fermi
1 fermi 1 fm 10-15 m
Proton radius is 0.8 fm,i.e., approximately 1 fm
No substructure of electrons or quarks has ever
been observed at resolutions down to
approximately 1/100,000,000 Angstroms 10-18 m.
At the present time we assume that electrons and
quarks are elementary particles.

6
Atomic Structure

Warning Sketch not to scale!
If the protons and neutrons in this nucleus are
10cm across then
the nucleus is about 100cm across,
the electrons and quarks are less than 0.1mm
across,
and the atom is 10km across!

7
Fundamental Forces

There are four fundamental forces which are
believed to give rise to all observed physical
phenomena.
Gravity holds us to the earth, binds stars,
solar systems, galaxies, etc.
Electromagnetic e.m. radiation, chemistry hence
biology, touch, electronics, etc.
Weak radioactivity, neutrino physics of
supernovae, etc.
Strong all familiar matter, nuclear energy,
powers sun and stars, etc.

8
Special Research Centre for the Subatomic
Structure of Matter (CSSM)

The CSSM is a Special Research Centre of the
Australian Research Council (ARC)
funded for nine years (since 1997) to carry out
theoretical research in subatomic physics.
Mission
- Make major advances in the understanding of
the structure of hadronic matter
- Cross fertilization enhances opportunities for
breakthroughs in understanding
- Pursue lattice, models, phenomenology, and
strong links to experimental results
- Develop strong international links, exchanges
Personnel
- High level postgraduate and postdoctoral
training
- Interact with best researchers in a
stimulating atmosphere
Service
- LANL Archive for Australia- Workshop program
(support external students and affiliate staff)
- Stimulate school students to science
(brochures, school visits) - Physics Guru,
Public Lectures, Newspapers, radio, Television

9
CSSM Current Academic Staff

Professor Anthony Thomas (Director)
A/Prof. Anthony Williams (Deputy Director)
Dr. P. Coddington
Dr. Alex Kalloniatis (Australian Research Fellow)
Dr. Derek Leinweber
Dr. Andreas Schreiber (Australian Research
Fellow)
Dr. Ingo Bojak
Dr. Xin-Heng Guo
Dr. Ayse Kizilersü
Dr. Vadim Guzey
Dr. Martin Oettel (joint appointment Alexander
von Humbolt Stiftung/Foundation CSSM)
Dr. Jianbo Zhang

10
Postgraduate Students

Sundance Bilson-Thompson (Ph.D.). Supervisors
D.B. Leinweber A.G. Williams
Francois Bissey (Ph.D.). Cotutelle (U. Blaise
Pascal) A.W. Thomas.
Frederic Bonnet (Ph.D.). Supervisors D.B.
Leinweber A.G. Williams.
Patrick Bowman (Ph.D.). Supervisors D.B.
Leinweber A.G. Williams position at Florida
State Univ.
Shane Braendler (Ph.D.). Supervisor A.W.
Thomas
Will Detmold (Ph.D.). Supervisors A. Bender
A.W. Thomas
Emily Hackett-Jones (M.Sc.). Supervisors D.B.
Leinweber A.W. Thomas

Waseem Kamleh (Ph.D.). Supervisor A.G.
Williams
Daniel Kusterer (M.Sc. Baden-Wuerttemberg/S.A.
Exchange Program) - Supervisor D.B. Leinweber
Olivier Leitner (Ph.D.). Cotutelle (U. Blaise
Pascal) A.W. Thomas
Tom Sizer (Ph.D.). Supervisor A.G. Williams
Stewart Wright (Ph.D.). Supervisors D.B.
Leinweber A.W. Thomasposition at Liverpool,
UK.
Ross Young (Ph.D.). Supervisors D.B. Leinweber
A.W. Thomas
James Zanotti (Ph.D.). Supervisors D.B.
Leinweber A.G. Williams

11
International Collaborative Agreements

Abdus Salam International Centre for Theoretical
Physics - Italy
Argonne National Laboratory - USA
Bonn University - Germany
Chinese Academy of Sciences (Beijing) - China
Commissariat à l'Energie Atomique - France
European Centre for Theoretical Studies in
Nuclear Physics and Related Areas (Trento) -
Europe
Indiana University (Bloomington) - USA
Institute for Nuclear Theory, University of
Washington (Seattle) - USA
Instituto De Fisica Teòrica (IFT-UNESP) - Brazil
Joint Institute for Nuclear Research (JINR -
Dubna) - Russia
Jülich (FZ) - Germany

12
International Collaborative Agreements (cont.)

MESON (Medium Energy Science Open Network)
involving IUCF Indiana Yonsei, Korea RCNP
Osaka KVI Groningen IMP Lanzhou TSL Uppsala
NAC Cape Town SAHA Calcutta FZ Jülich CIAE
Beijing
Osaka University - Japan
Computational Science and Information Technology
(CSIT, Florida) - USA
Svedberg Laboratory - Sweden
Thomas Jefferson National Accelerator Facility
(Newport News) - USA
Technical University of Munich - Germany
TRIUMF (Vancouver) - Canada
Université Blaise Pascal - France
University of Tübingen - Germany

13
CSSM Workshops/Conferences 2000

3rd International Symposium on Symmetries in
Subatomic Physics - MarchTotal Number of
Participants 85Overseas Participants
45Interstate Participants 12Local
Participants 28
International Conference on Quark Nuclear Physics
- FebruaryTotal Number of Participants
109Overseas Participants 75Interstate
Participants 1Local Participants 33
HallD Workshop - FebruaryTotal Number of
Participants 45Overseas Participants
24Interstate Participants NilLocal
Participants 21

14
CSSM Workshops/Conferences 2001

Lattice Hadron Physics Workshop - JulyTotal
Number of Participants 42Overseas Participants
26Interstate Participants 1Local Participants
15
Hamiltonian Lattice Gauge Theories Workshop -
AprilTotal Number of Participants 19Overseas
Participants NilInterstate Participants
4Local Participants 15
Leptonic Scattering Workshop - MarchTotal Number
of Participants 64Overseas Participants
35Local Participants 29

15
Visitor Program 2001

Dr. P. Bowman, Florida, USA
Dr. A. Chian, Sao Paolo, Brazil
Dr. M. Chaichian, Helsinki
Dr. G. Dunne, Connecticut
Dr. Y. Hoshino, Kushiro, Japan
Dr. C.-S. Huang, Beijing, China
Prof. A. Ioannides, RIKEN, Japan
Dr. S. Krewald, Jueilich, Germany
Dr. R. Landau, Oregon, USA
Dr. D. Lu, Zhejiang, China
Prof. W.-X. Ma, Beijing, China

Dr. K. Maltman, York, Canada
Dr. S. Sharpe, Seattle, USA
Dr. A. Signal, Massey, NZ
Dr. D. Sinclair, Argonne, USA
Prof. J. Speth, Juelich, Germany
Dr. P. Tandy, Ohio, USA
Dr. G. Valencia, Iowa, USA
Prof. M. Veltman, Utrecht
Dr. J. Vergados, Ionnina, Greece
Dr. L. von Smekal, Erlangen
Dr. M. Weyrauch, Bundesanstalt, Germany

16
Future Workshops

Joint Workshop with JHF, March 2002
The Structure of the Nucleon (Joint with ECT in
Trento), September 2002
NUPP Summer School, February 2003
2nd Lattice Workshop, Cairns, June/July(?) 2003

17
The Standard Model
Let us review some aspects of the standard model
briefly before beginning to focus on QCD itself.
18
The Standard Model Fermions

In addition to the 6 known flavors of quarks they
come in 3 colours red, blue, and green
Lepton comes from the Greek for small mass
Leptons do not carry color charge, i.e., they do
not feel the strong force

19
The Standard Model Bosons

The very massive W-, W, and Z0 bosons mediate
the weak interaction, which as a result is very
short range
The massless photon mediates the long-range e.m.
interactions
Gluons carry color and mediate the strong
interaction

20
The Standard Model Forces

Gravitons are thought to mediate the
gravitational force but have not yet been seen
Gravitational waves are to gravitons what e.m.
radiation is to photons
Above we see the relative strengths and relative
ranges of the four fundamental forces

21
Standard Model Sample Processes

Standard model processes and interactions
neutron beta decay (neutrons are only stable in
nuclei which is just as well!) - imagine the
universe if this was not so ...
electron-positron annihilation to meson-antimeson
pair
proton-proton collision producing two Z0 bosons
and other hadrons

22
Early Universe

Free quarks and gluons existed until about 10-5
seconds
atoms formed at about 300,000 years
stars formed at about 1 billion years
solar systems and life at about 12 billion years

23
Neutron Stars

Different phases of hadronic matter can co-exist
within a neutron star.
For this sample neutron star, it is expected that
quark matter becomes a stable phase 1km beneath
the surface.
In the central core quark matter is dominant.

24
Neutron Star Phase vs Density

Protons and neutrons are collectively referred to
as nucleons
Ordinary nuclear matter density is approximately
0.17 nucleons/fm-3

?
25
Quantum Chromodynamics (QCD)

All hadrons are color-singlet (white)
Baryons contain three quarks (red blue green)
- Different baryons arise from the three quarks
having different flavor combinations.
Mesons contain colour anticolour combinations
of quark and antiquark pairs (red anti-red,
green anti-green, blue anti-blue) - Different
mesons arise from different flavor combinations
of the pair.
Each flavor of quark cycles through the three
colors by exchanging gluons with the other quarks
or anti-quark.

26
QCD Nuclear Forces
All hadrons are color-singlet (neutral or
colorless or white) combinations of quarks (3
quarks for baryons or quark-antiquark pair for
mesons). But just as electrically neutral atoms
interact by van der Waals forces, so can color
neutral particles. This has very important
consequences the strong nuclear force.

and hence to atoms, molecules, chemistry, and
all of biology.

27
QCD Baryons and Antibaryons

Baryons are color-singlet combinations of three
quarks.
Anti-baryons are color-singlet combinations of
three anti-quarks.

28
QCD Mesons

Mesons are made up of a quark - anti-quark pair
with equal and opposite color charges giving a
color-singlet.

29
Confinement

The strong force between two quarks arises from
the exchange of gluons.
There is also a strong force between two gluons -
since they carry color themselves they can
interact with each other. This is not the case
for photons in QED since they carry no electric
charge.
The force between two quarks is constant, i.e.,
independent of their separation. This
corresponds to a linearly rising potential
between them, which is referred to as a string
tension.
This force between colored objects is equivalent
to a wieight of approximately 10 tons! - This is
why no free quarks or gluons are ever seen. QCD
has the property of CONFINEMENT.

30
String Breaking Quark - Anti-quark Pairs

What happens when we try to pull apart two
colored objects by pumping more and more energy
into the system, e.g., through energetic
collisions at a particle accelerator?
When the energy put in is large enough to make a
quark - anti-quark pair, then a meson can be
created and the string is broken.

Confinement survives however as no free color
particles are produced.

31
Asymptotic Freedom

In quantum electrodynamics (QED) the fine
structure constant is ? ? 1/137.
In QCD the coupling runs by decreasing with
increasing energy scale, i.e., at short
distances.
At the energy scale of the Z0 mass the strong
coupling constant has decreased to a value ?s
?0.12.
Quarks and gluons appear almost free at high
energies.
At low energies ?s ? 1, i.e., the coupling is
very STRONG and perturbation theory fails..

ASYMPTOTIC FREEDOM
32
Strong Coupling Constant at Z Mass

At the energy scale of the Z0 mass the strong
coupling constant has decreased to ?s ?0.12.
This has been confirmed in a variety of different
experiments with a remarkable degree of
consistency.

33
QCD Produces 98 of Your Mass

Proton mass is 938 MeV 0.938 GeV.
Up and down quark masses are approximately 3 and
6 MeV respectively.

Where does the rest of the hadron mass come from?

The interactions in the low-energy
(long-distance) are so strong (i.e.,
non-perturbative) that they induce a mass in the
quarks of approximately 300 MeV. This is
referred to as dynamical mass generation.
This is how three quarks in a bound state can
have a mass exceeding their naïve sum.
The fact that the up and down quarks are so light
and because of this mass-generation, Goldstones
theorem states that there will be nearly massless
Goldstone bosons associated with the spontaneous
breaking of this symmetry - these Goldstone
bosons are the pions which are anomalously light
mesons. This is the basis of what is called
chiral symmetry and dynamical chiral symmetry
breaking.

34
Lattice Gauge Theory

Physicists at the CSSM and elsewhere use the
techniques of lattice gauge theory to put all of
four-dimensional space-time on a grid or lattice.
We formulate the gauge field theory (e.g., QED,
QCD, etc.) on this discrete lattice with
finite-difference techniques. This is done in
Euclidean space-time for numerical reasons. We
use methods adapted from statistical mechanics to
study the physical properties of the theory from
the confining to the asymptotically free regimes.
We use this to study and model subatomic
particles and their interactions. It is VERY
computationally expensive to do this -
Teraflop-years of computer time are needed.
More accurate results need a finer lattice with
larger space-time volumes. This is what makes it
computationally costly.

35
Lattice QCD
Depiction of electron scattering from quark
through a virtual photon exchange in a
background gluon field. Lattice QCD does
weighted averages over gauge field configurations
to obtain physical quantities of interest.
36
Lattice QCD Gluon Configurations

Typical gluon field configuration used in lattice
calculations, (3-dim slice of 4-dim lattice
showing action density, where red depicts
highest).
The estimate of the integral over gluon fields
does a weighted average over hundreds of these.

37
High-Performance Computing

Traditionally supercomputers were very expensive,
contained purpose-built hardware, and were
obsolete within 5 years.
Most modern high-performance computing uses
cost-effective clusters of mass-produced
commodity off-the-shelf (COTS) hardware, rather
than expensive proprietary hardware.
These clusters of workstations or PCs are
connected either by commodity Fast Ethernet or
Gigabit switched networking or by (more
expensive) special ultrafast, low-latency
networks for clustering (e.g., Myrinet,
ServerNet, GigaNet, SCI, etc).
Clusters are flexible in their design and easy to
build and upgrade - e.g., add more nodes upgrade
some or all of the nodes upgrade some or all of
the networking.
Can get an order of magnitude better
price/performance ratio!

38
Top 500 Supercomputers

Clusters of PCs or Unix workstations have become
incredibly popular in the last few years --
ranging from a few networked PCs to around 1000
Compaq Alpha workstations.
The unit used to measure the performance of
computers is the flop, i.e., 1 flop 1
floating-point operation per second.
In other words 1 flop 1 calculation per
second.
The 12 fastest supercomputers in the world all
exceed 1 Teraflop, i.e., 1 Teraflop 1,000
Gigaflops 1,000 billion calculations per
second.
The current fastest is 7.2 Teraflops, (cluster
with 8,192 CPUs called ASCI White at Lawrence
Livermore National Laboratory in the USA- models
nuclear explosions in place of nuclear tests).
Three of the top 4 machines serve this same
purpose.

39
Top 500 Supercomputers (cont.)

The fastest supercomputer in Australia at present
is the NEC SX-5/32M2 at the CSIRO Bureau of
Meteorology in Melbourne. It is number 99 in the
world and is 241.4 /(256 peak) Gigaflops.
The current second fastest is the APAC facility
at ANU in Canberra, which is a Compaq alpha
workstation cluster and is number 134 in the
world and 167.5/(245 peak) Gigaflops. It will
very soon be upgraded to 980 peak Gigaflops
(almost a Teraflop peak) and at that time will be
Australias fastest.
The third is a similar Compaq cluster run by VPAC
in Melbourne and is number 151 at 149.1/(213
peak) Gigaflops.
Fourth is our own Sun cluster in Adelaide, called
Orion, which is number 246 at 110/(144 peak)
Gigaflops.

40
Cluster Computing Architectures

Many possible design choices in building a
compute cluster -- depends on type of application
(or applications).
Unix workstations or Beowulf PC cluster?
What processor, clock speed, cache, bus speed,
etc?
Single processor or Shared-Memory Processor (SMP)
nodes?
Linux or commercial operating system (OS)?
How much memory and disk per node?
Buy from vendor or systems integrator, or build
it yourself?
What networking technology to use?
Commodity Fast or Gigabit switched ethernet is
relatively cheap, but has high latency.
Low-latency, ultra-fast networks are
significantly more expensive, but far superior.

41
Orion Supercomputer

Orion is a Sun Technical Compute Farm with 40 Sun
E420R 4-way SMP nodes (160 processors). Fast
switched ethernet AND high-speed Myrinet network.
110/(144 peak) Gflops, 160 Gigabytes RAM, 640
Megabytes cache memory.
Fastest computer in Australia when installed in
June 2000 and now number 4.
The CSSM together with lattice theorists from
UNSW and the University of Melbourne obtained
RIEF funds to seed the National Computing
Facility for Lattice Gauge Theory (NCFLGT) which
houses the Orion supercomputer.

42
Orion Software

Nodes run Solaris and standard Sun software and
compilers.
Sun HPC ClusterTools includes
Sun Cluster Runtime Environment (CRE)
Sun MPI, optimized for SMP cluster (and recently
for Myrinet)
Sun Scientific Software Library (S3L)
Prism debugger and performance analysis tool
S3L and Prism are developed from CM software.
Sun Fortran 90/95 compiler, supports automated
parallelisation and OpenMP directives for shared
memory parallelism.
Portland Group HPF compiler, converts code to Sun
F77/90 plus MPI.
Sun Grid Engine (formerly CODINE) cluster
management system is more advanced than CRE,
supports batch queueing, detailed logging of
system usage, access levels, etc.

43
Centre for High-Performance Computing and
Applications (CHPCA)

The CHPCA is a newly created cross-disciplinary
Research Centre at Adelaide University. Its goal
is to bring together all researchers with an
interest and commitment to High-Performance
Computing (HPC) in order to share expertise and
to develop a very large shared computing
platform. Director AGW Deputy Directors Paul
Coddington (DHPC), Derek Lienweber (CSSM), and
Francis Vaughan (SAPAC).
Partner researchers include Physics, Chemistry,
Engineering, Biology and Bioinformatics, Plant
Science, Geology and Geophysics, Water Resource
Management, etc.
Next year (2002) the CHPCA already has enough
funds from its members and partners to construct
a 250 Gigaflop cluster consisting of 40 dual
processor 2 GHz Pentium 4 nodes with Myrinet 2000
cluster networking.
The goal is to raise funds to turn this into a
Teraflop supercomputer.

44
CHPCA Engineering Applications

Computational fluid dynamics.
Drag and noise reduction in planes, ships,
submarines, etc.
Petroleum geology, oil and gas reservoir
modeling.
Flow through porous media.
Water quality management and salinity.
Optimization of distribution systems for water
piplines, power lines, and telecommunication
networks.
Optimization of engineering design over a large
parameter space
search over multiple parameters using task farm
approach, many sequential jobs each with
different parameters

45
CHPCA Biological Applications

Bluegene - IBM plans to build a 1 Petaflop
computer to study fundamental problems in
computational biology and protein science - (1
Petaflop 1,000 Teraflops!) - 1 million
processors and each processor with multiple CPUs
and memory and communication logic built in.
Bluegene will focus on protein folding in
particular.
Modelling heart and brain function, organ and
arterial simulation - chaos, heart fibrillation,
epileptic seizures, etc.
The virtual human project - Oak Ridge National
Laboratory.
DNA and protein sequence analysis and
classification.
Genome data and bioinformatics - data farming
for efficient storage, recovery, searching and
matching of vast biological data, e.g., for
efficient drug design, etc.

46
Conclusions and Outlook

This is an exciting time for theoretical
subatomic physics in Australia.
The CSSM is continuing to build on its successes
and is highly productive.
The Australian lattice QCD program is now
well-established and runs a world-class
supercomputing facility.
With the establishment of a cross-disciplinary
CHPCA the path to a Teraflop computer and a
world-class resource for the coming years is
becoming a reality.
We look forward to new discoveries and new
opportunities in subatomic physics over the next
few years.
Cross-disciplinary activity in High-Performance
Computing research is becoming increasingly
important for the HPC field in order that
research areas that depend on it continue to
thrive. - We are working on that.
Thank you for your attention.