Fred Palma | Computer Scientist

BERKELEY, CA — A team of scientists from the U.S. Department of Energy’s Lawrence Berkeley National Laboratory (Berkeley Lab) has won a prestigious Gordon Bell Prize, sponsored by the Association for Computing Machinery (ACM), for special achievement in high performance computing for their research into the energy harnessing potential of nanostructures. Their method, which was used to predict the efficiency of a new solar cell material, achieved impressive performance and scalability.

The ACM Gordon Bell Prize annually recognizes the best performance of scientific applications on supercomputers. This year’s prize, presented in a special category for algorithm innovation, was announced Thursday, Nov. 20, at the awards session of the SC08 conference in Austin.
A test run of LS3DF, which took one hour on 17,000 processors of the Franklin supercomputer at NERSC), performed electronic structure calculations for a 3500-atom ZnTeO alloy. Isosurface plots (yellow) show the electron wavefunction squares for the bottom of the conduction band (left) and the top of the oxygen-induced band (right). The small grey dots are Zn atoms, the blue dots are Te atoms, and the red dots are oxygen atoms. (Image courtesy of Lin-Wang Wang)

The Berkeley Lab researchers used three of the most advanced scientific computing facilities of the Department of Energy (DOE) Office of Science for this award-winning work: the National Energy Research Scientific Computing Center (NERSC) at Berkeley Lab, the Argonne Leadership Computing Facilities (ALCF) at Argonne National Laboratory and the National Center of Computational Sciences (NCCS) at Oak Ridge National Laboratory. Their study was titled: “Linearly Scaling 3D Fragment Method for Large-Scale Electronic Structure Calculations.”

Nanostructures, tiny materials 100,000 times finer than a human hair, may hold the key to energy independence. Scientists believe that a fundamental understanding of nanostructure behaviors and properties could provide solutions for curbing our dependence on petroleum, coal and other fossil fuels.

To better understand and demonstrate the potential of nanostructures, the Berkeley Lab researchers simulated their behavior through development of the Linearly Scaling Three Dimensional Fragment (LS3DF) method. These computer algorithms use a novel “divide-and-conquer” technique to efficiently gain insights into how nanostructures function in systems with 10,000 or more atoms.

The LS3DF team consisted of Berkeley Lab’s Lin-Wang Wang, Byounghak Lee, Hongzhang Shan, Zhengji Zhao, Juan Meza, Erich Strohmaier and David Bailey, an agregate of materials scientists, mathematicians and computer scientists contributing their own special expertise to solve this problem.
Lin-Wang Wang, of Berkeley Lab’s Computational Research Division, led the development of the LS3DF algorithms, which used a novel “divide-and-conquer” technique to efficiently compute how nanostructures function in systems with 10,000 or more atoms.

The LS3DF application ultimately achieved a speed of 442 teraflop/s (442 trillion calculations per second) on a Cray XT5 system with 147,146 cores at the NCCS. The Berkeley Lab researchers were also able to run the code on the IBM BlueGene/P system at Argonne, reaching 224 teraflop/s on 163,840 cores, or 40.5 percent of the system’s peak performance capability.

The team first ran the LS3DF application on 36,864 cores of the Cray XT4 (Franklin) at NERSC, achieving 135 Tflop/s. These initial results at NERSC provided the key scientific insights from the application.

“By incorporating the correct chemical formulas into efficient computer programs, scientists can learn a lot about the structures and properties of molecules and solid,” said. Lin-Wang Wang, a computational material scientist who led the Berkeley Lab team. “I like to think of computers as chemistry’s third pillar. In most cases, computer simulations complement information obtained by chemical experiments, but in some cases they can also predict unobserved phenomena.”

A science run using LS3DF, which took one hour on 17,280 cores of the NERSC Franklin system, computed the electronic structure of a 3,500-atom ZnTeO alloy. This run verified that the code could be used to compute properties of the ZnTeO alloy that previously had been experimentally observed. The simulation led to a prediction for the efficiency of this alloy as a new solar cell material.

LS3DF offers a more efficient way for calculating energy potential because it is based on the observation that the total energy of a large nanostructure system can be broken down into small pieces, and each piece can be calculated separately. More traditional methods calculate the entire structure as a whole system and are much more time consuming and resource intensive. Because LS3DF scales almost perfectly with the number of compute cores, it is the first electronic structure code that runs efficiently on computer systems with tens to hundreds of thousands of cores.

“We are excited by the results we are seeing,” said LS3DF team member Meza, who heads Berkeley Lab’s High Performance Computing Research. “The efficiency of LS3DF on these large computer systems is impressive, but the real story is the power of algorithms. Using a linear scaling algorithm, we can now study systems that would otherwise take over 1,000 times longer on even the biggest machines today. Instead of hours, we would be talking about months of computer time for a single study.”

Getting codes to run with such high efficiencies on massively parallel machines is not a trivial task. Bailey, Shan and Strohmaier of the DOE Office of Science’s Scientific Discovery through Advanced Computing (SciDAC) Performance Engineering Research Institute (PERI) worked hand-in-hand with Wang and his colleagues to analyze the performance of LS3DF and to identify potential performance improvements. Responding to this analysis, Berkeley Lab researchers assisted with a major revision of the code, which led to the prize-winning submission.

“The computational power we have is staggering and it is important to make sure that each research project can effectively harness the power of Argonne’s Intrepid and optimize their calculations”, said Katherine Riley, the ALCF computational scientist who worked with the Berkeley Lab team. “Not only can we drastically reduce the time it takes to generate results, we can help scientists ask different questions and develop new insights in order to accelerate breakthroughs.”

Once the LS3DF code had been optimized it was a matter of days before it was running at each of the DOE supercomputing facilities. Oak Ridge National Laboratory invited Wang and other Gordon Bell finalists to carry out runs on ORNL’s leadership Cray supercomputer, Jaguar. In Wang’s case, the winning simulation was achieved after only two runs over a two-day period, demonstrating the ease of porting – and running – high-performance applications on the Cray XT architecture. The project had previously been awarded time on Jaguar under DOE’s Innovative and Novel Computational Impact on Theory and Experiment (INCITE) program.

“We still don’t quite understand how the electron moves around in a nanostructure, and how such properties depend on the size, geometry, composition and surface passivations,” said Wang. “Understanding this dependence will allow us to design nanostructures for desired applications. Using our improved LS3DF method will help us to understand and predict these properties.”

The ALCF, NCCS and NERSC are funded by the Office of Advanced Scientific Computing research in the DOE Office of Science, providing some of the world’s most powerful computing resources and support to thousands of researchers around the country.

Berkeley Lab is a U.S. Department of Energy national laboratory located in Berkeley, California. It conducts unclassified scientific research and is managed by the University of California. Visit our Website at www.lbl.gov

Additional Information

For more information about NERSC, visit: www.nersc.gov

For more information about the ALCF, visit: www.alcf.anl.gov

For more information about the NCCS, visit: www.nccs.gov

From Berkeley Lab

Tags: Energy, Nanotechnology by Fred
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From Can Huang, Ad Notten, and Nico Rasters – UNU-MERIT and Maastricht University

The paper provides a comprehensive review of more than 120 social science studies in nanoscience and technology, all of which analyze publication and patent data. We conduct a comparative analysis of bibliometric search strategies that these studies use to harvest publication and patent data related to nanoscience and technology. We implement these strategies on the 2006 publication data and find that Mogoutov and Kahane (2007) [Mogoutov, A. and B. Kahane, 2007. Data search strategy for science and technology emergence: A scalable and evolutionary query for nanotechnology tracking. Research Policy, 36: 893–903.], with their evolutionary lexical query search strategy, extract the highest number of records from the Web of Science. The strategies of Glanzel et al. (2003) [Glanzel, W., et al., 2003. Nanotechnology: Analysis of an Emerging Domain of Scientific and Technological Endeavour. Steunpunt O&O Statistieken, Report. Leuven: K.U. Leuven.], Noyons et al. (2003) [Noyons, E.C.M., et al., 2003. Mapping excellence in science and technology across Europe Nanoscience and nanotechnology. Draft report of project EC-PPN CT-2002-2001 to the European Commission.], Porter et al. (2008) [Porter, A.L. et al., 2008. Refining search terms for nanotechnology. Journal of Nanoparticle Research, 10(5):715-728.] and Mogoutov and Kahane (2007) produce very similar ranking tables of the top ten nanotechnology subject areas and the top ten most prolific countries and institutions.
Download

Tags: Development, Nanotechnology, research, search by Fred
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http://www.nanohub.org/tools/dynamicafm

Dynamic Approach Curves is the premier tool of a suite of tools being developed under the title of VEDA – Virtual Environment for Dynamic AFM. This tool accurately simulates the oscillations and tip-sample interaction forces of an AFM cantilever probe excited near resonance and brought close to a sample in either ambient conditions or ultra high vacuum. This tool features (a) accurate models of AFM probe dynamics, (b) realistic tip-sample interaction force models and (c) accurate, FORTRAN based, numerical integration schemes that are well-suited for non-smooth, nonlinear differential equations. From the tip oscillation time histories, which are simulated with a relative tolerance of 1e-9, quantities such as amplitude and phase of the first harmonic, peak interaction force, mean interaction force, and power dissipation are calculated.

Tags: Nanotechnology by Fred
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The partnership between Nokia and the University of Cambridge was announced in March, 2007 – an agreement to work together on an extensive and long term programme of joint research projects. NRC has established a research facility at the University’s West Cambridge site and collaborates with several departments – initially the Nanoscience Center and Electrical Division of the Engineering Department – on projects that, to begin with, are centered on nanotechnology.
Nokia – Video

Launched alongside The Museum of Modern Art “Design and The Elastic Mind” exhibition, the Morph concept device is a bridge between highly advanced technologies and their potential benefits to end-users. This device concept showcases some revolutionary leaps being explored by Nokia Research Center (NRC) in collaboration with the Cambridge Nanoscience Centre (United Kingdom) – nanoscale technologies that will potentially create a world of radically different devices that open up an entirely new spectrum of possibilities.Morph concept technologies might create fantastic opportunities for mobile devices:

• Newly-enabled flexible and transparent materials blend more seamlessly with the way we live
• Devices become self-cleaning and self-preserving
• Transparent electronics offering an entirely new aesthetic dimension
• Built-in solar absorption might charge a device, whilst batteries become smaller, longer lasting and faster to charge
• Integrated sensors might allow us to learn more about the environment around us, empowering us to make better choices

In addition to the advances above, the integrated electronics shown in the Morph concept could cost less and include more functionality in a much smaller space, even as interfaces are simplified and usability is enhanced. All of these new capabilities will unleash new applications and services that will allow us to communicate and interact in unprecedented ways.

Flexible & Changing DesignNanotechnology enables materials and components that are flexible, stretchable, transparent and remarkably strong. Fibril proteins are woven into a three dimensional mesh that reinforces thin elastic structures. Using the same principle behind spider silk, this elasticity enables the device to literally change shapes and configure itself to adapt to the task at hand.

A folded design would fit easily in a pocket and could lend itself ergonomically to being used as a traditional handset. An unfolded larger design could display more detailed information, and incorporate input devices such as keyboards and touch pads.

Even integrated electronics, from interconnects to sensors, could share these flexible properties. Further, utilization of biodegradable materials might make production and recycling of devices easier and ecologically friendly.

Self-CleaningNanotechnology also can be leveraged to create self-cleaning surfaces on mobile devices, ultimately reducing corrosion, wear and improving longevity. Nanostructured surfaces, such as “Nanoflowers” naturally repel water, dirt, and even fingerprints utilizing effects also seen in natural systems.

Advanced Power SourcesNanotechnology holds out the possibility that the surface of a device will become a natural source of energy via a covering of “Nanograss” structures that harvest solar power. At the same time new high energy density storage materials allow batteries to become smaller and thinner, while also quicker to recharge and able to endure more charging cycles.

Sensing The Environment Nanosensors would empower users to examine the environment around them in completely new ways, from analyzing air pollution, to gaining insight into bio-chemical traces and processes. New capabilities might be as complex as helping us monitor evolving conditions in the quality of our surroundings, or as simple as knowing if the fruit we are about to enjoy should be washed before we eat it. Our ability to tune into our environment in these ways can help us make key decisions that guide our daily actions and ultimately can enhance our health.

Press Material

• View press release
• View and download photos
• View Morph video (.mov, 46mb)

Other resourcesTo learn more about the “Design and The Elastic Mind” exhibition at The Museum of Modern Art visit MoMA webpage

To learn more about the Cambridge Nanoscience Centre visit http://www.nanoscience.cam.ac.uk/
Source: Nokia Research

Tags: Mobile, Nanotechnology by Fred
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The Royal Swedish Academy of Sciences has decided to award the Nobel Prize in Physics for 2007 jointly to

Albert Fert
Unité Mixte de Physique CNRS/THALES, Université Paris-Sud, Orsay, France,

and

Peter Grünberg
Forschungszentrum Jülich, Germany,

“for the discovery of Giant Magnetoresistance”.

Nanotechnology gives sensitive read-out heads for compact hard disks

This year’s physics prize is awarded for the technology that is used to read data on hard disks. It is thanks to this technology that it has been possible to miniaturize hard disks so radically in recent years. Sensitive read-out heads are needed to be able to read data from the compact hard disks used in laptops and some music players, for instance.

In 1988 the Frenchman Albert Fert and the German Peter Grünberg each independently discovered a totally new physical effect – Giant Magnetoresistance or GMR. Very weak magnetic changes give rise to major differences in electrical resistance in a GMR system. A system of this kind is the perfect tool for reading data from hard disks when information registered magnetically has to be converted to electric current. Soon researchers and engineers began work to enable use of the effect in read-out heads. In 1997 the first read-out head based on the GMR effect was launched and this soon became the standard technology. Even the most recent read-out techniques of today are further developments of GMR.

A hard disk stores information, such as music, in the form of microscopically small areas magnetized in different directions. The information is retrieved by a read-out head that scans the disk and registers the magnetic changes. The smaller and more compact the hard disk, the smaller and weaker the individual magnetic areas. More sensitive read-out heads are therefore required if information has to be packed more densely on a hard disk. A read-out head based on the GMR effect can convert very small magnetic changes into differences in electrical resistance and there-fore into changes in the current emitted by the read-out head. The current is the signal from the read-out head and its different strengths represent ones and zeros.

The GMR effect was discovered thanks to new techniques developed during the 1970s to produce very thin layers of different materials. If GMR is to work, structures consisting of layers that are only a few atoms thick have to be produced. For this reason GMR can also be considered one of the first real applications of the promising field of nanotechnology.
http://nobelprize.org/nobel_prizes/physics/laureates/2007/press.html

Tags: Nanotechnology, Nobel by Fred
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What is Nanotechnology?

A nanometer is one-billionth of a meter—25,000 times smaller than the width of a human hair, 200 times smaller than a typical virus, about the size of 3-4 atoms laid end-to-end. At that tiny scale, matter can exhibit some strange, new behaviors. Nanotechnology is all about harnessing those behaviors to create new devices and materials. Imagine a new material that is 100 times stronger than steel, with only one-sixth the weight! Imagine making a transistor out of a single molecule! Imagine molecular machines that practice personalized nanomedicine by repairing damaged cells. These are still dreams, but scientists and engineers in laboratories all over the world are working to make these dreams a reality—to turn the promise of nanoscience into technologies for the benefit of human society.

What is nanoHUB?

The nanoHUB is a rich, web-based resource for research, education and collaboration in nanotechnology. The nanoHUB hosts hundreds of resources which will help you learn about nanotechnology, including Online Presentations, Courses, Learning Modules, Podcasts, Animations, Teaching Materials, and more. Most importantly, the nanoHUB offers simulation tools which you can access from your web browser, so you can not only learn about but also simulate nanotechnology devices.

Resources come from hundreds of contributors in the nanoscience community, and are used by thousands of users from all over the world. Most of our users come from academic institutions and use nanoHUB as part of their research and educational activities. But we also have users from national labs and from industry.

Our Mission

The nanoHUB was created the NSF-funded Network for Computational Nanotechnology (NCN). The NCN is a network of universities with a vision to pioneer the development of nanotechnology from science to manufacturing through innovative theory, exploratory simulation, and novel cyberinfrastructure. NCN students, staff, and faculty are developing the nanoHUB science gateway while making use of it in their own research and education. Collaborators and partners across the world have joined the NCN in this effort.

Join Us

Take a tour of the nanoHUB and see how you can use our infrastructure to further your own research and educational activities. Create your own account. It’s free and will give you access to our online simulation tools, learning modules, and more. Become a contributor by uploading your own presentations and simulation tools onto nanoHUB for others to share. Ask a question in our community forum, and let the community help you out.

Research

The nanoHUB is designed to be a resource to the entire nano-community, but its creation is being spearheaded by the three themes of the NCN: Nanoelectronics, NEMS/nanofluidics, and nanomedicine/biology. An effort in nanophotonics is also being seeded. The NCN seeks partnerships with center-scale efforts to broaden the scope of the nanoHUB o other fields of nanoscience.

Computation and software is a cross-cutting theme in the NCN that connects computer scientists and applied mathematicians to problem-driven scientists and engineers, to address large scale problems and develop community codes for nanotechnology.

Look at current and former NCN Principal Investigators and NCN associates to see what we are working on.

Tour – Join - Contribute

Tags: Nanotechnology by Fred
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