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Computational Chemistry Trygve Helgaker CTCC, Department of Chemistry, University of Oslo.

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Presentation on theme: "Computational Chemistry Trygve Helgaker CTCC, Department of Chemistry, University of Oslo."— Presentation transcript:

1 Computational Chemistry Trygve Helgaker CTCC, Department of Chemistry, University of Oslo

2 Computer usage Notur 2007

3 Chemistry: a many-body problem  At the deepest level, molecules are simple:  charged particles in motion  governed by the laws of quantum mechanics HΨ=EΨ “The underlying physical laws necessary for the mathematical treatment of a large part of physics and the whole of chemistry are thus completely known and the difficult is only that the exact application of these laws leads to equations that are too complicated to be soluble” Dirac (1927) …but it is a many-body problem…

4 Computers came to our rescue…

5 Quantum chemistry Simulations of chemical systems and processes  approximate solutions of the Schrödinger equation Journal of Americal Chemical Society  40% of all articles supported by computation  most of these are quantum chemical HΨ=EΨ “Every attempt to to employ mathematical methods in the study of chemical questions must be considered profoundly irrational” August Comte (1798–1857) This is an amazing development for an experimental science

6 Computation: the third way Theory, experiment and computation  interpretation and prediction of experiment  alternative to experimental measurements HΨ=EΨ

7 Example: Reaction pathways

8 Example: NMR spectra 200 MHz NMR spectrum of vinyllithium

9 Methods development: DALTON Dalton program system – Scandinavian collaboration – 25 years of development – broad functionality – 1300 research groups – 250 computer centers Computational models are being constantly improved – increase accuracy and predictive power – broaden the range of applicability and lower the cost

10 Towards higher accuracy…

11 Towards larger systems… Real-world problems are typically large – computational cost typically scales cubically or high with increasing system size – however, in large systems, nearly all contributions are insignificant – these should be recognized and avoided in the computations – ideally, cost should increase in proportion to system size

12 Towards larger systems… Energies and structure of large molecules – Quantum chemistry is typically done on 50 or less atoms – Energy and forces for this 392-atom molecule can now be done in about one hour – This is more than an order of magnitude improvement over a few years – On a parallel computer, we should be able to do this in about one minute – We should reach 10.000 atoms in 2010 (currently at a few thousand) – Our bottleneck is memory

13 Computer developments Our requirements – CPU power and memory—little or no data transfer or storage Encouraging developments: – Powerful multicore chips – Graphical processing units (GPUs) – Improvements in bandwidths of interconnects Discouraging developments: – Chips are not getting faster (3GHz) – Multicore chips hard to program effectively – GPU/CPU communication slow Software and algorithm development necessary – This is our job!

14 Running on Blue Gene Dalton scales well to over 20.000 processing cores – Argonne’s Blue Gene/P – 1-PFLOPS computing with 294 192 PowerPC 450 850 MHz processors If you provide the hardware, we shall put it to good use…


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