Results 141 to 150 of about 914,936 (185)

Boron-Insertion-Induced Lattice Engineering of Rh Nanocrystals Toward Enhanced Electrocatalytic Conversion of Nitric Oxide to Ammonia. [PDF]

Nanomicro Lett
Han P, Xu X, Chen W, Zheng L, Ma C, Wang G, Xu L, Gu P, Wang W, He Q, Zeng Z, Wang J, Su D, Ling C, Gu Z, Chen Y.   +15 more
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Does chemistry need more physics? [PDF]

Pure Appl Chem
Saue T.
europepmc   +1 more source

FPGA-based Timing Distribution for High-Energy Physics Experiments

E. Mendes
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Dynamics of protonated oxalate from machine-learned simulations and experiment: infrared signatures, proton transfer dynamics and tunneling splittings.

Phys Chem Chem Phys
Andreichev V, Käser S, Bocanegra EL, Salik M, Johnson MA, Meuwly M.   +5 more
europepmc   +1 more source

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Computing in high energy physics experiments

Interfaces in Computing, 1985
Abstract High energy physics experiments are studying more and more exotic processes at ever-increasing energies. Enormous quantities of data must be measured and processed. This challenge can only be met by the use of computers throughout the experiments. An overview is given of how different applications each require specific hardware and software.
J Dorenbosch, L.O Hertzberger
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Grid applications for high energy physics experiments

The 6th IEEE/ACM International Workshop on Grid Computing, 2005., 2005
This paper discusses the use of e-science grid in providing computational resources for modern international high energy physics (HEP) experiments. We investigate the suitability of the current generation of grid software to provide the necessary resources to perform large-scale simulation of the experiment and analysis of data in the context of ...
A. Khan, T. Adye, C. A. J. Brew, F. Wilson, B. Bense, R. D. Cowles, D. A. Smith, ANDREOTTI, Daniele, C. Bozzi, LUPPI, Eleonora, VERONESI, Paolo, R. Barlow, M. P. Kelly, J. C. Werner, A. Forti, G. Grosdidier, E. Feltresi, A. Petzold, H. Lacker, J. E. Sundermann   +19 more
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EMC Planning for High-Energy Physics Experiments

IEEE Transactions on Electromagnetic Compatibility, 2016
During the last years, the large hadron collider (LHC), the most powerful particle accelerator in the world, has been running at CERN in Geneva, Switzerland. It includes four large high-energy experiments and the compact muon solenoid (CMS) is one of them. The electronic read-out for the CMS experiment is designed to process signals in the range of $\
F. Arteche, Claudio Rivetta, Javier Gomez-Aleixandre   +2 more
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Trigger control in a high energy physics experiment

IEEE Transactions on Nuclear Science, 1989
Control and diagnostic tools for the event-filtering system (trigger) of the L3 experiment at the LEP (Large Electron Positron) collider have been implemented using an expert system. The structure and behavior of the trigger electronics has been modeled using the hybrid framework (allowing both frame-based design and rule-based reasoning) of the shell ...
F. Menczer, L. Luminari, F. Corazziari, S. Falciano   +3 more
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