The Supercomputer Simulation of Nanocomposite Components and Transport Processes in the Li-ion Power Sources of New Types

“…Availability of commercial HPC infrastructure (where you have to pay for using it) C 3 Availability of skilled human resources C 4 Degree to which universities equip students with the necessary knowledge to work in HPC C 5 Availability of competitive public funding (e.g., direct public funding, grants, awards, baseline funding) C 6 Availability of private funding for R&D related to HPC C 7 Degree of awareness about HPC benefits C 8 Degree of science-industry cooperation related to HPC C 9 Degree of industry-public authorities' cooperation related to HPC C 10 Degree of science-public authorities' cooperation related to HPC C 11 HPC prioritization in legislative documents and strategies…”

Evaluation of Criteria for the Implementation of High-Performance Computing (HPC) in Danube Region Countries Using Fuzzy PIPRECIA Method

“…Availability of commercial HPC infrastructure (where you have to pay for using it) C 3 Availability of skilled human resources C 4 Degree to which universities equip students with the necessary knowledge to work in HPC C 5 Availability of competitive public funding (e.g., direct public funding, grants, awards, baseline funding) C 6 Availability of private funding for R&D related to HPC C 7 Degree of awareness about HPC benefits C 8 Degree of science-industry cooperation related to HPC C 9 Degree of industry-public authorities' cooperation related to HPC C 10 Degree of science-public authorities' cooperation related to HPC C 11 HPC prioritization in legislative documents and strategies…”

Evaluation of Criteria for the Implementation of High-Performance Computing (HPC) in Danube Region Countries Using Fuzzy PIPRECIA Method

“…Результаты применения и сложность задач С использованием комплекса проведено более 60 вычислительных экспериментов в области компьютерного моделирования компонентов низкотемпературных топливных элементов [4,8] (нанокомпозитные электроды на основе диоксидов переходных металлов и платины и мембраны на основе сложных гетерополикислот, полные модели элементов) и более 200 -при моделировании литий-ионных аккумуляторов новых типов [3,5,6,9] (композитные структуры на основе углерода и кремния -нанотрубки, наностержни, структурные кластеры кремния размерностью до 300 атомов, «нанобумага», твердые и полимерные электролиты, процессы зарядки/разрядки, транспортные модели ионного переноса). Продолжительность некоторых расчетов на кластере ИПХФ достигала 1 месяца.…”

Web tools for carrying out mass computing experiments in the field of supercomputer quantum-chemical simulation of nanocomposite materials

Supercomputer Simulation of Promising Nanocomposite Anode Materials for Lithium-Ion Batteries: New Results