A. S. Arakcheev scite author profile

A. S. Arakcheev

4Publications

105Citation Statements Received

17Citation Statements Given

How they've been cited

200

How they cite others

Affiliations

Budker Institute of Nuclear Physics, Novosibirsk State University, Novosibirsk State Technical University

Publications

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Investigation of the impact of transient heat loads applied by laser irradiation on ITER-grade tungsten

et al. 2014

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Cracking thresholds and crack patterns in tungsten targets after repetitive ITER-like edge localized mode (ELM) pulses have been studied in recent simulation experiments by laser irradiation. The tungsten specimens were tested under selected conditions to quantify the thermal shock response. A Nd:YAG laser capable of delivering up to 32 J of energy per pulse with a duration of 1 ms at the fundamental wavelength λ = 1064 nm has been used to irradiate ITER-grade tungsten samples with repetitive heat loads. The laser exposures were performed for targets at room temperature (RT) as well as for targets preheated to 400 • C to measure the effects of the ELM-like loading conditions on the formation and development of cracks. The magnitude of the heat loads was 0.19, 0.38, 0.76 and 0.90 MJ m −2 (below the melting threshold) with a pulse duration of 1 ms. The tungsten surface was analysed after 100 and 1000 laser pulses to investigate the influence of material modification by plasma exposures on the cracking threshold. The observed damage threshold for ITER-grade W lies between 0.38 and 0.76 GW m −2. Continued cycling up to 1000 pulses at RT results in enhanced erosion of crack edges and crack edge melting. At the base temperature of 400 • C, the formation of cracks is suppressed.

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Vapor shielding models and the energy absorbed by divertor targets during transient events

Skovorodin

Pshenov

Arakcheev

et al. 2016

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The erosion of divertor targets caused by high heat fluxes during transients is a serious threat to ITER operation, as it is going to be the main factor determining the divertor lifetime. Under the influence of extreme heat fluxes, the surface temperature of plasma facing components can reach some certain threshold, leading to an onset of intense material evaporation. The latter results in formation of cold dense vapor and secondary plasma cloud. This layer effectively absorbs the energy of the incident plasma flow, turning it into its own kinetic and internal energy and radiating it. This so called vapor shielding is a phenomenon that may help mitigating the erosion during transient events. In particular, the vapor shielding results in saturation of energy (per unit surface area) accumulated by the target during single pulse of heat load at some level Emax. Matching this value is one of the possible tests to verify complicated numerical codes, developed to calculate the erosion rate during abnormal events in tokamaks. The paper presents three very different models of vapor shielding, demonstrating that Emax depends strongly on the heat pulse duration, thermodynamic properties, and evaporation energy of the irradiated target material. While its dependence on the other shielding details such as radiation capabilities of material and dynamics of the vapor cloud is logarithmically weak. The reason for this is a strong (exponential) dependence of the target material evaporation rate, and therefore the “strength” of vapor shield on the target surface temperature. As a result, the influence of the vapor shielding phenomena details, such as radiation transport in the vapor cloud and evaporated material dynamics, on the Emax is virtually completely masked by the strong dependence of the evaporation rate on the target surface temperature. However, the very same details define the amount of evaporated particles, needed to provide an effective shielding to the target, and, therefore, strongly influence resulting erosion rate. Thus, Emax cannot be used for validation of shielding models and codes, aimed at the target material erosion calculations.

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Reduction of mass loss by the hot Jupiter WASP-12b due to its magnetic field

et al. 2017

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Novel electron beam based test facility for observation of dynamics of tungsten erosion under intense ELM-like heat loads

Vyacheslavov

Arakcheev

Бурдаков

et al. 2016

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A. S. Arakcheev

Investigation of the impact of transient heat loads applied by laser irradiation on ITER-grade tungsten

Vapor shielding models and the energy absorbed by divertor targets during transient events

Reduction of mass loss by the hot Jupiter WASP-12b due to its magnetic field

Novel electron beam based test facility for observation of dynamics of tungsten erosion under intense ELM-like heat loads

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