Hydrogen Retention in Doped Tungsten Materials Developed for Fusion

Голубева, А. В.; Черкез, Д. И.

doi:10.21517/0202-3822-2018-41-4-26-37

Cited by 3 publications

(4 citation statements)

References 46 publications

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“…В результате облучения в металле образуются поры и дислокационные петли. Взаимодействие дислокаций с подобными дефектами изучено недостаточно, в силу чего исследования в данном направлении являются актуальными [1]. В работе изучается механизм пластической деформации при взаимодействии краевой дислокации с порами, вызванными облучением в ядерных реакторах, с помощью метода молекулярной динамики с использованием пакета LAMMPS.…”

Section: моделирование механизма торможенияunclassified

Моделирование Механизма Торможения Дислокаций Порами В Вольфраме

Казаков¹,

Шарапова²,

Бабичева³

et al. 2022

Фундаментальная Математика И Ее Приложения В Естествознании

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Section: моделирование механизма торможенияunclassified

Моделирование Механизма Торможения Дислокаций Порами В Вольфраме

Казаков¹,

Шарапова²,

Бабичева³

et al. 2022

Фундаментальная Математика И Ее Приложения В Естествознании

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“…Blistering, which is among the most dangerous mechanisms of destruction of metals due to the formation of bubbles filled with gas (hydrogen, helium, etc. ), has been actively studied for more than 50 years, especially in connection with the problem of creating a thermonuclear reactor [20]. In contrast, the blister structure found in graphene materials can be used for the development of hydrogen storage and transportation systems [21][22][23].…”

Section: Reviewsmentioning

confidence: 99%

Graphene and Graphene-Like Materials for Hydrogen Energy

et al. 2020

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The review is devoted to current and promising areas of application of graphene and materials based on it for generating environmentally friendly hydrogen energy. Analysis of the results of theoretical and experimental studies of hydrogen accumulation in graphene materials confirms the possibility of creating on their basis systems for reversible hydrogen storage, which combine high capacity, stability, and the possibility of rapid hydrogen evolution under conditions acceptable for practical use. Recent advances in the development of chemically and heat-resistant graphene-based membrane materials make it possible to create new gas separation membranes that provide high permeability and selectivity and are promising for hydrogen purification in processes of its production from natural gas. The characteristics of polymer membranes that are currently used in industry for the most part can be significantly improved with small additions of graphene materials. The use of graphene-like materials as a support of nanoparticles or as functional additives in the composition of the electrocatalytic layer in polymer electrolyte membrane fuel cells makes it possible to improve their characteristics and to increase the activity and stability of the electrocatalyst in the reaction of oxygen evolution.

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“…Разработка и выбор передовых материалов естественным образом обусловлены необходимостью увеличения диапазона рабочих температур и флюенса, что позволит расширить возможности проведения современных экспериментальных исследований. Например, в обзорной статье [1] авторы обсуждают возможность использования вольфрама как обращенного к плазме материала термоядерных установок и пути устранения недостатков вольфрама, таких как высокая температура перехода из хрупкого состояния в пластическое, радиационное охрупчивание и др. Под воздействием облучения в материале накапливаются радиационные повреждения, образуются полости и другие дефекты на различной глубине [2].…”

Section: Introductionunclassified

“…The authors solved this problem using the LAMMPS package, carried out the integration of atoms motion equations by the fourth order Verlet method. The model under the study is a single crystal of a certain [111], [-1-12], [1][2][3][4][5][6][7][8][9][10] orientation along the basic X, Y, and Z coordinate axis relatively, in which the slip of edge dislocations in the main slip system of BCC metals and their interaction with pores is considered. The authors studied the influence of a pore size on the shear stress magnitude: the growth of pore diameter is proportional to the stress growth.…”

mentioning

confidence: 99%

Simulation of overcoming obstacles in the form of pores by dislocations in tungsten

Kazakov¹,

Sharapova²,

Babicheva³

et al. 2022

FMT

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Tungsten is widely used as a material capable of withstanding working conditions in nuclear reactors and other extreme conditions. Under the influence of irradiation, such defects as Frenkel pairs, pores, and dislocation loops are formed in the metal. Therefore, the research aimed at studying the interactions of these defects with each other and their influence on the mechanical properties of the metal are relevant. The paper presents the theoretical study based on the molecular dynamics method, the purpose of which is to investigate the mechanism of strain hardening of tungsten associated with the interaction of dislocations and pores. The authors solved this problem using the LAMMPS package, carried out the integration of atoms motion equations by the fourth order Verlet method. The model under the study is a single crystal of a certain [111], [–1–12], [1–10] orientation along the basic X, Y, and Z coordinate axis relatively, in which the slip of edge dislocations in the main slip system of BCC metals and their interaction with pores is considered. The authors studied the influence of a pore size on the shear stress magnitude: the growth of pore diameter is proportional to the stress growth. The dependences of shear stress on the shear strain in the temperature range of 600–1400 K are calculated, whereby the temperature change does not significantly influence the stress value. The study shows that dislocations cut the pores and, upon the repeated interaction with a pore, a lower value of peak shear stress is observed than during the first one. The presence of pores leads to the flow stress increase, and such an effect becomes more evident with the increasing pore diameter. The flow stress increases thrice for pores with a diameter of 6 nm compared to the material without pores. The authors described the mechanism of interaction between the edge dislocations and pores under the influence of shear stress.

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Hydrogen Retention in Doped Tungsten Materials Developed for Fusion

Cited by 3 publications

References 46 publications

Моделирование Механизма Торможения Дислокаций Порами В Вольфраме

Моделирование Механизма Торможения Дислокаций Порами В Вольфраме

Graphene and Graphene-Like Materials for Hydrogen Energy

Simulation of overcoming obstacles in the form of pores by dislocations in tungsten

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