Analitika

Аналитика

2227-572X2687-1351

Technosphera JSC

626839

10.22184/2227-572X.2023.13.1.48.54

Аналитика веществ и материалов

Research Article

Features and directions of development of the laser ablation method for the synthesis of nano-particles

Особенности и направления развития метода лазерной абляции для синтеза наночастиц

Shitova

Е. S.

Шитова

Е. С.

Russian Federation

ESShitova@bochvar.ru

Makarov

F. V.

Макаров

Ф. В.

Russian Federation

д. т. н.

ESShitova@bochvar.ru

Pertsev

А. А.

Перцев

А. А.

Russian Federation

к. т. н.

ESShitova@bochvar.ru

Ponomarenko

А. P.

Пономаренко

А. П.

Russian Federation

ESShitova@bochvar.ru

Shtraus

А. А.

Штраус

А. А.

Russian Federation

ESShitova@bochvar.ru

АО «ВНИИНМ»

15012023

131

48551302202413022024

2023

Шитова Е.С., Макаров Ф.В., Перцев А.А., Пономаренко А.П., Штраус А.А.

https://creativecommons.org/licenses/by-nc-nd/4.0/

https://journals.eco-vector.com/2227-572X/article/view/626839

The article presents an analytical review of the literature concerning the features of the laser ablation process for the synthesis of nanoparticles. The laser ablation method is shown to be promising, which makes it possible to meet the specified requirements for the characteristics of nanoparticles. Themain factors affecting the obtained nanoparticles, such as laser parameters (source, wavelength, fluence, pulse duration and frequency), target material and geometric characteristics, and the state of the environment (liquid, gaseous medium, vacuum) are given. The development trends of the method are determined.

В статье представлен аналитический обзор литературы, касающейся особенностей процесса лазерной абляции для синтеза наночастиц. Показана перспективность метода лазерной абляции, позволяющего обеспечить заданные требования к характеристикам наночастиц. Приведены основные факторы, влияющие на получаемые наночастицы, такие как параметры лазера (источник, длина волны, флюенс, длительность и частота импульса), материал и геометрические характеристики мишени, состояние окружающей среды (жидкость, газовая среда, вакуум). Определены тенденции развития метода.

nanoparticlesnanotechnologieslaser ablationnanoparticle synthesis

наночастицынанотехнологиилазерная абляциясинтез наночастиц

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