Brillouin lasing in single-mode tapered optical fiber with inscribed fiber Bragg grating array

“…In fact, random fiber lasers are able to produce light with unique performance characteristics without imposing stringent requirements on the cavity configuration. Current trends in Fibers 2021, 9, 53 2 of 9 random fiber lasers are associated with evolution of long (10-100 km) cavities based on SMF-28 fibers to short laser configurations based on short (~10m) FBG array fibers referred to as artificial Rayleigh fibers [8,9]. The use of artificial Rayleigh fibers, as the cavity of a random laser not only reduces the cavity length to acceptable values, but also provides the spectral selection of lasing generation at the reflection wavelength of the FBG array.…”

“…In addition, after applying a polymer coating over the fiber with gratings inscribed in it, its mechanical strength does not differ from that of a conventionally drawn fiber. However, it should be noted that the optical fiber chosen for inscribing FBGs during the drawing process should have a sufficient initial photosensitivity [8]. In [9], the possibility of fabricating a laser cavity from an array of FBGs inscribed in a segment of the Er-doped fiber with a relatively low concentration of Er 3+ ions (Er absorption~20 dB/m at a wavelength of 1530 nm) was demonstrated.…”

“…Thus, the use of extended lengths of optical fibers weakly doped with rare-earth dopants as a base for creating of SFL cavities will make it possible in the future to minimize or even get rid of the problem of the undesirable Self-Q-Switch mode appearance as well as the problem of excessive heat release and associated temperature instability. The output characteristics of a single-frequency Er-doped Random FBG laser are presented in [8], which are at least not inferior to lasers with a classical Fabry-Perot cavity, and make it a promising alternative to the "traditional" SFLs.…”

Photosensitive Yb-Doped Germanophosphosilicate Artificial Rayleigh Fibers as a Base of Random Lasers

“…In fact, random fiber lasers are able to produce light with unique performance characteristics without imposing stringent requirements on the cavity configuration. Current trends in Fibers 2021, 9, 53 2 of 9 random fiber lasers are associated with evolution of long (10-100 km) cavities based on SMF-28 fibers to short laser configurations based on short (~10m) FBG array fibers referred to as artificial Rayleigh fibers [8,9]. The use of artificial Rayleigh fibers, as the cavity of a random laser not only reduces the cavity length to acceptable values, but also provides the spectral selection of lasing generation at the reflection wavelength of the FBG array.…”

“…In addition, after applying a polymer coating over the fiber with gratings inscribed in it, its mechanical strength does not differ from that of a conventionally drawn fiber. However, it should be noted that the optical fiber chosen for inscribing FBGs during the drawing process should have a sufficient initial photosensitivity [8]. In [9], the possibility of fabricating a laser cavity from an array of FBGs inscribed in a segment of the Er-doped fiber with a relatively low concentration of Er 3+ ions (Er absorption~20 dB/m at a wavelength of 1530 nm) was demonstrated.…”

“…Thus, the use of extended lengths of optical fibers weakly doped with rare-earth dopants as a base for creating of SFL cavities will make it possible in the future to minimize or even get rid of the problem of the undesirable Self-Q-Switch mode appearance as well as the problem of excessive heat release and associated temperature instability. The output characteristics of a single-frequency Er-doped Random FBG laser are presented in [8], which are at least not inferior to lasers with a classical Fabry-Perot cavity, and make it a promising alternative to the "traditional" SFLs.…”

Photosensitive Yb-Doped Germanophosphosilicate Artificial Rayleigh Fibers as a Base of Random Lasers

“…Дополнительно в резонатор случайного лазера был добавлен короткий отрезок (~1 м) ОВ, легированного ионами эрбия, который использовался как динамический модовый фильтр [9]. Для получения перестраиваемой лазерной генерации в полосе до 4 нм в качестве резонатора может использоваться тейперное ОВ с массивом ВБР [10].…”

Искусственные Рэлеевские Волокна И Их Применение В Лазерах

“…Возможность достижения узкой линии и низкой мощности порога генерации любого лазера во многом определяется параметрами резонатора, такими как свободный спектральный диапазон (FSR) и его добротность, что накладывает очень жесткие требования к конструкции лазеров, предназначенных для генерации узкополосного излучения. Использование динамических отражательных структур открывает альтернативные возможности генерации излучения с низким порогом генерации и высокой когерентностью излучения без предъявления высоких требований к волоконному лазерному резонатору, позволяет создавать конструктивно более простые и, соответственно, более дешевые конфигурации лазеров [2][3][4][5] с низким порогом и рекордно низкой полосой генерации (<100 Гц) для использования в системах связи, метрологии, мониторинга и микроволновой фотоники.…”

Бриллюэновские Динамические Решетки: Применения В Волоконных Лазерах И Сенсорах