Modern High-Efficiency Solid State Lasers

article
Autores

Wetter, N U

Prado, F M

Data de Publicação

1 de fevereiro de 2026

Resumo

Abstract This work reviews recent advancements in modern neodymium-doped solid-state lasers, with a particular emphasis on Nd:YLF. Key innovations include highly efficient passively Q-switched configurations and the demonstration of novel emission wavelengths. Nd:YLF lasers achieved record-breaking efficiencies in both traditional and in-band pumping schemes, with a notable demonstration of 41 mJ pulse energy and 46 MW peak power in a sub-nanosecond Q-switched system employing a Cr⁴⁺:YAG saturable absorber and a side-pumping scheme. Nd:YAG systems achieved 40 mJ pulse energy with an 18 ns duration, underscoring their suitability for laser designation applications. Additionally, new wavelengths at 863 nm and 1370 nm were demonstrated in Nd:YLF crystals, enabling applications such as blue light generation and astrophysical studies. Multichromatic emissions were also investigated, highlighting the potential of Nd-doped lasers to produce simultaneous outputs at multiple wavelengths. These findings emphasize the versatility, efficiency, and scientific importance of Nd-doped lasers, paving the way for further innovations in laser technology.

Citação

BibTeX
@online{n_u2026,
  author = {N U , Wetter and F M , Prado},
  title = {Modern High-Efficiency Solid State Lasers},
  volume = {3183},
  number = {1},
  date = {2026-02-01},
  doi = {10.1088/1742-6596/3183/1/012001},
  langid = {pt-BR},
  abstract = {Abstract This work reviews recent advancements in modern
    neodymium-doped solid-state lasers, with a particular emphasis on
    Nd:YLF. Key innovations include highly efficient passively
    Q-switched configurations and the demonstration of novel emission
    wavelengths. Nd:YLF lasers achieved record-breaking efficiencies in
    both traditional and in-band pumping schemes, with a notable
    demonstration of 41 mJ pulse energy and 46 MW peak power in a
    sub-nanosecond Q-switched system employing a
    Cr\textsuperscript{4+}:YAG saturable absorber and a side-pumping
    scheme. Nd:YAG systems achieved 40 mJ pulse energy with an 18 ns
    duration, underscoring their suitability for laser designation
    applications. Additionally, new wavelengths at 863 nm and 1370 nm
    were demonstrated in Nd:YLF crystals, enabling applications such as
    blue light generation and astrophysical studies. Multichromatic
    emissions were also investigated, highlighting the potential of
    Nd-doped lasers to produce simultaneous outputs at multiple
    wavelengths. These findings emphasize the versatility, efficiency,
    and scientific importance of Nd-doped lasers, paving the way for
    further innovations in laser technology.}
}
Por favor, cite este trabalho como:
N U, Wetter, and Prado F M. 2026. “Modern High-Efficiency Solid State Lasers.” Journal of Physics: Conference Series. February 1, 2026. https://doi.org/10.1088/1742-6596/3183/1/012001.