What question did this study set out to answer?

The aim is to develop a lidar system for simultaneous observation of meteoric calcium atoms and ions in the upper atmosphere.

April 16, 2026

Ti:Sapphire-laser-based resonance-scattering lidar system for simultaneous observation of Ca and Ca

Key Points

The aim is to develop a lidar system for simultaneous observation of meteoric calcium atoms and ions in the upper atmosphere.
Utilized a dual-wavelength injection-locked nanosecond-pulsed Ti:sapphire lidar system.
Conducted benchmark tests to independently observe Ca and Ca+ layers.
Operated the lidar system over an entire night for stability testing.
Successfully detected both Ca and Ca+ with high signal-to-noise ratios.
Achieved high temporal and spatial resolutions in observations.
Demonstrated stable operation of the lidar system over an entire night.

Abstract

Meteoric atoms and ions are among the remarkable tracers to investigate a variety of dynamics appearing in the mesosphere and thermosphere at altitudes ranging from 80 to 150 km. Here, we report on a solid-laser-based lidar system, namely dual-wavelength injection-locked nanosecond-pulsed Ti:sapphire lidar, that can simultaneously detect resonance scatterings by meteoric calcium atom (Ca) and ion (Ca+) layers. We operated the lidar system and conducted a benchmark test in which Ca or Ca+ was observed independently as a first step. We found that the lidar system was operated stably over an entire night, having the ability to detect either Ca or Ca+ with a sufficient signal-to-noise ratio in addition to high temporal and spatial resolutions. In our presentation, we also report on a typical demonstration of the lidar system, namely the observation of Ca and Ca+ over an entire night.

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Ti:Sapphire-laser-based resonance-scattering lidar system for simultaneous observation of Ca and Ca

Key Points

Abstract

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