Lightning radiometry in visible and infrared bands

“…According to Laux et al (1995), emission from up to 7900-K air plasma in that band is due to an unidentified continuum and is very different from emission in the 3-5 μm band, which is examined in this study and discussed below. For 10 negative cloud-to-ground discharges, Wemhoner et al (2023) found the mean duration of the recorded IR power pulse to be 0.13 ms, which was about a factor of 2 shorter than that for simultaneously recorded visible to near IR (0.34-1.1 μm) power pulse, and the mean power pulse peak was a factor of 2.7 × 10 3 lower. Their IR photodiode had a field of view of 2.8°versus 5.8°for the visible plus near IR photodiode.…”

“…For 10 negative cloud‐to‐ground discharges, Wemhoner et al. (2023) found the mean duration of the recorded IR power pulse to be 0.13 ms, which was about a factor of 2 shorter than that for simultaneously recorded visible to near IR (0.34–1.1 μm) power pulse, and the mean power pulse peak was a factor of 2.7 × 10 −3 lower. Their IR photodiode had a field of view of 2.8° versus 5.8° for the visible plus near IR photodiode.…”

“…More recently, Wemhoner et al (2023), working at the Langmuir Laboratory in New Mexico, obtained photoelectric observations of lightning in the 2-2.5 μm IR band. According to Laux et al (1995), emission from up to 7900-K air plasma in that band is due to an unidentified continuum and is very different from emission in the 3-5 μm band, which is examined in this study and discussed below.…”

“…More recently, Wemhoner et al. (2023), working at the Langmuir Laboratory in New Mexico, obtained photoelectric observations of lightning in the 2–2.5 μm IR band. According to Laux et al.…”

Comparison of Lightning Channel Luminosity Versus Time Profiles in the Infrared and Visible Ranges

“…According to Laux et al (1995), emission from up to 7900-K air plasma in that band is due to an unidentified continuum and is very different from emission in the 3-5 μm band, which is examined in this study and discussed below. For 10 negative cloud-to-ground discharges, Wemhoner et al (2023) found the mean duration of the recorded IR power pulse to be 0.13 ms, which was about a factor of 2 shorter than that for simultaneously recorded visible to near IR (0.34-1.1 μm) power pulse, and the mean power pulse peak was a factor of 2.7 × 10 3 lower. Their IR photodiode had a field of view of 2.8°versus 5.8°for the visible plus near IR photodiode.…”

“…For 10 negative cloud‐to‐ground discharges, Wemhoner et al. (2023) found the mean duration of the recorded IR power pulse to be 0.13 ms, which was about a factor of 2 shorter than that for simultaneously recorded visible to near IR (0.34–1.1 μm) power pulse, and the mean power pulse peak was a factor of 2.7 × 10 −3 lower. Their IR photodiode had a field of view of 2.8° versus 5.8° for the visible plus near IR photodiode.…”

“…More recently, Wemhoner et al (2023), working at the Langmuir Laboratory in New Mexico, obtained photoelectric observations of lightning in the 2-2.5 μm IR band. According to Laux et al (1995), emission from up to 7900-K air plasma in that band is due to an unidentified continuum and is very different from emission in the 3-5 μm band, which is examined in this study and discussed below.…”

“…More recently, Wemhoner et al. (2023), working at the Langmuir Laboratory in New Mexico, obtained photoelectric observations of lightning in the 2–2.5 μm IR band. According to Laux et al.…”

Comparison of Lightning Channel Luminosity Versus Time Profiles in the Infrared and Visible Ranges

Processes in negative and positive CG lightning flashes detected from space by GLM