guest ::
| Home > Publications database > INSPIRE Sat-3 AtmoLITE - measuring gravity waves from aMicrosat |
| Home > Publications database > INSPIRE Sat-3 AtmoLITE - measuring gravity waves from aMicrosat |
| Abstract | FZJ-2024-05371 |
; ; ; ; ; ; ; ; ;
2024
This record in other databases:
Please use a persistent id in citations: doi:10.34734/FZJ-2024-05371
Abstract: Atmospheric dynamics are composed largely of atmospheric circulations of different scales. Onesuch circulation is the mesospheric pole-to-pole circulation, which gives rise to the intriguing phe-nomenon whereby the polar summer mesosphere, despite receiving 24 hours of sunlight, is thecoldest region in the atmosphere. These circulations are governed by atmospheric waves, whichagain come in various shapes and sizes. The pole-to-pole circulation of the upper mesosphere inparticular is driven by so-called gravity waves. Gravity waves are buoyancy waves where gravityserves as the restoring force. These waves carry energy and momentum from the lower atmosphereinto the mesosphere and lower thermosphere. As gravity waves travel vertically with wavelengths onthe scale of kilometers, they can be well measured by a satellite with a limb looking configuration.In recognition of the significance of accurately measuring these atmospheric dynamics, researchershave developed advanced instrumentation to capture the intricate details of these phenomena. Thisbrings us to a significant joint initiative aimed at enhancing our understanding of the upper meso-sphere. A collaborative effort between the J ̈ulich Research Center and the University of Wuppertalin Germany led to the development of such a limb sounding instrument. The instrument’s primaryobjective is to provide vertical temperature profiles with a fine vertical sampling of 1.5 km. Theseprecise measurements enable the effective capture and analysis of small to medium-scale gravitywaves in heights of about 90-140km, which is crucial for understanding the energy and momentumtransfer in the atmosphere. The measurement principle is based on spectral information whichis captured by an imaging Spatial Heterodyne Interferometer. This is essentially a Michelson in-terferometer with the two mirrors exchanged with blazed gratings in Littrow configuration. Thespectrum is extracted from the interferogram which is superimposing the image on the detector.To specifically observe the oxygen A-band emissions, a bandpass filter of 6 nm centered around763 nm is used. The Oxygen A-band was chosen as it peaks around 90 km and from its relativespectral band shape, the temperature can be directly derived. The instrument is scheduled to belaunched on the International Satellite Program in Research and Education (INSPIRE) Sat-3 mis-sion, led by the Indian Institute of Space Science and Technology. The objective of the mission istwofold: to acquire expertise for all participating scientists and to validate the onboard instrumentsin orbit. Furthermore, the mission aims to integrate into the INSPIRE constellation, providing aconstellation of Earth and space weather-monitoring satellites. The expected outcomes include en-hanced models of atmospheric dynamics and will facilitate more accurate space weather and climatepredictions.
Keyword(s): Instrument and Method Development (1st) ; Geosciences (2nd)
|
The record appears in these collections: |
PDF