#LPSC2023
#LPSC2023
Program with Links to Abstracts
Schedule Overview
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Poster Session: Lunar Missions, Payloads, and Preparation
Wednesday, March 15, 2023, 6:30 PM
iPosters/Gather.town
Garman S. M.*
Smith J. R.
Characterizing Electromagnetic Coupling with Lunar Regolith and Simulants for Wireless Power Transfer on the Lunar Surface
[#1781]
Effects of Fe-enriched and standard lunar simulant on wireless power transfer using magnetically coupled resonators. Metallic Fe content and particle size are critical.
Effects of Fe-enriched and standard lunar simulant on wireless power transfer using magnetically coupled resonators. Metallic Fe content and particle size are critical.
Young K. E.*
Graff T. G.
Evans C. A.
Artemis Internal Science Team
Artemis Internal Science Team Update: Artemis Science Flight Operations
[#1357]
We describe ongoing work to integrate science into flight operations for Artemis, both in pre-mission and mission execution phases.
We describe ongoing work to integrate science into flight operations for Artemis, both in pre-mission and mission execution phases.
Amitabh *
Suresh K.
Prashar A. K.
Abdullah S.
Terrain Characterisation of Potential Landing Sites for Chandrayaan-3 Lander Using Orbiter High Resolution Camera (OHRC) Images
[#1037]
This paper describes characterisation of potential landing sites for Chandrayaan-3 lander on the basis of engineering constrains and terrain parameters.
This paper describes characterisation of potential landing sites for Chandrayaan-3 lander on the basis of engineering constrains and terrain parameters.
Chaudhuri N.*
Kusuma K. N.
Bharathvaj S. A.
Understanding Lunar Olivine Composition of a Part of Oceanus Procellarum Using Terrestrial Analogues
[#1965]
Terrestrial analogues of lunar olivine are used to derive the chemistry of lunar olivine from the M3 VNIR spectra.
Terrestrial analogues of lunar olivine are used to derive the chemistry of lunar olivine from the M3 VNIR spectra.
Turchinskaya O. I.*
Grishakina E. A.
Tretyukhina O. S.
Feoktistova E. A.
Slyuta E. N.
Description of the Probable Location of the Visited Lunar Base on the Shaft of the Crater Shackleton
[#1083]
The strategic advantage of placing the lunar base near Shackleton crater is that its location allows you to control the area of the south pole within 85°.
The strategic advantage of placing the lunar base near Shackleton crater is that its location allows you to control the area of the south pole within 85°.
Seto E. P.*
Bouey N. Y.
Bywaters K.
Ratliff K. M.
Wood J.
In-situ and Flight Microbial Sterilization System for Future Missions
[#2177]
Our work will investigate methods of sterilization to ensure that contamination is minimized for future exploration.
Our work will investigate methods of sterilization to ensure that contamination is minimized for future exploration.
López-Martínez G.*
Parro L. M.
Habitability Potential of Lunar Pit Craters: Marius Hills, Mare Tranquilitatis, Lacus Mortis and Mare Ingenii Pit
[#2380]
We define the best pit craters suitable for establishing a lunar exploration base and we based our criteria on the data from LRO, GRAIL, Kaguya, among others.
We define the best pit craters suitable for establishing a lunar exploration base and we based our criteria on the data from LRO, GRAIL, Kaguya, among others.
Cohen B. A.*
Cremons D. R.
Greenhagen B. T.
Hayne P. O.
Paige D. A.
et al.
Lunar Flashlight: Mapping Accessible Water Frost
[#2228]
We have one request: / Cubesat with frickin’ laser / beams attached to it.
We have one request: / Cubesat with frickin’ laser / beams attached to it.
Swiney G.*
Hernandez A.
Lunar Landing and Operations Policy Analysis
[#1199]
NASA’s Office of Technology, Policy, and Strategy presents a policy analysis to address potential challenges to landing and operating at the lunar South Pole.
NASA’s Office of Technology, Policy, and Strategy presents a policy analysis to address potential challenges to landing and operating at the lunar South Pole.
*presenter
