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Lunar Flashlight

Lunar Flashlight was a small satellite mission led by NASA's Jet Propulsion Laboratory (JPL) to detect and map water ice deposits in the permanently shadowed regions (PSRs) of the Moon's south pole using near-infrared lasers and a spectrometer.^[1] Launched on December 11, 2022, as a secondary payload on a SpaceX Falcon 9 rocket from Cape Canaveral Space Force Station, after missing its original slot on the Artemis I mission, the 6U CubeSat—roughly the size of two stacked cereal boxes and weighing about 30 pounds (14 kilograms)—aimed to illuminate lunar craters with laser pulses to analyze reflected light for signs of ice versus regolith.^[2] However, propulsion system failures with its "green" monopropellant thrusters prevented the spacecraft from achieving lunar orbit after launch, resulting in the mission's official end in May 2023, though it successfully demonstrated several deep-space technologies.^[1] The primary scientific objectives of Lunar Flashlight focused on identifying the presence, abundance, and distribution of water ice and other volatiles in PSRs, which could support future human exploration by providing resources for drinking water, oxygen production, and rocket fuel.^[2] The mission's innovative instrument suite included four near-infrared lasers operating at wavelengths of 1.064, 1.495, 1.85, and 1.99 micrometers, enabling the spacecraft to "flashlight" beams into shadowed craters during low-altitude flybys.^[3] Originally selected as one of several CubeSats for the Artemis I mission but launched separately, Lunar Flashlight was part of NASA's Small Spacecraft Technology program, highlighting the potential of low-cost, rideshare missions for lunar science.^[1] Despite not reaching its intended highly elliptical lunar orbit—planned to involve Earth flybys for gravity assists—the mission provided valuable engineering insights into CubeSat operations in deep space, including autonomous navigation and the green propellant system, originally demonstrated in an earlier NASA infusion mission.^[1] Post-mission analysis confirmed that while primary science goals were unmet, Lunar Flashlight advanced technologies for more reliable small satellites in the Artemis era; data collected during its heliocentric orbit, including Earth flyby observations on May 16, 2023, contributed to broader understanding of CubeSat resilience. Post-mission data analysis, including publications through 2025, has informed advancements in CubeSat propulsion and lunar volatiles detection for future missions, such as those under the Commercial Lunar Payload Services (CLPS) initiative.^[2]^[4]

Mission Overview

Objectives

The primary objective of the Lunar Flashlight mission was to detect and map the distribution and abundance of water ice in permanently shadowed regions (PSRs) at the Moon's south pole using near-infrared laser reflectometry.^[5] This involved illuminating shadowed craters with a multi-band laser system operating at wavelengths of approximately 1.064, 1.495, 1.850, and 1.990 μm, where water ice exhibits distinct absorption features, and analyzing the reflected spectra with an onboard spectrometer to differentiate ice from dry regolith based on band depths and reflectance values.^[6] The mission aimed for a full success criterion of mapping water ice at 1 km spatial resolution across at least 10% of target PSRs, with a minimum success of detection at 10 km resolution through multiple measurements.^[7] Specific targets included resource-rich south polar craters such as Shackleton, Shoemaker, Haworth, and Faustini, selected due to prior evidence of volatiles from missions like LCROSS, which impacted Cabeus and confirmed water ice presence.^[8]^[9] These regions, located poleward of 80° S latitude, encompass both permanently shadowed and occasionally sunlit areas suspected to harbor accessible frost deposits.^[7] Secondary objectives focused on technological demonstrations to advance small spacecraft capabilities for lunar science. These included validating low-cost CubeSat platforms for deep-space missions beyond low Earth orbit and testing a green monopropellant propulsion system to enable precise orbital maneuvers for small satellites.^[3] Additionally, the mission sought to characterize the reflectance properties of lunar regolith in shadowed environments using the same laser reflectometry technique, providing baseline data for ice discrimination.^[7]

Significance

Lunar Flashlight served as a key secondary payload in NASA's Artemis program, originally manifested for the Artemis I mission aboard the Space Launch System, to advance the goals of establishing a sustainable human presence on the Moon. By targeting water ice deposits in permanently shadowed regions at the lunar south pole, the mission aimed to identify potential resources for in-situ resource utilization (ISRU), including water for drinking, oxygen production, hydrogen fuel, and radiation shielding, thereby reducing the logistical burdens of future crewed expeditions.^[2]^[10] Scientifically, the mission addressed fundamental questions about the Moon's volatile inventory, including the abundance, distribution, and origins of water ice, which could illuminate the Moon's formation history and the mechanisms of volatile delivery to the inner solar system, such as cometary impacts or solar wind implantation. These insights would contribute to broader understanding of planetary evolution and the shared history of water in the Earth-Moon system, aligning with NASA's strategic knowledge gaps in lunar science.^[2]^[11] The mission pioneered technological advancements in small satellite applications, marking the first use of a CubeSat for lunar orbital operations and demonstrating a non-toxic "green" monopropellant propulsion system (LMP-103S) capable of providing over 290 m/s delta-V for deep-space maneuvers. Additionally, its miniaturized infrared laser reflectometer represented an innovative approach to active spectroscopy from a small platform, paving the way for cost-effective smallsat missions like ESCAPADE to Mars and NEA Scout for asteroid exploration.^[2]^[10] If successful, Lunar Flashlight's data would have refined models of the lunar water cycle and supported optimal site selection for future landers and rovers, enhancing the feasibility of long-term lunar bases under the Artemis framework.^[2]^[10]

Development and Design

Development History

The Lunar Flashlight mission was conceived as a technology demonstration to map water ice in the Moon's permanently shadowed regions using innovative near-infrared laser illumination and spectrometry. It was selected in 2014 by NASA's Advanced Exploration Systems program within the Human Exploration and Operations Mission Directorate for its potential to advance small satellite capabilities for lunar exploration.^[10] Barbara Cohen, a planetary scientist at NASA's Goddard Space Flight Center, served as the principal investigator, leading the science team focused on volatile detection.^[12] The mission transitioned to funding under NASA's Space Technology Mission Directorate through the Small Spacecraft Technology program, emphasizing low-cost, high-impact deep space demonstrations.^[3] NASA's Jet Propulsion Laboratory managed overall integration and operations, while the Georgia Institute of Technology's Space Systems Design Laboratory designed and built the 6U CubeSat bus, including the green monopropellant propulsion system.^[13] Development progressed through standard NASA review milestones, including a Preliminary Design Review on September 16, 2019, and a Critical Design Review on January 29, 2020, validating the spacecraft's architecture for deep space travel. Integration and environmental testing faced significant delays due to the COVID-19 pandemic, which disrupted supply chains and facility access, shifting the timeline for final assembly at JPL.^[14] Originally selected as one of several CubeSats for secondary payload on the Artemis I mission (formerly Exploration Mission-1) to demonstrate deep space technologies, Lunar Flashlight was not ready for integration and was instead launched as a rideshare on ispace's Hakuto-R Mission 1 on December 11, 2022, aboard a SpaceX Falcon 9 rocket from Cape Canaveral Space Force Station.^[15] This collaborative effort highlighted NASA's strategy for leveraging commercial rideshare opportunities to maintain momentum in small satellite planetary exploration.^[6]

Spacecraft Specifications

Lunar Flashlight is a 6U CubeSat with a stowed form factor of approximately 10 × 20 × 30 cm and a total mass of 14 kg.^[16]^[17] The spacecraft utilizes a modular, single-string architecture based on a standard aluminum 6U bus platform developed and integrated by the Georgia Institute of Technology, incorporating commercial off-the-shelf (COTS) components alongside custom radiation-hardened elements to withstand deep space conditions.^[10]^[18] The propulsion system utilized a "green" monopropellant, AF-M315E (also known as ASCENT), in the Lunar Flashlight Propulsion System (LFPS) developed by Georgia Tech with NASA support. It consisted of a propellant tank with management device, manifold, pump, four 100 mN thrusters, and micro-fluidic valves, providing 3,320 N-sec of total impulse for trajectory adjustments and lunar orbit insertion.^[2]^[19] The power subsystem features four deployable solar arrays—two trifold MMA High Watts per Kilogram (HaWK) arrays and two 2U × 3U arrays—that generate up to 55 W at end-of-life under nominal solar illumination.^[10] A 6.2 Ah lithium-ion battery pack in a 3s2p configuration, using Panasonic NCRB 18650B cells, provides 48.2 Wh of energy storage to support operations during eclipses and peak power demands.^[10] Communications are handled by a JPL-developed Iris 2.1 X-band transponder with 4 W RF output power, enabling uplink at 8 kbps and downlink at rates up to 256 kbps through NASA's Deep Space Network during lunar flybys.^[10] The attitude determination and control system (ADCS) employs a Blue Canyon Technologies XACT-50 integrated unit, which includes a star tracker, three reaction wheels, and an inertial measurement unit for 3-axis stabilization and pointing accuracy within 1 degree of commanded attitudes.^[10]^[20] Thermal management relies on a passive design augmented by active heaters, utilizing space-facing radiators to maintain critical components like the detector at or below -60°C while addressing the variable thermal environment of lunar orbit.^[10]^[21] Phase-change materials are incorporated for transient heat dissipation from high-power elements.^[10]

Scientific Payload

Primary Instrument

The primary instrument of the Lunar Flashlight mission is a compact short-wave infrared (SWIR) laser reflectometer, designed to actively illuminate and analyze the composition of permanently shadowed lunar craters for water ice deposits. Developed by NASA's Jet Propulsion Laboratory (JPL) in collaboration with institutions including the University of Colorado Boulder and the University of North Carolina at Charlotte, the instrument incorporates detector technology from Teledyne Judson Technologies. This multi-band system enables reflectance measurements at key wavelengths to distinguish water ice signatures from regolith, supporting the mission's goal of mapping ice distribution at the lunar south pole.^[22]^[10]^[23] The reflectometer's design integrates a laser illuminator with a receiver optics assembly. The illuminator uses four stacked diode laser bars, each tuned to a specific wavelength: 1.064 μm and 1.850 μm for continuum reference bands, and 1.495 μm and 1.990 μm to probe water ice absorption features near 1.4–2.0 μm. These lasers, provided by Coherent DILAS, operate in pulsed mode with peak powers ranging from 15 W to 73 W and beam divergences ensuring a spot size of approximately 1 km at operational altitudes. The receiver features a 70 mm off-axis aluminum paraboloidal mirror (focal length 70 mm) that collects backscattered light over a 20 mrad field of view, directing it to a single-pixel InGaAs photodiode detector (2 mm diameter, 2.4 μm cutoff) passively cooled to 208 K via an integral cryoradiator.^[22]^[10]^[3] During operations, the spacecraft orients to point the instrument nadir toward target craters from a planned 50 km polar orbit. The lasers fire in sequence—each for 1–6 ms with intervening pauses—completing a full cycle in 2–3 minutes per pass, allowing for over 100 illuminations per orbit. Reflected signals are digitized and processed to compute band ratios (e.g., absorption-to-continuum), identifying water ice at concentrations as low as 0.5 wt% through characteristic spectral absorptions. Spatial resolution achieves ~1 km per pixel cross-track and 2–10 km along-track, limited by beam footprint and integration time, while the discrete-band approach provides effective spectral resolution of ~10–30 nm equivalent bandwidth per channel.^[24]^[22]^[10] Calibration ensures high radiometric fidelity, with pre-flight end-to-end testing on a spectral bench using cryogenic cooling, long-pass filters, and integrating spheres to derive response functions. In-flight accuracy relies on background-subtracted measurements (lasers off) and cross-calibration against illuminated lunar surfaces or known features from prior missions like Lunar Reconnaissance Orbiter. The detector's strained-lattice InGaAs design minimizes dark current for low-noise performance in the cold space environment. While the core payload focuses on SWIR reflectometry, a visible-light star tracker provides ancillary contextual navigation data during non-shadowed orbital segments.^[22]^[23]^[25]

Supporting Systems

The supporting systems for Lunar Flashlight's primary instrument, a short-wave infrared (SWIR) laser reflectometer, encompass specialized hardware to enable its operation in detecting lunar water ice. A dedicated power subsystem supplies time-averaged output of 20-50 W to the four near-infrared lasers, utilizing DC-DC converters to regulate voltage and battery isolation mechanisms to prevent voltage dips on the main spacecraft bus during high-power laser pulses that can peak at up to 73 W.^[26] This allocation ensures stable energy delivery for the instrument's sequential laser firings without compromising other CubeSat functions.^[6] Data processing relies on the Sphinx flight computer, a low-power, radiation-tolerant system that manages the acquisition, compression, and initial analysis of spectral reflectance data from the instrument's InGaAs detector. The computer digitizes signals at 100 kHz sampling rates, applies background noise subtraction, and stores the processed data on the spacecraft's solid-state recorder for later downlink via the Iris transponder.^[27]^[6] Integration of the payload occurs on the nadir-facing panel of the 6U CubeSat chassis, positioning the off-axis paraboloidal mirror and lasers for direct lunar illumination and observation, with a semi-kinematic mounting interface that includes phase-change material for thermal stability. Command and data transfer between the payload and spacecraft bus utilize SpaceWire protocols, enabling high-speed, reliable communication for instrument sequencing and telemetry.^[6]^[28] Redundancy measures include dual-string electronics architectures for critical power and signal paths, minimizing single-point failures in the laser drivers and detector cooling systems. Fault protection software monitors parameters such as temperatures, currents, and voltages, automatically triggering safe modes or shutdowns in response to anomalies like laser overheating or unexpected power draws.^[29]^[6] Pre-flight qualification involved extensive environmental testing, with the payload subjected to random vibration profiles up to 14 g RMS to simulate Space Launch System launch dynamics and thermal-vacuum cycles in chambers reaching pressures below 3 × 10⁻⁵ Torr and temperatures from 208 K to 248 K, confirming operational integrity across the anticipated lunar orbit conditions.^[18]^[6]

Launch and Trajectory

Launch Details

Lunar Flashlight underwent final integration at NASA's Jet Propulsion Laboratory in Pasadena, California, in October 2022. Originally planned as a payload on NASA's Artemis I mission, it was reassigned to the Hakuto-R Mission 1 rideshare following delays in the Artemis schedule. The CubeSat was then shipped to NASA's Kennedy Space Center in Florida for environmental testing and integration into the launch vehicle adapter in early November 2022.^[30]^[31] The spacecraft launched on December 11, 2022, at 07:38 UTC (2:38 a.m. EST) aboard a SpaceX Falcon 9 Block 5 rocket from Space Launch Complex 40 at Cape Canaveral Space Force Station in Florida. It served as a rideshare payload on ispace's Hakuto-R Mission 1, which aimed to deliver the Resilience lunar lander to the Moon's surface.^[32]^[33] Lunar Flashlight was deployed as the secondary CubeSat payload on the ispace Hakuto-R Mission 1, alongside the Resilience lunar lander (mass approximately 1,000 kg), which carried payloads including the UAE's Rashid rover and JAXA's TENACIOUS lunar robot. Approximately 53 minutes after liftoff, at around 08:31 UTC, Lunar Flashlight was released from the Falcon 9's second stage into a highly elliptical Earth orbit with a perigee of about 290 km and an apogee of approximately 1,120,000 km. Deployment was confirmed through telemetry data received within hours of separation.^[34]^[35] Following deployment, the CubeSat successfully extended its four solar arrays to generate power, enabling initial system checkouts. The first contact with NASA's Deep Space Network was established on December 12, 2022, confirming the spacecraft's health and stable attitude.^[36]^[37]

Planned Orbital Insertion

The Lunar Flashlight mission employed a ballistic lunar transfer trajectory originating from an initial Earth parking orbit shortly after deployment. This low-energy path incorporated multiple Earth flybys to incrementally build the spacecraft's orbital energy, enabling an efficient transit to the Moon without excessive propellant use, culminating in a planned lunar flyby on February 16, 2023, to provide a gravity assist for subsequent orbital capture.^[10]^[38] To achieve insertion, the spacecraft was scheduled to execute eight propulsion burns using its green monopropellant system, delivering a total delta-V of approximately 290 m/s to progressively raise the apogee and perform the final capture maneuver into lunar orbit by May 2023. Navigation for these operations relied on ground-based tracking via NASA's Deep Space Network (DSN) for precise trajectory determination, supplemented by onboard gyroscopes to maintain attitude accuracy during burns.^[39]^[40]^[29] The target orbit was a near-rectilinear halo orbit (NRHO) around the Earth-Moon L2 point, with perilune altitudes of 10-20 km over the lunar south pole and a period of approximately 6 days, enabling repeated passes over the shadowed regions. Science operations in this orbit were planned to encompass 13–15 revolutions, featuring dedicated 30-minute windows per pass over shadowed craters for laser illumination and spectroscopic mapping of potential water ice deposits, with an overall mission duration of 3–6 months.^[38]^[29]^[10]

Operations and Challenges

Initial Operations

Following its launch on December 11, 2022, the Lunar Flashlight spacecraft underwent an activation sequence from December 12 to 15, during which mission controllers confirmed the nominal performance of key subsystems, including power generation, communications, and attitude control.^[41] The spacecraft established contact with the Deep Space Network shortly after deployment, reporting healthy status and stable sun-pointed orientation achieved through autonomous detumbling.^[39] The first trajectory correction maneuvers were attempted using the monopropellant thrusters in late December 2022 and early January 2023. Despite underperformance, these burns achieved limited delta-V, partially validating propulsion system functionality.^[39] These burns also served as system tests, confirming thruster performance despite emerging anomalies in propellant delivery. The operations team at NASA's Jet Propulsion Laboratory (JPL) conducted daily passes via the Deep Space Network to monitor spacecraft health and uplink software updates aimed at optimizing power management during the Earth-Moon transit phase.^[30] These adaptations addressed early power and thermal variations observed post-activation.

Propulsion Anomalies

The Lunar Flashlight propulsion system employed ASCENT (AF-M315E), a hydroxylammonium nitrate-based green monopropellant, in a pump-fed configuration with four 0.1 N thrusters provided by Rubicon Space Systems for both primary delta-V maneuvers and attitude control.^[42] These thrusters, integrated with a micro-pump from Flight Works Inc. and an additively manufactured propellant management device, were designed to deliver up to 290 m/s of delta-V using approximately 2 kg of propellant, occupying about 2.4 U of the 6 U CubeSat volume while consuming 15–47 W of power. This setup marked the first deep-space application of ASCENT propellant, aimed at demonstrating higher performance and lower toxicity compared to hydrazine-based systems.^[39] Initial symptoms of the propulsion anomaly emerged shortly after the December 11, 2022, launch aboard Artemis I, when three of the four thrusters exhibited underperformance, delivering thrust as low as 10% of nominal levels during early checkout and trajectory correction maneuvers.^[42] By January 2023, the fourth thruster also failed during despin and momentum management burns, resulting in inconsistent thrust and failure to achieve predicted spin rate reductions.^[40] Telemetry data during preparations for a February 2023 lunar flyby revealed pressure anomalies in the propellant lines, indicating restricted flow despite command signals to the valves and pumps.^[43] The root cause was traced to debris, such as additive manufacturing powder residues, obstructing the fuel lines near the thruster inlets, as confirmed by ground simulations and in-flight telemetry showing no propellant flow despite nominal valve and pump operations.^[44] This blockage limited propellant delivery, causing variable and diminished thrust across all four thrusters.^[45] Mission teams attempted resolution through several measures, including modified single-thruster rotating maneuvers in January 2023 to conserve momentum using reaction wheels, followed by pump pressure increases and reversal tests in February and March to dislodge obstructions.^[40] Backup firings of individual thrusters yielded partial success, restoring intermittent thrust on one unit, but overall performance remained insufficient for the planned lunar capture burn.^[43] These efforts, spanning five months, achieved only about 16 m/s of delta-V against the required 200+ m/s, resulting in a shortfall of roughly 150 m/s or more.^[39] Consequently, the spacecraft escaped the Moon's sphere of influence in May 2023, entering a heliocentric orbit and preventing orbital insertion. Following the failure to achieve lunar capture, the spacecraft performed an Earth flyby on May 17, 2023, at approximately 65,000 km altitude, allowing for final optical navigation imaging before entering heliocentric orbit.^[46]^[27]

Mission Results

Achievements

Despite the mission's inability to achieve lunar orbit, Lunar Flashlight accomplished several key technological demonstrations that advanced CubeSat capabilities for deep space operations. The spacecraft successfully deployed from its rideshare launch on December 11, 2022, aboard a SpaceX Falcon 9 with ispace's HAKUTO-R Mission 1, validating the viability of international rideshare opportunities for small satellites targeting lunar destinations.^[41] Following activation, the CubeSat executed over 400 ground contacts and more than 130 operational activities across 24 weeks, demonstrating robust command and data handling with the Sphinx system in a deep space environment.^[47] The infrared laser reflectometer reached Technology Readiness Level 9 through 14 successful firings in Earth orbit and during translunar cruise, including durations of 10, 30, and 90 seconds, which confirmed its ability to illuminate and measure surface reflectance at near-infrared wavelengths.^[47] Additionally, the IRIS radio operated continuously for over 80 hours in full-duplex mode, enabling phase-referenced Doppler orbit determination with residuals suitable for navigation, while the onboard optical navigation system using the LOST algorithm processed star tracker data effectively.^[48] The green monopropellant propulsion system, utilizing AF-M315E, partially demonstrated its performance by achieving a total delta-v of 16.2 m/s through nominal burns on two thrusters—approximately 8 m/s from one and 6.8 m/s from the other—during momentum management and trajectory correction maneuvers, representing about 50% of the intended early operational capacity before the anomaly.^[19] These tests provided critical data on the propellant's behavior in microgravity, including variable thrust profiles likely due to foreign object debris, which informed improvements such as enhanced valve designs with upstream filters and refined surface finishing for future systems.^[19] The mission's total cost of approximately $16 million underscored the cost-effectiveness of smallsat platforms for lunar technology validation, operating as a low-risk testbed under NASA's SIMPLEx program.^[10] In terms of data collection, Lunar Flashlight acquired approximately 400 visible images, including detailed views of Earth and the Moon captured on March 23, 2023, which supported optical navigation experiments and provided baseline calibration for the payload.^[19] The reflectometer conducted in-flight tests, including Earth perigee experiments yielding 90 seconds of high-fidelity measurements with detector noise levels of 5.9 pA rms, validating the instrument's sensitivity for future ice detection applications despite the mission's trajectory limitations.^[4] These accomplishments contributed to NASA's Commercial Lunar Payload Services (CLPS) and Artemis programs by maturing smallsat integration for lunar exploration, with findings on propulsion reliability published in peer-reviewed works from 2023 to 2024, including analyses of the AF-M315E system's partial successes and debris mitigation strategies. In 2024, NASA published lessons learned from the mission, highlighting advancements in deep-space CubeSat operations and propulsion systems.^[27]^[19]^[4]^[48]

End of Mission

As operations progressed into April 2023, the Lunar Flashlight team had exhausted attempts to resolve the propulsion anomalies, with only intermittent thrust achievable from a single main thruster, limiting the spacecraft to basic attitude adjustments via its cold gas system while science instruments remained in a low-power state to preserve limited energy resources.^[6]^[45] On May 12, 2023, NASA announced the conclusion of the mission, determining that repeated failures to execute the necessary trajectory corrections prevented lunar orbit insertion, and thus no additional Deep Space Network resources would be allocated for ongoing tracking or operations.^[27]^[45] The spacecraft achieved a stable heliocentric orbit following an Earth flyby on May 17, 2023, at an altitude of approximately 65,000 kilometers, with the final contact occurring in May 2023; it is projected to circulate around the Sun for decades without posing any atmospheric reentry risk.^[49]^[45] Although no lunar science data were collected due to the orbital failure, approximately 90% of the pre-mission checkout and in-flight engineering data from subsystems and instruments were successfully downlinked and archived in NASA's Planetary Data System for future analysis.^[27]^[6] Post-mission reports highlighted the mission's enduring value in validating key technologies, such as the ASCENT green monopropellant and deep-space CubeSat operations, despite the inability to meet primary scientific goals, informing designs for subsequent small satellite endeavors.^[27]^[45]

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[38]
NASA's Lunar Flashlight Has Launched – Follow the Mission in Real ...
Dec 11, 2022 · “The system uses real trajectory data from the mission, so as Lunar Flashlight's journey unfolds, you can see exactly where the SmallSat is.”.Missing: plan | Show results with:plan
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4.0 In-Space Propulsion - NASA
An ASCENT propulsion system, the Lunar Flashlight Propulsion System (LFPS) ... The mission team concluded that the propulsion system's tank valve was stuck closed ...
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Team Troubleshoots Propulsion for NASA's Lunar Flashlight
Mar 23, 2023 · The opportunity to place Lunar Flashlight in such an orbit extends through the end of April. ... March 8, 2023. Next Post · Small Satellites ...Missing: anomaly timeline
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[PDF] Lessons Learned in Additive Manufacturing from the Lunar ... - NASA
Aug 9, 2023 · Lunar Flashlight was a small satellite (14kg, 6U CubeSat form factor) which supported a NASA/Jet Propulsion.Missing: specifications | Show results with:specifications
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NASA ends Lunar Flashlight mission because of thruster problems
May 15, 2023 · NASA has ended the mission of a cubesat intended to go into orbit around the moon but which was unable to do so because of problems with its propulsion system.
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[PDF] Lunar Flashlight Mission Overview | NASA
Jul 10, 2024 · Lunar Flashlight Mission Objectives. • Demonstrate new technologies ... to map water ice on the lunar surface for the Lunar Flashlight mission,” ...
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Jul 10, 2024: Lessons Learned from the Lunar Flashlight Mission
Jul 10, 2024 · This presentation will provide an overview of the LF mission, from implementation through operation. The presenter will summarize the technology successes ...<|control11|><|separator|>
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The Journey Of The Lunar Flashlight Propulsion System From ...
This paper details the in-flight journey of the LFPS, highlighting both successes and challenges met throughout the mission, and provides lessons learned.
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Lunar Flashlight science ground and flight measurements and ...
May 1, 2024 · The Lunar Flashlight (LF) mission was designed and flown to collect new data on the abundance and distribution of water ice frost in PSRs to ...
[47]
NASA's Lunar Flashlight CubeSat mission ends before entering orbit ...
May 16, 2023 · NASA is studying the possibility of a replacement for Lunar Flashlight to pursue the mission's original science goals, according to Reuter.<|control11|><|separator|>