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Understanding the risks of returning icy samples from the lunar south pole for analysis.

February 28, 2026Open Access

The Challenge of Icy Sample Return Begins With Artemis

Puntos clave

Understanding the risks of returning icy samples from the lunar south pole for analysis.
Modeling phase behavior of H2O-NH3 binary ices under lunar conditions.
Analyzing peritectic melting effects on icy samples.
Examining sublimation processes impacting sample integrity.
H2O-rich ices can melt or change texture at temperatures below -95°C.
Sublimation of NH3 starts 100°C lower at lunar surface pressures, risking sample integrity.
Misinterpretation of solution chemistry can harm Artemis mission planning.

Resumen

Abstract Throughout the Solar System, volatiles are found as solid ices. Returning ices to Earth for scientific analysis is critical to understanding the formation of a Solar System that bears life. This challenge begins with the Artemis missions to the lunar south polar region, where the coldest lunar regolith is enriched in H2O and other ices—systems with complex phase equilibria. Ignoring solution chemistry results in erroneous conclusions that—if allowed to guide Artemis sampling, transport, and curation planning—would result in irreparable damage to returned samples. Here we use the H2O‐NH3 binary as a model for more complex ices. At 1 bar, H2O‐rich ices undergo peritectic melting at or below −95°C, changing the textural record of the ice and generating a liquid with >30% NH3. At lunar surface pressures, sublimation of NH3—and sample damage—begins at least 100 C° lower, increasing the challenge of icy sample return.

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