56 lines
No EOL
3 KiB
Markdown
56 lines
No EOL
3 KiB
Markdown
---
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type: entity
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entity_type: research_program
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name: Alba Mons Lava Tube System
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domain: space-development
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status: characterized
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supports:
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- Alba Mons at 40.47°N is the strongest known Mars settlement co-location candidate because it offers documented lava tube systems and ice-rich mantling deposits within the same volcanic structure
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reweave_edges:
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- Alba Mons at 40.47°N is the strongest known Mars settlement co-location candidate because it offers documented lava tube systems and ice-rich mantling deposits within the same volcanic structure|supports|2026-05-04
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---
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# Alba Mons Lava Tube System
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**Location:** 40.47°N, 250.4°E (Arcadia quadrangle, Mars)
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**Status:** Morphologically characterized, not thermally characterized
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**Significance:** Strongest known Mars settlement co-location candidate for radiation shielding and water ISRU
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## Overview
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Alba Mons is a broad shield volcano hosting documented lava tube systems on its western flank, with ice-rich mantling deposits overlying the volcanic structure itself. At 40.47°N, it sits within the brine-active zone (>30°N) and adjacent to Arcadia Planitia's excess ice deposits.
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## Key Features
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**Lava Tubes:**
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- Large concentration of lava tube systems on western flank (Crown et al. 2022)
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- Morphologically characterized but not thermally characterized
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- Provide standard Mars lava tube radiation shielding: ~20x GCR dose reduction at 6.25m depth to ~12 mSv/year
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**Water Ice:**
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- Ice-rich mantling deposits directly overlie Alba Mons features (Crown et al. 2022)
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- Pedestal craters, infilled craters, heavily mantled lava flow margins on northern distal flanks
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- Within 2 degrees latitude of Amazonis Planitia shallow ice sites (AP-1, AP-8, AP-9)
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- Located in brine-active zone (>30°N) with seasonal near-surface melting
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## Co-location Advantage
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Alba Mons is the only Mars site currently characterized where:
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1. Lava tube radiation shielding is documented
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2. Ice-rich deposits exist on the same volcanic structure
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3. Location falls within the brine-active zone for liquid water access
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This makes it a stronger settlement co-location candidate than Elysium Mons (24-29°N, outside shallow ice zone) despite Elysium having a more thoroughly studied skylight.
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## Limitations
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- Lava tubes are morphologically characterized only (Crown 2022), not thermally characterized like Elysium Mons skylight
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- Northern latitude (40°N) means colder surface temperatures
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- Tube accessibility relative to ice deposits requires site-specific analysis
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- Lower altitude than other Tharsis volcanoes but gentler slopes
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## Timeline
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- **2022** — Crown et al. publish "Distribution and Morphology of Lava Tube Systems on the Western Flank of Alba Mons, Mars" in JGR:Planets, documenting large lava tube concentration and ice-rich mantling deposits
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- **2025** — Luzzi et al. document near-surface ice at Amazonis Planitia sites within 2 degrees latitude of Alba Mons
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- **2025** — Nature Communications marsquake study confirms brine-active zone >30°N, placing Alba Mons within seasonal liquid water access region |