Interstellar Greenhouse — Alien Plant Encyclopedia

Explore how Earth crops adapt to low gravity, high radiation, and exotic starlight. Simulate plant growth on alien worlds and find the best species for your colony.

財務データや従業員数は記録しません。すべての計算はブラウザ内で即座に実行されます。

Environment Parameters

Light Intensity (PPFD) — 300 µmol/m²/s

102000

Spectral Type

Atmospheric Pressure — 60 kPa

0.1200

Surface Gravity — 0.38 g

0.012.5

Effective PAR

79.5 µmol/m²/s

Radiation Factor

1.4×

PAR Fraction

45%

Peak Wavelength

550 nm

Plant Recommendations

Species	Type	Viability	Days to Harvest	Yield	LED Power
Radiotrophic Fungus (Xeno-engineered) Fictional: uses melanin to convert gamma radiation into metabolic energy	Fictional	High (95%)	14 d	2.86 g/m²/d	—
Silicon Cactus (Xenomorphica) Fictional: silicon-based extremophile, survives near-vacuum, slow growth	Fictional	High (95%)	180 d	1.43 g/m²/d	—
Arabidopsis thaliana Model plant, rapid life cycle, used in ISS experiments	Real	High (95%)	42 d	0.47 g/m²/d	28.2 W/m²
Chlorella (Microalgae) Extremophile algae, high O2 production, rapid growth	Real	High (81%)	3 d	16.15 g/m²/d	8.2 W/m²
Sweet Potato High-calorie tuber, NASA ALS candidate crop	Real	Medium (70%)	120 d	5.58 g/m²/d	128.2 W/m²
Potato High-yield staple, validated in sealed chamber trials	Real	Medium (70%)	90 d	4.88 g/m²/d	128.2 W/m²
Dwarf Wheat Compact cereal, ISS-tested, medium light needs	Real	Medium (65%)	70 d	3.27 g/m²/d	168.2 W/m²

Viability scores are weighted: PAR suitability (35%), radiation tolerance (35%), pressure (15%), gravity (15%). LED power assumes horticultural LEDs at 2.5 µmol/J efficacy.

Species data sourced from NASA BVAD (2018), Wheeler et al. (2003), and Poulet et al. (2020). Fictional species are speculative designs based on known extremophile biology.

Space Agriculture Science

Photosynthesis in Red Dwarf Light

M-dwarf stars emit mostly infrared. Plants evolved under G-type spectra need adapted LED spectra to photosynthesize efficiently. Research shows red:blue ratios of 3-5:1 work best for biomass accumulation.

Gravity & Root Architecture

Microgravity disrupts gravitropism. ISS experiments show roots grow in spirals without gravity cues. Porous tube hydroponics and aeroponics are leading solutions for root zone management in space.

Radiation Shielding for Crops

Galactic cosmic rays damage plant DNA. Underground greenhouses (lava tubes) or water-shielded modules can reduce exposure 100-1000x. Polyploid plants show enhanced radiation tolerance.

Frequently Asked Questions

How are plant viability scores calculated?

Viability is a weighted score (0-1) based on PAR suitability (35%), radiation tolerance (35%), atmospheric pressure (15%), and gravity (15%). A score above 0.7 indicates high viability for the given environment.

What do the fictional plant species represent?

Fictional species are speculative designs based on known extremophile biology on Earth. Radiotrophic fungi are inspired by melanin-rich Cryptococcus found in Chernobyl. Silicon-based organisms are theoretical constructs for ultra-low-temperature, low-pressure environments.

How is LED power consumption calculated?

LED power is calculated assuming 2.5 µmol/J horticultural LED efficacy. The supplemental PAR needed to reach each species minimum optimal range is divided by this efficacy to estimate watts per square meter.

Does this tool account for Martian/Lunar regolith?

The current version focuses on atmospheric, gravitational, and radiative factors. Soil chemistry (regolith toxicity, nutrient availability) is planned for a future update.

ECLSS計算機

モル質量

Eco-Metrics

MoonSync

財務データや従業員数は記録しません。すべての計算はブラウザ内で即座に実行されます。 · モル質量はIUPAC 2023原子量およびNIST標準参照データベース144に基づき、200種類の一般的な化合物についてPubChem参照値と検証（平均偏差 < 0.001 g/mol）。炭素排出量はCloud Carbon Footprint 2024手法およびEPA 2025排出係数を使用 — ISO 14064認証会計ではなく、方向性のあるESG報告に適しています。