HyFlux Aviation LCA

Well-to-Wake Lifecycle Analysis — Boeing CASCADE V2.7

Compare Liquid Hydrogen, Sustainable Aviation Fuel, and Superconducting H₂-Electric propulsion pathways for aviation decarbonisation through 2050.

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Core Capabilities

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3 Propulsion Pathways

Analyze LH₂-fueled, SAF-powered, and superconducting H₂-electric aircraft architectures with detailed payload trade studies.

LH₂ | SAF | H₂-E
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5 SAF Feedstocks

Compare waste-to-fuel, algae, forest residue, camelina, and hydroprocessed esters across regional carbon intensity.

HEFA | ATJ | SPK
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130+ Parameters

Configure energy density, GWP, regional electricity grids, airport infrastructure, and operational efficiency factors.

CASCADE v2.7
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Real-Time Charts

Interactive lifecycle emissions, cost comparison, energy density, and sensitivity analysis dashboards.

Chart.js + Mapbox

What You Can Do

1

Configure Aircraft & Routes

Set payload, range, cruise altitude, and route parameters for regional or intercontinental missions.

2

Select Fuel Pathways

Choose LH₂, SAF feedstock, or H₂-electric powertrain with supply chain transparency.

3

Customize Energy Grids

Adjust regional electricity mix to reflect coal, gas, wind, solar, or nuclear production assumptions.

4

Analyze Well-to-Wake Emissions

View cradle-to-grave GWP including fuel production, transport, infrastructure, and operational burn.

5

Run Sensitivity Studies

Test carbon intensity, hydrogen cost, electricity grid decarbonisation, and aircraft efficiency improvements.

6

Export & Share Results

Download charts, comparison tables, and executive summaries for stakeholder presentations.