Expert-level hydrogen energy covering production methods, storage, fuel cells, hydrogen economy, safety, and the role of hydrogen in decarbonization.
Grey hydrogen: steam methane reforming, 95% of current production, high CO2 emissions. Blue hydrogen: SMR with carbon capture, lower emissions, CCS reliability concerns. Green hydrogen: water electrolysis using renewable electricity, zero direct emissions. Electrolysis types: alkaline, PEM, solid oxide, each with different efficiency and cost. Electrolyzer efficiency: 65-80% HHV for current systems, improving with technology.
Compressed gas: 350-700 bar in high-pressure tanks, gravimetric density 5-6%. Liquid hydrogen: cryogenic at minus 253 C, higher density, boil-off losses. Metal hydrides: absorbed into metal lattice, heavy, low temperature release. Chemical carriers: ammonia and LOHC, higher energy density, reconversion needed.
PEM fuel cell: proton exchange membrane, low temperature, fast startup, transport. SOFC: solid oxide fuel cell, high temperature, high efficiency, fuel flexibility. Reaction: H2 plus O2 produces H2O plus electricity plus heat. Efficiency: 50-60% electrical, 80-90% combined heat and power. Stack degradation: membrane degradation, catalyst poisoning, water management.
Hard-to-abate sectors: steel, cement, shipping, aviation, chemical feedstock. Hydrogen color codes: green, blue, grey, turquoise, pink depending on production method. Infrastructure: pipelines repurposed from natural gas, distribution network needed. Cost trajectory: green hydrogen cost falling, grid parity with grey in some regions.
| Pitfall | Fix |
|---|---|
| Ignoring electrolyzer efficiency | 70% efficiency means 30% of renewable electricity lost |
| Treating all hydrogen as green | Verify production method and carbon intensity |
| Underestimating compression energy | Compression to 700 bar uses significant energy |
| Hydrogen vs direct electrification | Direct use of electricity is more efficient in most cases |