@blake @serklarvel @ketan The point of hydrogen is that it neither depends on fossil fuels nor excess raw materials. If we are going to have civilian vehicles (which face it, we will), it must be something like hydrogen cars.

The counterarguments are really just FUD from battery car companies. They don't even want you to know that a fuel cell is an electrochemical cell, and that FCEVs are EVs too. There's very little downside compared to other EVs.

@Hypx @blake @serklarvel @ketan
Re: fossil-fuel dependence
It's true that H2 production doesn't have to depend on fossil-fuels, but it currently does.

It's important to state that H2 as a green fuel requires a very large increase in renewable electricity to use to produce green hydrogen.

Building a retail hydrogen distribution system is also needed to be the auto fuel solution. Easier or harder than charging stations?

@joeinwynnewood @blake @serklarvel @ketan BEV adoption does not follow green electricity FYI. In many cases, they are just being powered by fossil fuels. We should not have a double standard here.

Using car batteries as a way to stabilize the grid is an incredibly dumb idea. Those batteries are not designed for that. Meanwhile, hydrogen for grid energy storage completely solves the problem.

@Hypx @blake @joeinwynnewood @serklarvel @ketan

Hydrogen production is at best about 80% efficient (https://www.sciencedirect.com/science/article/pii/S2589299119300035), the fuel cell is about 60% efficient (https://www.sciencedirect.com/science/article/abs/pii/S1364032111004709) and then you have another voltage conversion (another 90%ish efficient step). This doesn't include compression or liquefaction for transport.

All-in, then, hydrogen is only around 40% efficient (https://www.sciencedirect.com/science/article/abs/pii/S0360319908015061) at delivering electric energy to a motor vs. the 80-90% offered by BEVs.

@Hypx @blake @joeinwynnewood @serklarvel @ketan
Compressing or liquefying H2 for transportation requires another step of between 80% and 60% efficiency to be added on top (https://www.hydrogen.energy.gov/pdfs/9013_energy_requirements_for_hydrogen_gas_compression.pdf).

Thus, on a kWh-for-kWh basis, the hydrogen car is considerably less efficient (by about a factor of 2 to 3) compared to a BEV. The main advantage would be if you can make hydrogen without needing electricity.

@ckfinite @blake @joeinwynnewood @serklarvel @ketan I cannot access the whole paper, but he is factually wrong if he is making that claim. The theoretical limit is 100% efficiency, as in 100% conversion of chemical to electrical energy.

https://www.dynamictidalpower.eu/resources/Documenten/Maximum_conversion_efficiency_of_hydroge.pdf

@Hypx The 72% thermodynamic efficiency is of a *realized* PEM fuel cell; the theoretical 100% efficiency is a lot like carnot-ideal efficiency: you don't get particularly close to that.

In that paper they note that even the idealized efficiency with real gases is not 100%:
> The lowest value of the maximum efficiency is 82.1%, 75.7%,
and 79.3%, respectively, for CH4-air fuel cell, H2eO2 fuel cell,
and H2-air fuel cell and the corresponding highest maximum
efficiency is 92.7%, 82.7% and 82.7%.