Mastodawn

Ketan Joshi Mar 28, 2023

Me and a few other climate folks on Twitter have noticed a very clear new prominence of climate deniers and delayers

So with some help, I gathered up some data and checked - it turns out that denial/delay, pro-fossil disinformation accounts have seen massive growth in their audience, while pro-climate-action accounts have either stagnated or shrunk.

Elon Musk is reshaping Twitter into a safe space for right-wingers, and in doing so, empowering climate change deniers, delayers and pro-fossil advocates more than ever before.

New post:

https://ketanjoshi.co/2023/03/28/musk-is-remaking-twitter-into-a-climate-denier-sanctuary/

Musk is remaking Twitter into a climate denier sanctuary

I got some data that analyses how climate deniers have changed their audience size, relative to pro-climate accounts, on Musk’s Twitter. It’s….not good.

Ketan Joshi

serklarvel Mar 29, 2023

@ketan ironically, Elon's fortune comes from a company that sells electric cars, which is supposed to reduce carbon gas emitions

Hypx Mar 29, 2023

@serklarvel @ketan Battery electric cars are just a greenwashing exercise. The real future will be #hydrogen powered cars.

serklarvel Mar 29, 2023

@Hypx @ketan agree, I don't believe electrical cars are the solution

Blake Leonard Mar 29, 2023

@serklarvel @Hypx @ketan The future is going to be (or maybe just should be) good public transportation, and "small" vehicles like bikes, skateboards, and scooters :)
As for hydrogen fuel, I feel like it's best suited for use as backup power, but not as the primary power source since it's inefficient and costly (it takes way more power to produce than it puts out).
I don't have any idea what a good primary power source for civilian vehicles like cars should be, if not batteries (which blow up).

Hypx Mar 29, 2023

@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.

Grassroots Joe Mar 29, 2023

@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?

Hypx Mar 29, 2023

@joeinwynnewood @blake @serklarvel @ketan Let's just say BEVs will never be the solution for everyone and there must be an alternative.

Grassroots Joe Mar 30, 2023

@Hypx @blake @serklarvel @ketan What is undoubtedly true is that hydrogen will/must be instrumental in the decarbonization of heavy industry, air and sea transportation.
Beyond that I think is very much up in the air depending on how much green hydrogen is available how soon.
EV adoption could go much faster than H2 availability depending on several factors.
There is also the future grid stability benefit of distributed energy storage in millions of garages to be considered.

Hypx Mar 30, 2023

@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.

Blake Leonard Mar 30, 2023

@Hypx @joeinwynnewood @serklarvel @ketan Hydrogen production and storage is highly inefficient. It costs about 5 times more energy to make (and contain?) it than it produces.
Plus, the production of hydrogen, especially now, will likely use fossil fuels.

Hypx Mar 30, 2023

@blake @joeinwynnewood @serklarvel @ketan It helps to not swallow BEV propaganda on this subject. The efficiency between hydrogen and lithium is not significant, and both are vastly more efficiency than conventional internal combustion engines. This becomes more obvious once you realize the need for grid energy storage and the cost and raw material problems of li-ion batteries.

ckfinite Apr 22, 2023

@Hypx @blake @joeinwynnewood @serklarvel @ketan Lithium batteries are extremely efficient on a columbic basis (you get in about 99% of the energy out what you put in https://www.nature.com/articles/s41560-020-0648-z). The main loss of energy is in the charger itself, and modern SMPS design can get that to around 90% efficiency. Hydrogen is considerably worse than this.

Understanding and applying coulombic efficiency in lithium metal batteries - Nature Energy

Coulombic efficiency (CE) has been frequently used to assess the cyclability of newly developed materials for lithium metal batteries. The authors argue that caution must be exercised during the assessment of CE, and propose a CE testing protocol for the development of lithium metal batteries.

Nature

ckfinite Apr 22, 2023

@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.

ckfinite Apr 22, 2023

@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.

Hypx Apr 22, 2023

@ckfinite @blake @joeinwynnewood @serklarvel @ketan This is mostly just propaganda. A fuel cell is an electrochemical system. It has more or less same rules governing it. Theoretical efficiency is 100% at every step. Real world analysis will also find that batteries have huge efficiency issues of their own (weight, production, parasitic losses, cold weather, etc.), and in practice there is little to no difference in efficiency.

ckfinite Apr 22, 2023

@Hypx @blake @joeinwynnewood @serklarvel @ketan When you say 100% efficiency, what's that in relation to? Is it realized efficiency of the process compared to maximum theoretical performance or in terms of overall thermodynamic efficiency?

Hypx Apr 22, 2023

@ckfinite @blake @joeinwynnewood @serklarvel @ketan In relationship to energy efficiency. You are just confusing yourself. As electrolysis and fuel cell reactions are electrochemical processes, they work the same way as li-ion batteries. People are simply creating an elaborate fiction for why only some electrochemical systems are possible and others are not.

@Hypx @blake @joeinwynnewood @serklarvel @ketan Not all electrochemical reactions work the same way? The chemistry that li-on batteries use is fundamentally different than the chemistry that's happening in electrolysis. A simple example of how different chemistry begets very different performance is to compare alkaline batteries to lithium ion batteries. They're both electrochemical processes, but their realized performance is very different!

Hypx Apr 22, 2023

@ckfinite @blake @joeinwynnewood @serklarvel @ketan Just so you are aware, alkaline batteries and li-ion batteries have almost the same columbic density. The only difference is voltage. The energy density difference comes almost entirely from this fact.