[fastball]

But is that maintenance lower than the existing maintenance burden?

Even then, this is still a wildly conservative estimate in terms of price. For example, you're also not taking into account any of the things that can't currently be easily electrified, such as passenger jets.

[WJW]

It'd need to be lower than the existing maintenance plus fuel burden of course, since sunshine is free but oil and coal are not. In any case, if you can't change the power source (as you say, passengers jets are pretty tricky to electrify) then you don't have to build solar panels for those so the upfront cost would go down.

Thinking about it more it would seem likely that as overall oil consumption falls, the relative cost of oil derivatives like jet fuel would go up because the advantages of scale decrease from what they are now. It's a pretty fascinating subject since solar prices seem to follow a Moore's law type price evolution at the moment while oil will get cheaper as well while demand decreases. Presumably there is a balance point somewhere?

[carbonguy]

> But is that maintenance lower than the existing maintenance burden?

While I haven't looked up the data yet, it seems plausible to assume that maintenance on photovoltaic electric generation is not only lower but significantly lower than thermal generation.

For example, having no moving parts in the generation process must be a large maintenance savings, though of course there must be unique costs associated with photovoltaics - cleaning, perhaps?

> Even then, this is still a wildly conservative estimate in terms of price.

I just did some quick calculations to check this statement and found it basically true - I estimate the cost of 100% PV solar generation at around $180tn 2019 USD for 30 years of capacity.

For reference, I used these figures:

173,340 TWh energy consumption in 2019 [1] * $35/MWh for utility-scale PV solar[2] * 1,000,000 MWh/TWh = $6.1t yearly energy cost for 100% PV energy production, or $182t over a 30-year lifetime.

This, of course, does not take into account the increase of energy consumption over that period which would raise costs, nor the economies of scale of this level of PV deployment which would surely lower costs, but as a BotE calculation it sounds about right and corresponds with your earlier estimate of $210tn for the same investment. Note also that the $35/MWh figure includes all operating expenses and amortized capital costs i.e. it takes all costs into account already.

However, as you imply with your first question regarding maintenance burden, the correct comparison is not "how much would it cost" but rather "how much would it cost relative to projected costs of energy" - and again per [2], utility PV solar is already cheaper than new utility thermal power generation. There is of course plenty of nuance when it comes to energy consumption - you point out, for example, that aviation will be a difficult sector to "electrify," a true enough statement in and of itself. However, it's pointed out in [3] that jet fuel represents 12% of transportation energy consumption and that transportation overall represents 25% of global energy consumption, implying that aviation only represents about 3% of global energy consumption.

Based on this, I speculate that aviation fuels can be produced in a 100% solar PV energy regime without increasing - and likely lowering - energy production costs above the current regime.

[1] https://ourworldindata.org/energy-production-consumption [2] https://www.lazard.com/perspective/lcoe2019 [3] https://www.maritime-executive.com/article/transport-uses-25...