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Again, why are you talking about cost, when the real question is viability? How does the study you linked plan to accommodate intermittency? The answer is just a vague statement about storage mechanisms: > Storage of energy is an important element of 100% RE systems, especially when using large shares of variable sources
like solar and wind [14], [40]–[42], and it can take various forms [43]–[45]. Batteries can supply efficient short term storage, while e-fuels can provide long-term storage solutions. Other examples are mechanical storage in pumped hydro energy storage [46], [47] and compressed air energy storage [48], [49], and thermal energy in a range of storage media at various temperature levels [43], [50]. Nowhere do they actually outline how much storage of each system they will provision. How many TWh of batteries? How many TWh of pumped hydro? Totally unanswered. They just mention the existence of storage, and avoid any tangible discussion of scale. Like I said, there's no realistic plans for a grid primarily powered by intermittent sources. The storage required for such a grid is orders of magnitude larger than what can be feasibly provisioned. This isn't a tiny insignificant detail. It's is a foundational part of a primarily renewable grid. And nobody has a plan to solve it that doesn't amount to "assume some different system, which has never been deployed at scale, can tens of terawatt hours of storage". |
In the real world the energy crisis was a cost crisis. But you seem to no care the slightest about massively increasing the ratepayers bills and by that creating a new self made energy crisis. This time fueled by nuclear subsidies.
So you skipped the first two studies. I suppose because you found nothing to complain about in them. Good to know.
Then you go on a meta-analysis on the entire field and demand them to produce a TWH figure for some energy system you can't even specify.
You truly are grasping for the straws.
Here's the quote you missed:
> Much of the resistance towards 100% RE systems in the literature seems to come from the a-priori assumption that an energy system based on solar and wind is impossible since these energy sources are variable. Critics of 100% RE systems like to contrast solar and wind with ’firm’ energy sources like nuclear and fossil fuels (often combined with CCS) that bring their own storage. This is the key point made in some already mentioned reactions, such as those by Clack et al. [225], Trainer [226], Heard et al. [227] Jenkins et al. [228], and Caldeira et al. [275], [276]. However, while it is true that keeping a system with variable sources stable is more complex, a range of strategies can be employed that are often ignored or underutilized in critical studies: oversizing solar and wind capacities; strengthening interconnections [68], [82], [132], [143], [277], [278]; demand response [279], [172], e.g. smart electric vehicles charging using delayed charging or delivering energy back to the electricity grid via vehicle-to-grid [181], [280]– [282]; storage [40]– [43], [46], [83], [140], [142], such as stationary batteries; sector coupling [16], [39], [90]– [92], [97], [132], [216], e.g. optimizing the interaction between electricity, heat, transport, and industry; power-to-X [39], [106], [134], [176], e.g. producing hydrogen at moments when there is abundant energy; et cetera. Using all these strategies effectively to mitigate variability is where much of the cutting-edge development of 100% RE scenarios takes place.
> With every iteration in the research and with every technological breakthrough in these areas, 100% RE systems become increasingly viable. Even former critics must admit that adding e-fuels through PtX makes 100% RE possible at costs similar to fossil fuels. These critics are still questioning whether 100% RE is the cheapest solution but no longer claim it would be unfeasible or prohibitively expensive. Variability, especially short term, has many mitigation options, and energy system studies are increasingly capturing these in their 100% RE scenarios.
With the conclusion based on the meta-analysis:
> The main conclusion of the vast majority of 100% renewable energy systems studies is that such systems can power all energy in all regions of the world at low cost. As such, we do not need to rely on fossil fuels in the future. In the early 2020s, the consensus has increasingly become that solar PV and wind power will dominate the future energy system and new research increasingly shows that 100% renewable energy systems are not only feasible but also cost effective. This gives us the key to a sustainable civilization and the long-lasting prosperity of humankind.
Since the study was released in mid 2022 has it become easier to harder to create 100% renewable energy systems? Easier.