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Understanding Solar Energy

(www.construction-physics.com)
261 points chmaynard | 7 comments | 20 Mar 25 12:09 UTC | HN request time: 0.838s | source | bottom
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pjc50 ◴[20 Mar 25 14:19 UTC] No.43423893[source]
Good longread.

What I'd like to have a better understanding of, and I'm hoping to crowdsource here, is exactly how the solar panel cost has come down so precipitously. Part of it is simply manufacture scaling - almost everything is much cheaper in large quantities. But part of it must be a thousand incremental tech advances. Things like the reduced kerf diamond wire saw.

Also of note: I think monocrystalline has won completely? People experimented with all sorts of alternate chemistries and technologies, like ion deposition and the extremely poisonous CIGS, but good old "Czochralski process + slice thinly" has won despite being energy intensive itself.

Perovskites remain an unknown quantity.

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philipkglass ◴[20 Mar 25 15:45 UTC] No.43424853[source]
The article posted by wolfram74 is part one of two, covering solar PV history up through the early 1980s.

Here's part two of the series with more recent history: https://www.construction-physics.com/p/how-did-solar-power-g...

Even this fairly long two-part discussion misses some of the more important technical developments of the past 20 years.

Converting trichlorosilane to pure silicon via CVD growth in Siemens-type reactors is now much more energy efficient due to changes in rod geometry and heat trapping via reactor design. A significant minority of purified silicon is now manufactured via even more efficient fluidized bed reactors.

The solar industry is dominated by Czochralski process monocrystalline silicon, but it's now continuous Czochralski: multiple crystals grown from a single crucible, recharging the molten silicon over time; the traditional process used a crucible once and then discarded it.

The dominant silicon material has switched from boron doped p-type silicon to gallium doped p-type silicon (mentioned by pfdietz) to phosphorus doped n-type silicon (used by the currently dominant TOPCon cell technology as well as heterojunction (HJT) cells and most back contact cells).

Changes in wafering that you mentioned (like the reduced kerf diamond wire saw) have reduced silicon consumption per wafer and therefore per watt, even holding cell technology constant.

The dominant cell technology has moved from Al-BSF to PERC to mono-PERC to TOPCon. Heterojunction and back-contact cells are not yet dominant, but they are manufactured on a multi-gigawatt scale and will probably overtake TOPCon eventually. Each one of these changes has eked out more light conversion efficiency from the same area of silicon.

Cells mostly still use screen-printed contacts made from conductive silver pastes, much like 20 years ago, but there has been continuous evolution of the geometry and composition of applied pastes so that silver consumption per watt is now much lower than it used to be. This is important because silver has the highest cost per kilogram of any material in a typical solar panel, and it's the bottleneck material for plans to expand manufacturing past the terawatt scale.

Wafer, cell, and module manufacturing have become much more automated. That reduced labor costs, increased throughput, and increased uniformity.

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1. justanotherjoe ◴[20 Mar 25 16:04 UTC] No.43425068[source]
In terms of resource extraction needed for the batteries and the panels, how sustainable is it? The way I understand it is that you can't really repair broken panels and batteries... Can we still make these after, let's say, 500 years? I have no conception at all in this topic...
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2. pjc50 ◴[20 Mar 25 16:09 UTC] No.43425131[source]
No, but I don't see a good reason why you can't recycle the cells especially given they contain a thin layer of silver. Google already finds local recycling firms, since it's required by WEEE.

(The 500 years question has issues for all the other sources of energy as well!)

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3. ◴[20 Mar 25 16:14 UTC] No.43425196[source]
4. ZeroGravitas ◴[20 Mar 25 17:39 UTC] No.43426313[source]
Yes, batteries are getting better at such a rate that you can recycle old batteries at end of life, lose 10% of the material in that process and build a new battery with new tech and less material that is better than the original.

The resource extraction issue is more than these are so useful we're going to build an ever growing amount of them.

Luckily they're made from widely available materials, with even more widely available substitutions possible e.g sodium batteries.

5. adgjlsfhk1 ◴[21 Mar 25 00:58 UTC] No.43430818[source]
You can't repair, but you can recycle (although doing so likely isn't very profitable until the exponential price decrease stops)
6. ben_w ◴[21 Mar 25 08:47 UTC] No.43433254[source]
The resources all start off chemically bound in rocks that aren't famous for spontaneously generating or storing electricity.

I don't see it being meaningfully more expensive to process smashed up old PV or batteries than starting from the natural state, and my expectation is that it would be easier.

The exception would be if some of the chemical pathways turn into low-concentration atmospheric gasses that then diffuse all over the world, which is how we got the problem with CO2 (and unrelated problems with CFCs).

7. pfdietz ◴[23 Mar 25 23:39 UTC] No.43456743[source]
Aside from silver for contact wires, PV panels are made (or could be made) with mundane materials available in essentially unlimited amounts. The total mass flowing through new PV panels each year if the US were fully solar powered would be much less than the volume of mundane material flowing through the system already. For example, the EPA estimated that in 2018 the US generated 600 million tons of construction and demolition waste (of which 143 million tons went to landfills.)

https://www.epa.gov/facts-and-figures-about-materials-waste-...