Scientists Formulate New Method To Create Low-Cost High Efficiency Solar Cells

An anonymous reader quotes a report from Phys.Org: Scientists from the Energy Materials and Surface Sciences Unit at the Okinawa Institute of Science and Technology Graduate University (OIST) believe they've found a winning formula in a new method to fabricate low-cost high-efficiency solar cells. Prof. Yabing Qi and his team from OIST in collaboration with Prof. Shengzhong Liu from Shaanxi Normal University, China, developed the cells using the materials and compounds that mimic the crystalline structure of the naturally occurring mineral perovskite. They describe their technique in a study published in the journal Nature Communications. Perovskite offers a more affordable solution, Prof. Qi says. Perovskite was first used to make solar cells in 2009 by Prof. Tsutomu Miyasaka's research team at Toin University of Yokohama, Japan, and since then it has been rapidly gaining importance. The fabrication method he and his research team have developed produces perovskite solar cells with an efficiency comparable to crystalline silicon cells, but it is potentially much cheaper than making silicon solar cells.

To make the new cells, the researchers coated transparent conductive substrates with perovskite films that absorb sunlight very efficiently. They used a gas-solid reaction-based technique in which the substrate is first coated with a layer of hydrogen lead triiodide incorporated with a small amount of chlorine ions and methylamine gas -- allowing them to reproducibly make large uniform panels, each consisting of multiple solar cells. In developing the method, the scientists realized that making the perovskite layer 1 micron thick increased the working life of the solar cell significantly. In addition, a thicker coating not only boosted the stability of the solar cells but also facilitated the fabrication processes, thereby lowering its production costs. The team is now working on increasing the size of their newly designed solar cell prototype to large commercial-sized panels that can be several feet long. They have reportedly built a working model of their new perovskite solar modules, thanks to funding from OIST's Technology Development and Innovation Center, but "the process of upscaing has reduced the efficiency of the cells from 20% to 15%," reports Phys.Org. "[T]he researchers are optimistic that they will be able to improve the way they work in the coming years and successfully commercialize their use."

Re:

[nospam007]

"This new technology alongside the Tesla Powerbank and the Tesla car in my basement are sure to disrupt and revolutionize transportation industry."

You're doing it wrong.
The powerbank belongs in the basement, the car in the garage.
But good news, you're right, the solar singles go on the roof.

Headline a little old

[Geoffrey.landis]

I have to point out that perovskites [wikipedia.org] have been the hot research topic for low-cost solar cells for several years now. It's nice that slashdot suddenly noticed them, but mentioning one research group, while ignoring a hundred other research groups working on perovskite solar cells, is a little misleading.

For more information, here are 33,000 papers to read: https://scholar.google.com/sch... [google.com]

What Gas?

[mentil]

the substrate is first coated with a layer of hydrogen lead triiodide incorporated with a small amount of chlorine ions and methylamine gas

Great, now smurfs will be stealing solar cells so they can be used in methamphetamine production.

Cue the Republicans to tell us sun isn't reliable

[Anonymous Coward]

Like that's their job or something

Re:

[Excelcia]

Actually, the Republicans will love it and want to invest. After all, increased solar output is responsible for global warming, and that makes this a great investment.

Re:

[Waffle Iron]

Natural gas only appears cheap to those who fail to account for the damage caused by CO2 emissions and methane leakage.

Natural gas is only effcient in big chunks

[Ungrounded Lightning]

are a cheap and efficient way to turn that into electricity.

At grid scale, yes. At residential scale, not so much.

Energy storage solutions alone will not save solar power because such storage doesn't care if it is charged from solar power or anything else.

But the cost of getting the energy to the storage must be included.

Solar pa

Natural gas is only effcient in big chunks, cont.

[Ungrounded Lightning]

(Lenovo's touchpad hits "[Submit]" once again...)

Energy storage solutions alone will not save solar power because such storage doesn't care if it is charged from solar power or anything else.

But the cost of getting the energy to the storage must be included.

Large fuel-powered steam generation plants and their distribution networks have had a century of intense engineering and are currently nibbling away at the last slivers of inefficiency between their current state and theoretical limits, such as the Carno

Re:

[crunchygranola]

Anti-solar FUD from an AC. What else is new?

It is a thankless task perhaps to take on anonymous BS, the logical fail here is notable.

Cheap and efficient energy storage could in fact kill solar power, it just would not be able to compete with far more reliable energy sources to charge them up. I'm not sure even if solar power were free that it could compete because the demands for storage would still price it out of existence.

Wow. Cheap efficient energy storage will kill even free solar energy by pricing it out of existence. Who knew?

Lab demonstrations leave a lot to be desired

[DanDD]

In developing the method, the scientists realized that making the perovskite layer 1 micron thick increased the working life of the solar cell significantly.

Typical good quality crystalline silicon solar cells lose as much as 1% per year in efficiency, and lose as much as 15% efficiency in the first few months of deployment. This is why a 100 watt panel will typically produce as much as 120 watts for the first month or so, then taper off to 100 watts, then degrade slowly thereafter. This is one of the reason that to meet code, wiring for a solar installation must exceed the specs of the panels by around 20%. Now, my apologies if this isn't perfectly accurate, I've been intentionally hand-wavy as I've been out of the PV world for a bit.

Amorphous silicon is much, much worse, as it degrades as much as 10% per year, until they become opaque sheets of glass. This is why cheep Harbor Freight solar panels are cheap. Soon, they'll be just colored glass.

The manufacturing technique described in this article is similar to that of amorphous silicon, and the quoted sentence above glosses over a lot of ifs in the article. Still, I hope these researchers succeed.

Even if they don't, traditional silicon solar and some CdTe technologies are already at grid parity [scientificamerican.com], so the current state of the art can already economically offset burning stuff to keep the lights on, or charge the electric car.

Re:

[aevan]

Well, going by his.. other team? (Dr. Liu), these types of cells apparently don't even make two years [phys.org]. So either they have to be dirt cheap and easily replaced, or they'll have to work on extending the life. Personally though, more interested if the materials involved aren't as... well.. 'Chinese Lakes of Toxic Sludge'. I'd count that as a win, regardless the rest.

Re:

[Chas]

Nah. Because you're still stuck with megatons of landfill over time...

Re:

[K. S. Kyosuke]

Or you could use silicon instead, which doesn't even build a toxic mountain.

Re:

[Chas]

Just so long as you're the first person to volunteer to live on the mountain of unrecyclable panels.

Re:Lab demonstrations leave a lot to be desired

[Squirmy McPhee]

In developing the method, the scientists realized that making the perovskite layer 1 micron thick increased the working life of the solar cell significantly.

Typical good quality crystalline silicon solar cells lose as much as 1% per year in efficiency, and lose as much as 15% efficiency in the first few months of deployment. This is why a 100 watt panel will typically produce as much as 120 watts for the first month or so, then taper off to 100 watts, then degrade slowly thereafter. This is one of the reason that to meet code, wiring for a solar installation must exceed the specs of the panels by around 20%. Now, my apologies if this isn't perfectly accurate, I've been intentionally hand-wavy as I've been out of the PV world for a bit.

You're still correct on the basic principles, but the figures you give for crystalline silicon cells describe low-quality cells these days. Typical warranties these days are 2-3% degradation in the first year and 0.5%/year thereafter. The vast majority of field data is not public and that that is public suggests that plenty of modules conform to this sort of warranty and plenty don't, but for what it's worth, reinsurance companies (who actually have access to the highest volumes of field data) are willing to take on the risk of underwriting such warranties.

The manufacturing technique described in this article is similar to that of amorphous silicon, and the quoted sentence above glosses over a lot of ifs in the article.

Degradation in amorphous silicon has to do with the structure of the material itself, not the manufacturing process. That said, perovskite does have its own very serious degradation problem -- much worse than amorphous silicon, in fact -- that needs to be solved (or at least improved) before it will become practical as a major energy source. Even if it can be made cheaper than crystalline silicon, it's hard to see it gaining much traction outside of consumer gadgets and specialized short-term applications if the cells die after 5 years. Someone could still make money that way, but it wouldn't address much of our energy demand.

That said, what I've seen of this work is promising because the scientists are at least making an effort to address many of the issues that have to be solved to commercialize perovskite cells. There is increasing attention paid to that, but it seems to me that many researchers still prefer to chase headline-grabbing efficiencies. I wish them luck, but I do firmly believe they will struggle to create a successful commercial product if they don't make some strides on longevity.

Re:

[K. S. Kyosuke]

Typical good quality crystalline silicon solar cells lose as much as 1% per year in efficiency, and lose as much as 15% efficiency in the first few months of deployment.

Not necessarily, really. [psu.edu] One might argue that making them look "good as new" even after two decades really should be the next goal for the PV industry.

Re:

[Anonymous Coward]

Typical good quality crystalline silicon solar cells lose as much as 1% per year in efficiency, and lose as much as 15% efficiency in the first few months of deployment. This is why a 100 watt panel will typically produce as much as 120 watts for the first month or so, then taper off to 100 watts, then degrade slowly thereafter. This is one of the reason that to meet code, wiring for a solar installation must exceed the specs of the panels by around 20%. Now, my apologies if this isn't perfectly accurate, I've been intentionally hand-wavy as I've been out of the PV world for a bit.

At least in the USA the reason for the 20% margin on wiring gauge is because of a safety factor, this applies to any device considered a "constant load". I found this out when helping someone install some electric heaters. I found it odd that every heater we saw with a 30 amp plug would consume no more than 24 amps, and 15 amp heaters had 20 amp plugs. When looking at the National Electrical Code these plugs were required to meet code.

Lots of other loads, like motors and even some lighting, will have a

What's the life?

[whoever57]

I thought the big issue with using perovskite in solar panels is useful life.

Since this is coming out of China...

[Chas]

I'll wait until the research comes in.

Clever Trump

[TJHook3r]

Waiting for prices to fall before pushing solar energy, as he inevitably will!