By combining two types of photovoltaic material, researchers from MIT and Stanford have developed a new “tandem” solar cell that harnesses more sunlight.
Researchers at MIT and Stanford University have developed a new kind of solar cell that combines two different layers of sunlight-absorbing material in order to harvest a broader range of the sun’s energy. The development could lead to photovoltaic cells that are more efficient than those currently used in solar-power installations, the researchers say.
The new cell uses a layer of silicon — which forms the basis for most of today’s solar panels — but adds a semi-transparent layer of a material called perovskite, which can absorb higher-energy particles of light. Unlike an earlier “tandem” solar cell reported by members of the same team earlier this year — in which the two layers were physically stacked, but each had its own separate electrical connections — the new version has both layers connected together as a single device that needs only one control circuit.
The new findings are reported in the journal Applied Physics Letters by MIT graduate student Jonathan Mailoa; associate professor of mechanical engineering Tonio Buonassisi; Colin Bailie and Michael McGehee at Stanford; and four others.
“Different layers absorb different portions of the sunlight,” Mailoa explains. In the earlier tandem solar cell, the two layers of photovoltaic material could be operated independently of each other and required their own wiring and control circuits, allowing each cell to be tuned independently for optimal performance.
By contrast, the new combined version should be much simpler to make and install, Mailoa says. “It has advantages in terms of simplicity because it looks and operates just like a single silicon cell,” he says, with only a single electrical control circuit needed.
One tradeoff is that the current produced is limited by the capacity of the lesser of the two layers. Electrical current, Buonassisi explains, can be thought of as analogous to the volume of water passing through a pipe, which is limited by the diameter of the pipe: If you connect two lengths of pipe of different diameters, one after the other, “the amount of water is limited by the narrowest pipe,” he says. Combining two solar cell layers in series has the same limiting effect on current.
To address that limitation, the team aims to match the current output of the two layers as precisely as possible. In this proof-of-concept solar cell, this means the total power output is about the same as that of conventional solar cells; the team is now working to optimize that output.
Perovskites have been studied for potential electronic uses including solar cells, but this is the first time they have been successfully paired with silicon cells in this configuration, a feat that posed numerous technical challenges. Now the team is focusing on increasing the power efficiency — the percentage of sunlight’s energy that gets converted to electricity — that is possible from the combined cell. In this initial version, the efficiency is 13.7 percent, but the researchers say they have identified low-cost ways of improving this to about 30 percent — a substantial improvement over today’s commercial silicon-based solar cells — and they say this technology could ultimately achieve a power efficiency of more than 35 percent.
They will also explore how to easily manufacture the new type of device, but Buonassisi says that should be relatively straightforward, since the materials lend themselves to being made through methods very similar to conventional silicon-cell manufacturing.
One hurdle is making the material durable enough to be commercially viable: The perovskite material degrades quickly in open air, so it either needs to be modified to improve its inherent durability or encapsulated to prevent exposure to air — without adding significantly to manufacturing costs and without degrading performance.
This exact formulation may not turn out to be the most advantageous for better solar cells, Buonassisi says, but is one of several pathways worth exploring. “Our job at this point is to provide options to the world,” he says. “The market will select among them.”
“I think this work is very significant,” says Martin Green, a professor at the University of New South Wales, in Australia, who was not connected with this research. “The work is important in establishing a proof-of-concept and will stimulate higher efficiencies with this approach. … It’s an excellent starting point for further work in this area.”
The research team also included Eric Johlin PhD ’14 and postdoc Austin Akey at MIT, and Eric Hoke and William Nguyen of Stanford. It was supported by the Bay Area Photovoltaic Consortium and the U.S. Department of Energy.
Reference: “A 2-terminal perovskite/silicon multijunction solar cell enabled by a silicon tunnel junction” by Jonathan P. Mailoa, Colin D. Bailie, Eric C. Johlin, Eric T. Hoke, Austin J. Akey, William H. Nguyen, Michael D. McGehee and Tonio Buonassisi, 24 March 2015, Applied Physics Letters.
DOI: 10.1063/1.4914179
10 Comments
Can’t you just kinda put a magnifying glass over the tandem panel and increase output substantially?
Like when I was a kid, and exponentially magnify the intensity of light?
And if not, make it crystalline, just like the eyes of a simple ant.
Oh yeah add a low voltage rotary sensor so the roof panels rotate and thus capture more of the energy of the sun during peak production hours.
That’s it, I now claim all rights and absolute ownership of the sun!
I’ll elaborate – in simple terms, as the advancement of technology simply amazes me, and I laud all those making advancements.
You know that bubble wrap (plastic from oil) that comes in packaging?
That’s what it should look like …
And energy recovery should approach 50%.
Try it – you’ll like it. At least Mikey does.
So many solutions provided by simple mother nature.
You have my e-mail (please keep it private).
If you try this experiment, and if successful,
Please let me know via the address I’ve provided.
Thanks.
Convex (or concave) over-panels.
Additional ancillary benefits –
Shingled roofs last a lot longer.
Day-by-day – benefits exponential.
I thank God for people like you (researchers);
Despite the profit motive, for the good of all.
P.S.
I’ll read the article above shortly.
The dark panels should be the underlayment.
For the same reason Arabs wear whit in the desert,
Black attracts more sunlight – just like pavement does.
Add that caveat – experiment – just make sure to let me know.
Who could ever have imagined in my lifetime,
from rotary phones – to calculators – to the IBM XT?
To the Apple I-pod, I-pad, to GPS, to EV’s, to Green.
It’s simply astounding. I wrote programs on lotus 123/DB3.
.
I guess that’s why as a child I loved Star Trek so much (the original).
.
“For everything the human mind can imagine – eventually comes to pass.”
One small disagreement (having read the article).
The two layers should not match output … ever.
Though I do agree with the thought of one circuit;
I do also believe (theoretically) one (both) should outdo the other,
and in so doing compliment each other to enhance overall performance.
If you do not currently realize what you have created,
I shall tell you.
You know those black silicon (plastic) panels in black?
Most vehicles are made (substantially) out of silicone.
Plastic used to reduce vehicle weight and so increase mileage.
The what if.
What if …
You used this material (that which you’ve created) as the outside skin to an EV vehicle with batteries?
The implications are profound.
I’m getting ahead of myself,
but using fractionated light out of the spectrum,
that which the human eye (at least) cannot see …
It could also be offered in a multitude of colors.
One final thought (or perhaps an experiment).
I was watching once on tv (about ten years ago) about this up-scale watering hole in Manhattan with a unisex bathroom. The windows (a make-shift wall) were clear as glass.
With one touch of the finger, the glass turned opaque white, and nothing could be visibly seen beyond.
Quite a feat of technology, wouldn’t you say?