Info
Info
News Article

Piranha Etching Boosts InP Solar Cell Efficiency

A novel etching method can make the surface of indium phosphide nanowires much smoother, and with fewer imperfections
Energy losses in nanowire solar cells can be significantly reduced by ‘cleaning’ the surface of the cells with a special etching method.

This has been shown by researchers at Eindhoven University of Technology (TU/e), Delft University of Technology and Philips in a paper published in the journal Nano Letters.

The solar cell has an efficiency of 11.1 percent, which the research say put it just below the current world record, but it was reached with much less use of material. This is the latest step forward in the rapid development of this type of solar cell in recent years.



A nanowire array in the solar cell. (Photo: Eindhoven University of Technology)

The nanowire solar cell is a relatively new type of cell in which a bundle of semiconducting wires, each with a thickness of around 100nm, collect light and convert it into electricity. Big advances have been made in the development of this type of solar cell in recent years, and the efficiencies achieved are increasing rapidly by around 5 percent per year - much stronger growth than that of competing solar cell technologies.

Relatively large surface area

A big advantage of thin nanowires is the greatly reduced need for costly semiconductor material, which means they can be produced at low cost. However a disadvantage is their large surface area relative to the volume - and the surface is exactly where imperfections in the material lead to high energy losses.

In the publication in Nano Letters the researchers, led by Erik Bakkers and Jos Haverkort, describe a method to make the surface of InP nanowires much smoother, with fewer imperfections. They do this using an etching method that they have developed themselves - called ‘piranha etching’ - in which the surface is ‘cleaned’ by a chemical reaction.

Efficiency boost

Their solar cell reaches an efficiency of 11.1 percent - slightly less than the current world record of 13.8 percent which was achieved earlier this year by a group of Swedish, German and Chinese researchers using nanowires made of the same material.

However the nanowires of the Dutch researchers are only 40 percent as thick. Since the efficiency normally falls as the wires become thinner, the expected efficiency should be only around 4.5 percent. Which means the ‘cleaning job’ in fact gives a significant boost in efficiency.

The researchers see opportunities to raise efficiency further in the near future with little extra use of resources. “By varying the thickness of the nanowires and improving the way the crystals inside them are stacked, we think we should soon be able to approach an efficiency of 20 percent", says Bakkers. In the longer term, it should in theory even be possible to reach efficiencies of 65 percent by stacking multiple subcells.

This work is described in further detail in the paper, "Efficiency Enhancement of InP Nanowire Solar Cells by Surface Cleaning," by Yingchao Cui et al in Nano Letters (2013). http://pubs.acs.org/doi/abs/10.1021/nl4016182 





AngelTech Live III: Join us on 12 April 2021!

AngelTech Live III will be broadcast on 12 April 2021, 10am BST, rebroadcast on 14 April (10am CTT) and 16 April (10am PST) and will feature online versions of the market-leading physical events: CS International and PIC International PLUS a brand new Silicon Semiconductor International Track!

Thanks to the great diversity of the semiconductor industry, we are always chasing new markets and developing a range of exciting technologies.

2021 is no different. Over the last few months interest in deep-UV LEDs has rocketed, due to its capability to disinfect and sanitise areas and combat Covid-19. We shall consider a roadmap for this device, along with technologies for boosting its output.

We shall also look at microLEDs, a display with many wonderful attributes, identifying processes for handling the mass transfer of tiny emitters that hold the key to commercialisation of this technology.

We shall also discuss electrification of transportation, underpinned by wide bandgap power electronics and supported by blue lasers that are ideal for processing copper.

Additional areas we will cover include the development of GaN ICs, to improve the reach of power electronics; the great strides that have been made with gallium oxide; and a look at new materials, such as cubic GaN and AlScN.

Having attracted 1500 delegates over the last 2 online summits, the 3rd event promises to be even bigger and better – with 3 interactive sessions over 1 day and will once again prove to be a key event across the semiconductor and photonic integrated circuits calendar.

So make sure you sign up today and discover the latest cutting edge developments across the compound semiconductor and integrated photonics value chain.

REGISTER FOR FREE

VIEW SESSIONS

Info
×
Search the news archive

To close this popup you can press escape or click the close icon.
×
Logo
×
Register - Step 1

You may choose to subscribe to the Compound Semiconductor Magazine, the Compound Semiconductor Newsletter, or both. You may also request additional information if required, before submitting your application.


Please subscribe me to:

 

You chose the industry type of "Other"

Please enter the industry that you work in:
Please enter the industry that you work in:
 
X
Info
X
Info
{taasPodcastNotification}
Live Event