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Scientists at the Research Institute for Electronic Science at Hokkaido University have created what they call a "golden sandwich," a photoelectrode that captures 85% of sunlight and uses it to split water and thus crate hydrogen. Yes, this is experimental stuff, and no, it has not yet reached commercial production. But stop and think for a minute what that could mean to the renewable energy revolution.

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“Golden Sandwich” Photoelectrode Harvests 85% Of Sunlight

Scientists at the Research Institute for Electronic Science at Hokkaido University have created what they call a “golden sandwich,” a photoelectrode that captures 85% of sunlight and uses it to split water and thus crate hydrogen. Yes, this is experimental stuff, and no, it has not yet reached commercial production. But stop and think for a minute what that could mean to the renewable energy revolution.

Scientists at the Research Institute for Electronic Science at Hokkaido University have created what they call a “golden sandwich,” a photoelectrode that captures 85% of sunlight and uses it to split water and thus crate hydrogen. Yes, this is experimental stuff, and no, it has not yet reached commercial production. But stop and think for a minute what that could mean to the renewable energy revolution.

The breakthrough from Hokkaido University hints at renewable energy production that is 11 times more efficient than current systems. Of course, we have no idea what commercial versions of the technology might cost (if 11 times more than current systems, it’s a net-zero benefit), but just imagine getting 11 times as much zero-emissions energy from a photoelectrode. The implications are staggering.

So what’s the secret sauce for making a golden sandwich? A titanium dioxide film just 30 nanometers thick with a 100 nanometer thick gold film on one side and gold nano-particles on the other. When sunlight strikes the nanoparticle side, the gold film below acts as a mirror trapping the light in the cavity between the two gold layers. That helps the nano-particles to absorb more of the available light, which is critical to the surprisingly high energy conversion factor.

In a paper reporting on their discovery published by Nature Nanotechnology (pay wall), the researchers say that gold nano-particles exhibit a phenomenon known as localized plasmon resonance, which absorbs certain wavelengths of light. “Our photoelectrode successfully created a new condition in which plasmon and visible light trapped in the titanium oxide layer strongly interact, allowing light with a broad range of wavelengths to be absorbed by gold nanoparticles,” says Hiroaki Misawa, lead author of the study report. “The light energy conversion efficiency is 11 times higher than those without light-trapping functions.”

Hydrogen may become an important component in the clean energy economy of the future, but most of the commercially available hydrogen today is derived from reformed natural gas, which itself is a product of fracking. Hydrogen is a non-starter for clean energy so long as it depends on the extraction of natural gas by unnatural means.

The researchers conclude their report by saying, “Using very small amounts of material, this photoelectrode enables an efficient conversion of sunlight into renewable energy, further contributing to the realization of a sustainable society.” That can’t happen soon enough for a planet that is under increasing stress from carbon emissions.

This article has been updated to clarify the type of energy conversion system seemingly described by the researchers.

 
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Steve writes about the interface between technology and sustainability from his homes in Florida and Connecticut or anywhere else the Singularity may lead him. You can follow him on Twitter but not on any social media platforms run by evil overlords like Facebook.

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