The use of sunlight as an energy source is achieved in a number of ways, from conversion to electricity via photovoltaic (PV) panels, concentrated heat to drive steam turbines, and even hydrogen generation via artificial photosynthesis. Unfortunately, much of the light energy in PV and photosynthesis systems is lost as heat due to the thermodynamic inefficiencies inherent in the process of converting the incoming energy from one form to another. Now scientists working at the University of Bayreuth claim to have created a super-efficient light-energy transport conduit that exhibits almost zero loss, and shows promise as the missing link in the sunlight to energy conversion process.
Using specifically-generated nanofibers at its core, this is reported to be the very first time a directed energy transport system has been exhibited that effectively moves intact light energy over a distance of several micrometers, and at room temperature. And, according to the researchers, the transference of energy from block to block in the nanofibers is only adequately explained at the quantum level with coherence effects driving the energy along the individual fibers.
Quantum coherence is the phenomenon where subatomic waves are closely interlinked via shared electromagnetic fields. As they travel in phase together, these quantum coherent waves start to act as one very large synchronous wave propagating across a medium. In the case of the University of Bayreuth device, these coherent waves of energy travel across the molecular building blocks from which the nanofibers are made, passing from block to block and moving as one continuous energy wave would in unbound free space.
It is this effect that the scientists say is driving the super-low energy loss capabilities of their device, and have confirmed this observation using a variety of microscopy techniques to visualize the conveyance of excitation energy along the nanofibers. The nanofibers themselves are specifically-prepared supramolecular strands, manufactured from a chemically bespoke combination of carbonyl-bridged (molecularly connected) triarylamine (an organic compound) combined with three naphthalimide bithiophene chromophores (copolymer molecules that absorb and reflect specific wavelengths of light). When brought together under particular conditions, these elements spontaneously self-assemble into 4 micrometer long, 0.005 micrometer diameter nanofibers made up of more than 10,000 identical chemical building blocks.
"These highly promising nanostructures demonstrate that carefully tailoring materials for the efficient transport of light energy is an emerging research area," said Dr. Richard Hildner, an experimental physicist at the University of Bayreuth. The results of this research were recently published in the journal Nature.
The Netherlands made headlines last year when it built the world's first solar road - an energy-harvesting bike path paved with glass-coated solar panels. Now, six months into the trial, engineers say the system is working even better than...
Sarcoptic mange can leave southern hairy-nosed and bare-nosed wombats blind and deaf before eventually killing them Two of Australia’s three native wombat species are under threat from a disease which can leave the animal blind and deaf, and...
Newcastle, home to the world's biggest coal export port, has voted to curb its links to banks backing the fossil fuel industry in a move described by a dissenting councillor as taking the city "back to the Stone Age".
Scientists say warming waters and melting ice were to blame for levels rising faster than 50 years ago and ‘it’s very likely to get worse’ Sea levels worldwide have risen an average of nearly eight centimetres (three inches) since 1992 because of...
A warming atmosphere has already worsened California’s drought and harmed coastal ecosystems, but the worst is yet to come, according to the latest scientific research presented this week on the interactions of air pollution, water reserves and...
Harapan, who resides at the Cincinnati Zoo, will fly to south-east Asia where most of the estimated 100 remaining rhinos live An Ohio zoo that has the last Sumatran rhino in the US on Tuesday announced plans to send the endangered species to...
A big step closer to hydrogen as a practical fuel to power vehicles and electrical devices.
Researchers at Michigan Technological University have found a way to convert light to hydrogen fuel more efficiently — a big step closer to mimicking photosynthesis. Current methods for creating hydrogen fuel are based on using electrodes made from titanium dioxide (TiO2), which acts as a catalyst to stimulate the light–>water–>hydrogen chemical reaction. This works great with ultraviolet (UV) light, but UV comprises only about 4% of the total solar energy, making the overall process highly inefficient.*
The ideal would be to use visible light, since it constitutes about 45 percent of solar energy. Now two Michigan Tech scientists — Yun Hang Hu, the Charles and Carroll McArthur professor of Materials Science and Engineer, and his PhD student, Bing Han — have developed a way to do exactly that.
They report in Journal of Physical Chemistry that by absorbing the entire visible light spectrum, they have increased the yield and energy efficiency of creating hydrogen fuel by up to two magnitudes (100 times) greater than previously reported.
Bing Han and Yun Hang Hu. Highly Efficient Temperature-Induced Visible Light Photocatalytic Hydrogen Production from Water. J. Phys. Chem. C, 2015, 119 (33), pp 18927–18934; DOI: 10.1021/acs.jpcc.5b04894
Sharing your scoops to your social media accounts is a must to distribute your curated content. Not only will it drive traffic and leads through your content, but it will help show your expertise with your followers.
How to integrate my topics' content to my website?
Integrating your curated content to your website or blog will allow you to increase your website visitors’ engagement, boost SEO and acquire new visitors. By redirecting your social media traffic to your website, Scoop.it will also help you generate more qualified traffic and leads from your curation work.
Distributing your curated content through a newsletter is a great way to nurture and engage your email subscribers will developing your traffic and visibility.
Creating engaging newsletters with your curated content is really easy.