Electronic plants created

Augmenting plants with electronic functionality would make it possible to combine electric signals with the plant's own chemical processes.

Credit: Laboratory of Organic Electronics

Researchers at Linköping University in Sweden have created analog and digital electronics circuits inside living plants. The group at the Laboratory of Organic Electronics (LOE), under the leadership of Professor Magnus Berggren, have used the vascular system of living roses to build key components of electronic circuits.

The article featured in the journal Science Advances demonstrates wires, digital logic, and even displays elements -- fabricated inside the plants -- that could develop new applications for organic electronics and new tools in plant science.

Plants are complex organisms that rely on the transport of ionic signals and hormones to perform necessary functions. However, plants operate on a much slower time scale making interacting with and studying plants difficult. Augmenting plants with electronic functionality would make it possible to combine electric signals with the plant's own chemical processes. Controlling and interfacing with chemical pathways in plants could pave the way to photosynthesis-based fuel cells, sensors and growth regulators, and devices that modulate the internal functions of plants.

"Previously, we had no good tools for measuring the concentration of various molecules in living plants. Now we'll be able to influence the concentration of the various substances in the plant that regulate growth and development. Here, I see great possibilities for learning more," says Ove Nilsson, professor of plant reproduction biology and director of the Umeå Plant Science Center, as well as a co-author of the article.

The idea of putting electronics directly into trees for the paper industry originated in the 1990s while the LOE team at Linköping University was researching printed electronics on paper. Early efforts to introduce electronics in plants were attempted by Assistant Professor Daniel Simon, leader of the LOE's bioelectronics team, and Professor Xavier Crispin, leader of the LOE's solid-state device team, but a lack of funding from skeptical investors halted these projects.

Thanks to independent research money from the Knut and Alice Wallenberg Foundation in 2012, Professor Berggren was able to assemble a team of researchers to reboot the project. The team tried many attempts of introducing conductive polymers through rose stems. Only one polymer, called PEDOT-S, synthesized by Dr. Roger Gabrielsson, successfully assembled itself inside the xylem channels as conducting wires, while still allowing the transport of water and nutrients. Dr. Eleni Stavrinidou used the material to create long (10 cm) wires in the xylem channels of the rose. By combining the wires with the electrolyte that surrounds these channels she was able to create an electrochemical transistor, a transistor that converts ionic signals to electronic output. Using the xylem transistors she also demonstrated digital logic gate function.

Dr. Eliot Gomez used methods common in plant biology -- vacuum infiltration -- to infuse another PEDOT variant into the leaves. The infused polymer formed "pixels" of electrochemical cells partitioned by the veins. Applied voltage caused the polymer to interact with the ions in the leaf, subsequently changing the color of the PEDOT in a display-like device -- functioning similarly to the roll-printed displays manufactured at Acreo Swedish ICT in Norrköping.

These results are early steps to merge the diverse fields of organic electronics and plant science. The aim is to develop applications for energy, environmental sustainability, and new ways of interacting with plants. Professor Berggren envisions the potential for an entirely new field of research:

"As far as we know, there are no previously published research results regarding electronics produced in plants. No one's done this before," he says.

Professor Berggren adds, "Now we can really start talking about 'power plants' -- we can place sensors in plants and use the energy formed in the chlorophyll, produce green antennas, or produce new materials. Everything occurs naturally, and we use the plants' own very advanced, unique systems."

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The above post is reprinted from materials provided by Linköping University. Note: Materials may be edited for content and length.

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More proof of Einstein's general theory of relativity

Chandra image of the black hole at the center of spiral galaxy M81.

Credit: X-ray: NASA/CXC/Wisconsin/D.Pooley & CfA/A.Zezas; Optical: NASA/ESA/CfA/A.Zezas; UV: NASA/JPL-Caltech/CfA/J.Huchra et al.; IR: NASA/JPL-Caltech/CfA

A Florida State University high-performance computing researcher has predicted a physical effect that would help physicists and astronomers provide fresh evidence of the correctness of Einstein's general theory of relativity.

Bin Chen, who works at the university's Research Computing Center, describes the yet-to-be-observed effect in the paper "Probing the Gravitational Faraday Rotation Using Quasar X-ray Microlensing," published today in the journal Scientific Reports.

"To be able to test general relativity is of crucial importance to physicists and astronomers," Chen said.

This testing is especially so in regions close to a black hole, according to Chen, because the current evidence for Einstein's general relativity -- light bending by the sun, for example -- mainly comes from regions where the gravitational field is very weak, or regions far away from a black hole.

Electromagnetism demonstrates that light is composed of oscillating electric and magnetic fields. Linearly polarized light is an electromagnetic wave whose electric and magnetic fields oscillate along fixed directions when the light travels through space.

The gravitational Faraday effect, first predicted in the 1950s, theorizes that when linearly polarized light travels close to a spinning black hole, the orientation of its polarization rotates according to Einstein's theory of general relativity. Currently, there is no practical way to detect gravitational Faraday rotation.

In the paper, Chen predicts a new effect that can be used to detect the gravitational Faraday effect. His proposed observation requires monitoring the X-ray emissions from gravitationally lensed quasars.

"This means that light from a cosmologically distant quasar will be deflected, or gravitationally lensed, by the intervening galaxy along the line of sight before arriving at an observer on the Earth," said Chen of the phenomenon of gravitational lensing, which was predicted by Einstein in 1936. More than 100 gravitational lenses have been discovered so far.

"Astronomers have recently found strong evidence showing that quasar X-ray emissions originate from regions very close to supermassive black holes, which are believed to reside at the center of many galaxies," Chen said. "Gravitational Faraday rotation should leave its fingerprints on such compact regions close to a black hole.

"Specifically, the observed X-ray polarization of a gravitationally microlensed quasar should vary rapidly with time if the gravitational Faraday effect indeed exists," he said. "Therefore, monitoring the X-ray polarization of a gravitationally lensed quasar over time could verify the time dependence and the existence of the gravitational Faraday effect."

If detected, Chen's effect -- a derivative of the gravitational Faraday effect -- would provide strong evidence of the correctness of Einstein's general relativity theory in the "strong-field regime," or an environment in close proximity to a black hole.

Chen generated a simulation for the paper on the FSU Research Computing Center's High-Performance Computing cluster -- the second-largest computer cluster in Florida.

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The above post is reprinted from materials provided by Florida State University. Note: Materials may be edited for content and length.

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