Rootkit

[Image: Work by Diana Scherer, used to promote an event coming up on December 14th, in Wageningen, Holland, where the artist will be speaking].

The work of German-born artist Diana Scherer explores what she calls “the dynamics of belowground plant parts.” She uses plant roots themselves as a medium for creating patterns and networks, the purpose of which is to suggest overlaps between human technological activity and the embodied “intelligence” of living botanical matter. “This buried matter is still a wondrous land,” she writes.

The results are incredible. They feature roots woven like carpets or textiles, imitating Gothic ornament with floral patterns and computational arabesques underground.

[Image: “Ornament with Thistle” by Daniel Hopfer; via Wikimedia].

Compare Scherer’s work, for example, to traditional Gothic plant ornament—that is, geometric shapes meant to imitate the movements and behaviors of plants—but here actually achieved with plants themselves.

Scherer calls this “root system domestication,” where, on the flipside of an otherwise perfectly “natural” landscape, such as an expanse of lawn grass, wonderfully artificial, technical patterns can be achieved.

[Images: All images by Diana Scherer, from “Harvest: Exercises in Rootsystem Domestication”].

The idea that we could grow biological circuits and living rootkits is incredible, as if, someday, electronic design and gardening will—wonderfully and surreally—converge.

You simply step into your backyard, exhume some root matter as if harvesting potatoes, and whole new circuits and electrical networks are yours to install elsewhere.

[Image: From “Harvest: Exercises in Rootsystem Domestication” by Diana Scherer].

After all, the soil is already alive with electricity, and plants are, in effect, computer networks in waiting.

Scherer’s work simply takes those observations to their next logical step, you might argue, using plants themselves as an intelligent form-finding technology with implications for the organic hardware of tomorrow.

For more images, click through to Diana Scherer’s website, and, for those of you near Wageningen, consider stopping by the artist’s live Q&A on December 14th. Someone please commission a landscape-scale work from Scherer soon!

Electronic Plantlife

[Image: A rose-circuit, courtesy Linköping University].

In a newly published paper called “Electronic plants,” researchers from Linköping University in Sweden describe the process by which they were able to “manufacture” what they call “analog and digital organic electronic circuits and devices” inside living plants.

The plants not only conducted electrical signals, but, as Science News points, the team also “induced roses leaves to light up and change color.”

Indeed, in their way of thinking, plants have been electronic gadgets all along: “The roots, stems, leaves, and vascular circuitry of higher plants are responsible for conveying the chemical signals that regulate growth and functions. From a certain perspective, these features are analogous to the contacts, interconnections, devices, and wires of discrete and integrated electronic circuits.”

[Image: Bioluminescent foxfire mushrooms (used purely for illustrative effect), via Wikipedia].

Here’s the process in a nutshell:

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.

Headily enough, using plantlife as a logic gate also implies a future computational use of vegetation: living supercomputers producing their own circuits inside dual-use stems.

Previously, we have looked at the use of electricity to stimulate plants into producing certain chemicals, how the action of plant roots growing through soil could be tapped as a future source of power, and how soil bacteria could be wired up into huge, living battery fields—in fact, we also looked at a tongue-in-cheek design project for “growing electrical circuitry inside the trunks of living trees“—but this actually turns vegetation into a form of living circuitry.

While Archigram’s “Logplug” project is an obvious reference point here within the world of architectural design, it seems more interesting to consider instead the future landscape design implications of technological advances such as this—how “electronic plants” might affect everything from forestry to home gardening, energy production and distribution infrastructure to a city’s lighting grid.

[Image: The “Logplug” by Archigram, from Archigram].

We looked at this latter possibility several few years ago, in fact, in a post from 2009 called “The Bioluminescent Metropolis,” where the first comment now seems both prescient and somewhat sad given later developments.

But the possibilities here go beyond mere bioluminescence, into someday fully functioning electronic vegetation.

Plants could be used as interactive displays—recall the roses “induced… to light up and change color”—as well as given larger conductive roles in a region’s electrical grid. Imagine storing excess electricity from a solar power plant inside shining rose gardens, or the ability to bypass fallen power lines after a thunderstorm by re-routing a town’s electrical supply through the landscape itself, living corridors wired from within by self-assembling circuits and transistors.

And, of course, that’s all in addition to the possibility of cultivating plants specifically for their use as manufacturing systems for organic electronics—for example, cracking them open not to reveal nuts, seeds, or other consumable protein, but the flexible circuits of living computer networks. BioRAM.

There are obvious reasons to hesitate before realizing such a vision—that is, before charging headlong into a future world where forests are treated merely as back-up lighting plans for overcrowded cities and plants of every kind are seen as nothing but wildlife-disrupting sources of light cultivated for the throwaway value of human aesthetic pleasure.

Nonetheless, thinking through the design possibilities in addition to the ethical risks not only now seems very necessary, but might also lead someplace truly extraordinary—or someplace otherworldly, we might say with no need for justification.

For now, check out the original research paper over at Science Advances.