Berkeley Lab Awarded $4.6 Million for Transformational Agriculture Technologies

Two projects will provide a window to the underground, yielding information on roots and soil

Agriculture Technologies
Two Berkeley Lab projects to “see” into the soil. (Credit: KateLeigh/istock.com)

As advanced as agriculture has become, there remains a pressing need for nondestructive ways to ”see” into the soil. Now the U.S. Department of Energy’s Advanced Research Projects Agency-Energy (ARPA-E) has awarded $4.6 million to Lawrence Berkeley National Laboratory (Berkeley Lab) for two innovative projects to address this gap, giving farmers important information to increase crop yields while also promoting the storage of carbon in soil.

One project aims to use electrical current to image the root system, which will accelerate the breeding of crops with roots that are tailored to specific conditions (such as drought). The other project will develop a new imaging technique based on neutron scattering to measure the distribution of carbon and other elements in the soil.

“Both technologies could be transformational for agriculture⎯for quantifying belowground plant traits and where carbon and other elements are distributed⎯and will enable the next generation of predictive models for agriculture and climate,” said Eoin Brodie, deputy director of Berkeley Lab’s Climate & Ecosystem Sciences Division and a microbiologist who is contributing to both projects. “They’re windows into the soil, something that we urgently need.”

Berkeley Lab received these competitive awards from ARPA-E’s Rhizosphere Observations Optimizing Terrestrial Sequestration (ROOTS) program, which seeks to develop crops that take carbon out of the atmosphere and store it in soil—enabling a 50 percent increase in carbon deposition depth and accumulation while also reducing nitrous oxide emissions by 50 percent and increasing water productivity by 25 percent.

Soil carbon deficits are a global phenomenon resulting from many decades of industrial agriculture. Soils have the capacity to store significant quantities of carbon, reducing atmospheric carbon dioxide concentrations while also enhancing soil fertility and water retention.

An EEG for plants

Development of the Tomographic Electrical Rhizosphere Imaging (TERI) technology, which was awarded $2.3 million by ARPA-E, is led by Berkeley Lab geophysicist Yuxin Wu, also in the Climate & Ecosystem Sciences Division. “You can think of it like brain imaging, or EEG, where electrodes attached to your head can record brain wave patterns,” Wu said. “The new technology will be like an EEG for plants.”

By sending a small electrical current into the stem, which will then travel throughout the root system, TERI will sense the electrical response of both roots and soil and provide information on root mass, surface area, depth, and distribution in the soil, together with data on soil texture and moisture content and how these variables change over time.

In contrast, the common approach to studying root properties, which goes by the moniker “shovelomics,” involves not much more than a shovel and a bucket of water before root analysis in the lab. “It’s a very labor intensive and low-throughput method to characterize roots,” Wu said. “And once you dig up the root, you’re done. You can’t look at changes over time.”

Wu has begun initial testing in the lab. Later he will do field testing with wheat crops in collaboration with The Samuel Roberts Noble Foundation. Based in Ardmore, Oklahoma, the Noble Foundation is the largest independent agricultural research institute in the U.S. with more than 13,500 acres of farmland carrying out research to enable farmers and ranchers to increase regional productivity and land stewardship.

“They have exceptional facilities and are experts in agronomics, plant breeding, and genomics, among other things,” Wu said. “One of our key strengths is in the characterization and imaging of the soil-plant system. So it’s a great match.”

Wu and his team are also partnering with Subsurface Insights, a small business focusing on software development for geophysical applications.

The project’s goal is to develop next-generation root phenotyping technology integrated with ecosystem modeling to accelerate the breeding of root-focused cultivars with certain traits; for example, better climate resiliency and better tolerance for low water and low fertilizer conditions. Ultimately, the tool could help increase yields while increasing carbon input to the soil.

“This technology can have a significant impact on multiple fronts, not just agriculture. For example, it has significant potential for forestry and for understanding belowground plant traits in unmanaged ecosystems that store significant quantities of carbon,” said Susan Hubbard, Associate Laboratory Director for Earth & Environmental Sciences.

From neutrons to gamma rays to carbon detection

In the second project, also awarded $2.3 million, Berkeley Lab physicists led by Arun Persaud of the Accelerator Technology & Applied Physics (ATAP) Division will build an instrument to analyze soil chemistry, without disturbing it, by means of inelastic neutron scattering. “The generator will send neutrons into the soil,” Persaud said. “Each neutron can react with atoms in the soil and generate a gamma ray, which we can detect aboveground with a gamma detector. Then we measure the energy of the gamma, and from that you can tell what kind of atom it is; carbon or iron or aluminum, for example.”

Similar technology is currently used in homeland security applications, such as detecting explosives and other materials in cargo, and is a longtime area of research at Berkeley Lab.

“This technology will be able to not only measure how much carbon is in the soil but also do so with spatial resolution of a few centimeters,” said Wim Leemans, ATAP Director. “This is an outstanding example of R&D leverage to address challenges with very significant societal impact.”

Persaud said that unlike current technologies for analyzing soil properties, this technique can be employed in the field and can measure changes over space and time without disturbing the soil. Standard methods now involve drilling soil cores and doing chemical analyses on them back in the lab, which does not allow for repeat measurements of the same soil and is not practical over large areas.

Together with ATAP physicist Bernhard Ludewigt, Persaud will work with Adelphi Technology Inc. to develop the neutron generator. The resulting system could eventually take the form of a mobile instrument that takes in situ measurements in a farmer’s field.

“Aligned with several of Berkeley Lab’s projects as well as the Lab’s Microbes-to-Biomesinitiative, these are two key projects in what we hope will eventually be an entire nimble and networked ecosystem sensing system (called EcoSENSE), which can guide agricultural or forestry system management and quantify the impacts of land use, extreme weather, and climate on carbon storage and ecosystem function,” Brodie said.

Added James Symons, Associate Laboratory Director for Physical Sciences: “This is a project with potentially transformational impact that is really enabled by having cross-disciplinary scientific expertise⎯in soil biology, soil physics, soil chemistry, geophysics, nuclear physics⎯all in one location at Berkeley Lab.”