WESTERN CORN ROOTWORM INFESTATION AND SOYBEAN NODULATION DETECTION AT EARLY STAGES WITH MISIROOT.pdf

Tianzhang Zhao (15379703)

04 May 2023

<p>Root phenotyping technology is an essential component of modern agriculture and plant science research. Conducting root-related research in a non-destructive manner is crucial for studying plant roots without damaging the plants themselves and allowing for time-series studies. The research aims to validate the efficacy of MISIRoot, an innovative root phenotyping technology, through the implementation of two projects. The first project focuses on the early detection of western corn rootworm, one of the most devastating corn rootworm species in North America, particularly in midwestern corn-growing areas. The second project focuses on the assessment of the soybean nodulation process, which is crucial for nitrogen fixation by Rhizobia living in the nodules on the soybean roots. The current state-of-the-art methods for western corn rootworm and soybean nodulation assessments still require the whole plant to be dug up, which causes irreversible destruction to the plant itself. Although recently developed root phenotyping methods such as minirhizotron, CT, and MRI scanners offer unique advantages in observing plant roots, their potential for field applications is currently limited.</p> <p>Data collection for both projects was carried out using MISIRoot, a minimally invasive plant root phenotyping robot that works in situ within natural soil. The MISIRoot system mainly consists of an industrial-level robotic arm, a mini-size camera with a lighting set, a plant pot holding platform, and image processing software for root recognition and feature extraction. MISIRoot can take high-resolution color images of the roots in soil with minimal disturbance to the root and reconstruct the plant roots' three-dimensional (3D) structure at an accuracy of 0.1 mm.</p> <p>For the first project, the MISIRoot system successfully distinguished the corn plants inoculated with western corn rootworm larvae from the healthy plants before the shoot section of the corn plants revealed significant differences. For the second project, the MISIRoot system successfully demonstrated its ability to differentiate soybean plants with and without nodules.</p>

Agricultural engineering

MISIRoot

Western corn rootworm (WCR)

soybean nodulation

Agricultural Engineering

minimally invasive root measurement

Soybean Yield and Biomass Response to Supplemental Nitrogen Fertilization

McCoy, Justin Michael

12 August 2016

Soybean (Glycine max [L.] Merr.) has become one of the main agricultural grain crops produced in the United States. Soybean production continues to increase in high-yield environments throughout the U.S. New innovations are required to sustain gains in soybean yield potential. Field experiments were conducted at the Delta Research and Extension Center in Stoneville, MS in 2014 and 2015 to evaluate soybean aboveground biomass and grain yield response to supplemental N fertilization in a high-yielding environment on two soil textures commonly cropped to soybean in Mississippi. Greenhouse studies were conducted in 2016 at the Delta Research and Extension Center in Stoneville, MS to evaluate the influence of supplemental N fertilization on nodule formation and belowground biomass of soybean on two soil textures commonly cropped to soybean in Mississippi.

soybean

soybean fertilization

soybean nitrogen

soybean root growth

nitrogen nodule inhibition

soybean nodulation

polymer coated urea

late season nitrogen fertilizer