IMPACT OF VIBRATION ON TILLAGE PERFORMANCE OF SUBSOILERS USING THE DISCRETE ELEMENT METHOD (DEM)

Plow pan is one of the main obstacles to high production of agricultural plants in Chongqing, China. As a minimal tilling method, subsoiling can break the plow pan and help the growth of agricultural plants. There are two subsoiling methods: vibrating subsoiling (VS) and traditional subsoiling (TS). A soil model with upland field features in Chongqing was established for DEM-based simulation. The simulation was validated by field experiments, in items of soil looseness, coefficient of soil disturbance, and cross-section of tillage, the errors of the simulated and experimental values of the soil looseness and soil disturbance coefficient of TS and VS were 12.9% and 14.7%, respectively. Compared with TS, VS resulted in lower soil looseness, higher coefficient of soil disturbance, smaller width of upper furrow, and lighter damage of tillage layer, and no obvious overturn of soil blocks was observed for the VS. Compared with TS, vibration helps improve the tillage performance of subsoilers.

Exploring Suitable Biochar Application Rates with Compost to Improve Upland Field Environment

A field experiment was carried out to investigate crop productivity, emissions of carbon dioxide (CO2) and nitrous oxide (N2O), and soil quality of an upland field treated with compost and varying rates of biochar (BC) derived from soybean stalks during crop growing periods in a corn and Chinese cabbage rotation system. Compost was supplemented with BC derived from soybean stalks at varying rates of 5, 10, 15, and 20 t ha−1 (BC5, BC10, BC15, and BC20, respectively); the control (BC0) area was untreated. Our results reveal that crop productivity and emissions of CO2 and N2O varied significantly with the biochar application rate. Moreover, irrespective of the biochar application rate, crop productivity was improved after BC application as compared to the control treatment area, by 11.2–29.3% (average 17.0 ± 8.3%) for corn cultivation and 10.3–39.7% (average 27.8 ± 12.7%) for Chinese cabbage cultivation. Peak emissions of CO2 and N2O were mainly observed in the early period of crop cultivation, whereas low CO2 and N2O emissions were determined during the fallow period. Compared to the control area, significant differences were obtained for CO2 emissions produced by the different biochar application rates for both crops. During the two cropping periods, the overall N2O emission was significantly decreased with BC5, BC10, BC15, and BC20 applications as compared to the control, ranging from 11.1 to 13.6%, 8.7 to 15.4%, 23.1 to 26.0%, and 15.0 to 19.6%, respectively (average 16.9% decrease in the corn crop period and 16.3% in the Chinese cabbage crop period). Soil quality results after the final crop harvest show that bulk density, soil organic carbon (SOC), pH, and cation exchange capacity (CEC) were significantly improved by biochar application, as compared to the control. Taken together, our results indicate that compost application supplemented with biochar is potentially an appropriate strategy for achieving high crop productivity and improving soil quality in upland field conditions. In conclusion, appropriate application of biochar with compost has the concomitant advantages of enriching soil quality for long-term sustainable agriculture and reducing the use of inorganic fertilizers.

Mutation of IDR1 enhances drought tolerance by reducing ROS production and activating ROS scavenging in rice

To discover new mutant alleles conferring enhanced tolerance to drought stress, we screened a mutagenized rice population (cv. IAPAR9) and identified a mutant, named idr1-1 (for increased drought resistance 1-1), with obviously increased drought tolerance under upland field conditions. The idr1-1 mutant possessed a significantly enhanced ability to tolerate high-drought stress in different trials. Map-based cloning revealed that the gene LOC_Os05g26890 (corresponding to D1 or RGA1 gene), residing in the mapping region of IDR1 locus, carried a single-base deletion in the idr1-1 mutant, which caused a frameshift and premature translation termination. Complementation tests indicated that such a mutation was indeed responsible for the elevated drought tolerance in idr1-1 mutant. IDR1 protein was localized in nucleus and to plasma membrane or cell periphery. Further investigations indicated that the significantly increased drought tolerance in idr1-1 mutant stemmed from a range of physiological and morphological changes occurring in such a mutant, including greater leaf potentials, increased proline contents, heightened leaf thickness, and upregulation of antioxidant-synthesizing and drought-induced genes, etc., under drought-stressed conditions. Especially, ROS production from NADPH oxidases and chloroplasts might be remarkably impaired, while ROS-scavenging ability appeared to be markedly enhanced as a result of significantly elevated expression of a dozen ROS-scavenging enzyme genes in idr1-1 mutant under drought-stressed conditions. Besides, IDR1 physically interacted with TUD1, and idr1-1 mutant showed impaired EBR responsiveness. Altogether, these results suggest that mutation of IDR1 leads to alterations of multiple layers of regulations, which ultimately confers obviously enhanced drought tolerance to the idr1-1 mutant.One-sentence summaryMutation of IDR1 significantly enhances drought tolerance in an upland cultivar IAPAR9 by decreasing apoplastic and chloroplastic ROS production and increasing ROS-scavenging ability