Salinity reduces radiation absorption and use efficiency in soybean

The potential rate of plant development and biomass accumulation under conditions free of environmental stress depends on the amount of radiation absorption and the efficiency of utilizing the absorbed solar energy to drive photosynthetic processes that produce biomass materials. Salinity, as a form of soil and water stress, generally has a detrimental effect on plant growth, and crops such as soybean are usually sensitive to salinity. Field and greenhouse experiments were conducted to determine soybean growth characteristics and the relative impact of salinity on radiation absorption and radiation-use efficiency (RUE) at a whole plant level. Cumulative absorption of photosynthetically active radiation ([summation operator]APAR) was estimated using hourly inputs of predicted canopy extinction coefficients and measured leaf area indices (LAI) and global solar radiation. On 110 days after planting, soybean plants grown under non-saline conditions in the field accumulated 583 MJ [summation operator]APAR m-2. A 20% reduction in [summation operator]APAR resulted from growing the plants in soil with a solution electrical conductivity (EC) of about 10 dS m-1. Soybeans grown under non-saline conditions in the field achieved a RUE of 1.89 g MJ-1 [summation operator]APAR for above-ground biomass dry materials. The RUE reached only 1.08 g MJ-1 [summation operator]APAR in the saline soil, about a 40% reduction from the non-saline control. Salinity also significantly reduced [summation operator]APAR and RUE for soybeans in the greenhouse. The observed smaller plant and leaf sizes and darker green leaves under salinity stress were attributed to reductions in LAI and increases in unit leaf chlorophyll, respectively. Reductions in LAI exceeded small gains in leaf chlorophyll, which resulted in less total canopy chlorophyll per unit ground area. Analyzing salinity effect on plant growth and biomass production using the relative importance of [summation operator]APAR and RUE is potentially useful because APAR and total canopy chlorophyll can be estimated with remote sensing techniques.