Your search keyword '"Liyin L. Liang"' showing total 2 results

1. Rapid laboratory measurement of the temperature dependence of soil respiration and application to changes in three diverse soils through the year

Author

Louis A. Schipper, J. Ryburn, Liyin L. Liang, Tanya Ann O'Neill, Jasmine M. Robinson, and Vickery L. Arcus

Subjects

010504 meteorology & atmospheric sciences, Moisture, Chemistry, Soil chemistry, Soil classification, Soil science, 04 agricultural and veterinary sciences, Soil type, 01 natural sciences, Soil respiration, Temperature gradient, Environmental chemistry, Soil water, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental Chemistry, Water content, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology

Abstract

Determining the temperature dependence of soil respiration is needed to test predictive models such as Arrhenius-like functions and macro-molecular rate theory (MMRT). We tested a method for rapid measurement of respiration using a temperature gradient block, cooled at one end (~2 °C) and heated at the other (~50 °C) that accommodated 44 tubes containing soil incubated at roughly 1 °C increments. Gas samples were taken after 5 h incubation and analysed for CO2. The temperature gradient block allowed rapid assessment of temperature dependence of soil respiration with the precision needed to test models and explore existing theories of how temperature and moisture interact to control biochemical processes. Temperature response curves were well fitted by MMRT and allowed calculation of the temperature at which absolute temperature sensitivity was maximal (Tinf). We measured temperature response of three soils at seven moisture contents and showed that the absolute rate and sensitivity of respiration was partly dependent on adjusted moisture content. This result implied that comparisons between soils need to be made at a common moisture content. We also measured potential changes in the temperature dependence (and sensitivity) of respiration for three different soils collected at one site throughout a year. Tinf ranged from 43 to 51 °C for the three soils. Tinf and temperature sensitivity were not dependent on soil type collected but was partly dependent on time of year of collection. Temporal changes in temperature response suggested that the microbial communities may tune their metabolisms in response to changes in soil temperatures.

Published

2017

2. Unusually high soil nitrogen oxide emissions influence air quality in a high-temperature agricultural region

Author

Cui Ge, David A. Grantz, Patricia Y. Oikawa, G. D. Jenerette, J. R. Eberwein, Liyin L. Liang, Jun Wang, and Lindy A. Allsman

Subjects

Hot Temperature, Nitrogen, Air pollution, General Physics and Astronomy, medicine.disease_cause, Atmospheric sciences, Article, California, General Biochemistry, Genetics and Molecular Biology, Soil, chemistry.chemical_compound, Air Pollution, medicine, Tropospheric ozone, Fertilizers, Water content, Air quality index, Sorghum, NOx, Pollutant, Air Pollutants, Multidisciplinary, General Chemistry, Agronomy, chemistry, Atmospheric chemistry, Soil water, Environmental science, Nitrogen Oxides

Abstract

Fertilized soils have large potential for production of soil nitrogen oxide (NOx=NO+NO2), however these emissions are difficult to predict in high-temperature environments. Understanding these emissions may improve air quality modelling as NOx contributes to formation of tropospheric ozone (O3), a powerful air pollutant. Here we identify the environmental and management factors that regulate soil NOx emissions in a high-temperature agricultural region of California. We also investigate whether soil NOx emissions are capable of influencing regional air quality. We report some of the highest soil NOx emissions ever observed. Emissions vary nonlinearly with fertilization, temperature and soil moisture. We find that a regional air chemistry model often underestimates soil NOx emissions and NOx at the surface and in the troposphere. Adjusting the model to match NOx observations leads to elevated tropospheric O3. Our results suggest management can greatly reduce soil NOx emissions, thereby improving air quality., Soil NOx emissions can significantly impact air quality in agricultural regions, particularly high temperature fertilized systems. Here, the authors investigate NOx emissions in one such system in California and suggest that the NOx emissions are the highest ever observed, with implications for air quality.

Published

2015