Your search keyword '"Wu DF"' showing total 4 results

1. [Variation of Soil CO 2 Flux and Environmental Factors Across Erosion-Deposition Sites Under Simulation Experiment].

Author

Du LL, Wang ZQ, Wang R, Li RJ, Wu DF, Zhao M, Sun QQ, Gao X, and Guo SL

Abstract

The CO 2 flux from soil is an important component of global carbon cycle, and a small variation of soil CO 2 flux can prominently influence atmospheric CO 2 concentration and soil organic carbon stock. Soil erosion significantly influences soil CO 2 emission. However, the process of soil CO 2 flux during soil erosion and soil deposition remains uncertain. At the present study, a simulated experiment on soil erosion and deposition was conducted at Changwu State Key Agro-Ecological Station, Shaanxi, China. From July to September in 2014 and 2015, soil CO 2 flux was periodically measured using an automated CO 2 flux system LI-8100 (LI-COR, Lincoln, NE, USA) and soil temperature and moisture were collected by series data collection system of soil temperature and soil moisture (EM50, DECAGON, USA). The measurement frequency of soil CO 2 flux was once a week during 09:00 and 11:00. Soil temperature and soil moisture of 10 cm topsoil were measured continuously (at an interval of 30 minutes) during the experiment. At the same time, runoff and sediment were collected as well in each rain event, and then SOC content in sediment was measured. The results showed that soil CO 2 flux between erosion and deposition sites had a significant difference ( P <0.05), and soil CO 2 flux at deposition site [mean value 1.38 μmol·(m 2 ·s) -1 ] was 31% higher than that of soil CO 2 flux at deposition site [1.05 μmol·(m 2 ·s) -1 ], while temperature sensitivity at deposition site ( Q 10 :8.14) was 3 times as high as that at erosion site (2.34). Soil moisture at deposition site was 19% higher than that at erosion site ( P <0.05). Soil temperature was slightly higher at erosion site. The average SOC content (7.26 g·kg -1 ) increased by 6% in the sediment compared with the initial SOC content (6.83 g·kg -1 ). Soil moisture and SOC redistribution across erosion and deposition sites were influencing factors for soil CO 2 flux under erosional environment. In conclusion, soil CO 2 flux showed a significant variation at erosion site and deposition site. Changes in soil moisture and SOC contributed much to the difference in soil CO 2 flux across erosion and deposition sites.

Published

2016

2. [Response of Soil Respiration to Extreme Precipitation in Semi-arid Regions].

Author

Zhao M, Wang R, Li RJ, Du LL, Wu DF, Sun QQ, Gao X, and Guo SL

Subjects

Carbon Cycle, China, Soil, Desert Climate, Rain, Soil Microbiology

Abstract

Evaluating the response of soil microbial respiration to extreme precipitation event is significant for a better understanding about the influence of the change of precipitation regime on soil carbon cycling under global warming. A simulated experiment of extreme precipitations was conducted during the rainy season (July-September 2015) in the Changwu State Key Agro-Ecological Station, Shaanxi, China. The treatments consisted of three total precipitations in rainy season (600 mm, 300 mm, and 150 mm) and two precipitation regimes (10 mm, 150 mm; P 10 , P 150 ). Soil microbial respiration varied differently in the same single rainfall event among three precipitations. The variation coefficient of soil microbial respiration under 600 mm total precipitation was 36% (P 150 ) and 33% (P 10 ), and 28% and 22% under 300 mm total precipitation, 43% and 29% under 150 mm total precipitation. Under 600 mm total precipitation, the cumulative soil microbial respiration under P 150 was 20% less than that under P 10 ; however, the cumulative soil respiration of P 150 under 150 mm total precipitation was 22% more than that under P 10 ; and there was no significant difference between P 10 and P 150 under 300 mm total precipitation. Therefore, the duration in soil water stress must be considered to estimate soil microbial respirations under extreme precipitations.

Published

2016

3. [Changes of Soil Organic Carbon and Its Influencing Factors of Apple Orchards and Black Locusts in the Small Watershed of Loess Plateau, China].

Author

Li RJ, Wang R, Li NN, Jiang JS, Zhang YJ, Wang ZQ, Liu QF, Wu DF, and Guo SL

Subjects

Biomass, China, Ecosystem, Plant Roots, Carbon analysis, Carbon Sequestration, Malus, Robinia, Soil chemistry

Abstract

Orchard and black locust are two typical plants for comprehensive control in the small watershed of land uses in Loess area. The analysis of soil carbon sequestration function changes of growing two plants is important to gain a deep understanding of soil carbon cycle process and its influencing factors of terrestrial ecosystems under the condition of small watershed comprehensive control. The experiment was conducted in the Changwu State Key Agro-Ecological Station, Shanxi, China. SOC, TN, fine root biomass and litter amount were determined at different age apple orchards and black locusts on the slope land of Wangdonggou watershed to study the variation characteristics of soil organic carbon and its influencing factors under two measurements. The results showed that: (1) SOC and TN contents in apple orchards significantly decreased with the increased age, whereas those in black locust showed an increased tendency with the age increased. Compared with the adjacent cropland,the SOC and TN contents in year 3, year 8, year 12 and year 18 apple orchards were decreased 3. 26%, 10. 54%, 18. 08%, 22. 55% and - 8. 08%, - 0. 48%, 4. 97%, 16. 91%, respectively. However,SOC and TN contents increased 5. 31%, 32. 36%, 44. 13% and 2. 49%, 15. 75%, 24. 22%, in year 12, year 18 and year 25 black locusts, respectively. (2) The fine root biomass in year 3, year 8, year 12, and year 18 apple orchards were about 25. 97% 66. 23%, 85. 71% and 96. 10% of the adjacent cropland, respectively; and the litter amounts were all 0 g . m-2. However, compared with adjacent cropland, The fine root biomass in year 12, year 18 and year 25 black locusts were increased 23. 53%, 79. 41%, 157. 35%, respectively; and the litter input rates were 194, 298 , 433 g . (m2 . a) -1, respectively. (3) The difference of organic matter input was the major factor which drove the variability of soil carbon sequestration function of apple orchard and black locust ecosystems.

Published

2015

4. [Effects of Nitrogen Fertilization on Soil Respiration and Temperature Sensitivity in Spring Maize Field in Semi-Arid Regions on Loess Plateau].

Author

Jiang JS, Guo SL, Wang R, Liu QF, Wang ZQ, Zhang YJ, Li NN, Li RJ, Wu DF, and Sun QQ

Subjects

Biomass, China, Plant Roots growth & development, Seasons, Zea mays growth & development, Desert Climate, Fertilizers, Nitrogen chemistry, Soil chemistry, Temperature

Abstract

Understanding the effects of nitrogen fertilization on soil respiration rate and its temperature sensitivity (Q10) is of critical importance to predict the variability of soil respiration in cropland. A field experiment was established in a rain-fed spring maize cropland (Zea mays L. ) in the State Key Agro-Ecological Experimental Station in the Loess Plateau in Changwu County, Shaanxi Province, China. The experiment comprised of two treatments: no N-fertilizer application ( CK) and N-fertilizer application with 160 kg N · hm(-2) (N). Soil respiration rate, soil temperature, soil moisture, yields, aboveground biomass and root biomass were measured in two continuous spring maize growing seasons from April 2013 to September 2014. The cumulative soil CO2 emissions were increased by 35% in 2013 and 54% in 2014 in N treatment as compared to CK treatment. Though nitrogen fertilization significantly increased the cumulative soil CO2 emissions (P < 0.05), it did decrease evidently the temperature sensitivity of soil respiration (P < 0.05) . The Q10 values in N treatment were decreased by 27% and 17% compared with CK treatment in 2013 and 2014, respectively. Nitrogen fertilization significantly increased the maize yields, aboveground biomass and root biomass (P < 0.05). Root biomasses in N treatment were 32% and 123% greater than those in CK treatment of 2013 and 2014, respectively. Nitrogen fertilization had no marked influence on soil temperature or moisture. Root biomass was a critical biotical factor for variation of soil respiration under nitrogen fertilization.

Published

2015