Soil microbial respiration rate and temperature sensitivity along a north‐south forest transect in eastern China: Patterns and influencing factors

Wang, Qing; He, Nianpeng; Yu, Guirui; Gao, Yang; Wen, Xuefa; Wang, Rongfu; Koerner, Sally E.; Yu, Qiang

doi:10.1002/2015jg003217

Cited by 50 publications

(40 citation statements)

References 65 publications

(99 reference statements)

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“…); C is the slope of the change in CO 2 concentration; V is the volume of the incubation bottle and gas tube; m is the soil weight (g); α is the conversion coefficient for CO 2 mass (12/44, from CO 2 to C); and β is a conversion coefficient of time (3600, from s to h) (Wang et al, 2016). …”

Section: Measurement Of Soil Microbial Respiration Rate (R S )mentioning

confidence: 99%

Strong pulse effects of precipitation events on soil microbial respiration in temperate forests

Wang

Liu

et al. 2016

Geoderma

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Precipitation is a critical factor triggering soil biogeochemical processes in arid and semi-arid regions. In this study, we selected soils from two temperate forests-a mature natural forest and a degraded secondary forest-in a semi-arid region. We investigated the pulse effects of simulated precipitation (to reach 55% soil water-holding capacity) on the soil microbial respiration rate (R S ). We performed high-intensity measurements (at 5-min intervals for 48 h) to determine the maximum value of R S (R S-max ), the time to reach R S-max (T R S-max ), and the duration of the pulse effect (from the start to the end of ½R S-max ). The responses of R S to simulated precipitation were rapid and strong. R S-max was significantly higher in degraded secondary forest (18.69 μg C g soil) than in mature natural forest (7.94 μg C g soil). In contrast, the duration of the pulse effect and T R S-max were significantly lower in degraded secondary forest than in mature natural forest. Furthermore, the accumulative microbial respiration per gram of soil (A R S-soil ) did not differ significantly between degraded secondary forest and mature natural forest, but the accumulative microbial respiration per gram of soil organic C (A R S-soc ) was significantly higher in degraded secondary forest than in mature natural forest. Soil microbial biomass, soil nutrient, and litter nitrogen content were strongly correlated with the duration of the pulse effect and T R S-max . Soil physical structure, pH, and litter nitrogen content were strongly correlated with R S-max and A R S-soc . Our results indicate that the responses of soil microbial respiration to simulated precipitation are rapid and strong and that microbial respiration rate per gram C can be used to precisely determine the precipitation pulse of different soil samples as well as the effects of changing precipitation patterns on soil C content under various scenarios of global climate change.

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Section: Measurement Of Soil Microbial Respiration Rate (R S )mentioning

confidence: 99%

Strong pulse effects of precipitation events on soil microbial respiration in temperate forests

Wang

Liu

et al. 2016

Geoderma

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“…5). Chemical properties (pH, ORP), substrate (DOC), and temperature primarily exerted an influence on Q 10 by regulating microbial activity (Wang et al, 2016). Similarly, Wei et al (2014) confirmed that Q 10 depends on the structure of the soil microbial community.…”

Section: Soil Microbial Properties Control the Responses Of Q 10mentioning

confidence: 48%

“…2). R S and soil temperature were simultaneously and continuously measured during the model of varying temperature over 24-h based on the program of Wang et al (2016). Measuring R S more frequently (i.e., at intervals of several minutes) allows for an improved exploration of the relationship between R S and changing temperatures, as well as a more accurate calculation of Q 10 .…”

Section: Laboratory Incubation and Analysismentioning

confidence: 99%

“…This method was modified from He et al (2013) based on the designated program of Wang et al (2016). Furthermore, a button thermometer (DS1922L) was used to measure the actual soil temperature when we measured R S , providing accurate paired data for R S and soil temperature to calculate Q 10 (Wang et al, 2016). To reduce the error in button thermometer readings, we used five button thermometers to monitor soil temperature in the incubation bottles.…”

Section: Measurement Of R S and Soil Propertiesmentioning

confidence: 99%

“…For instance, the temperature in the incubator ranged from 6 C to 30 C during the first 12-h, and from 30 C to 6 C in the following 12-h, whereas the temperature measurements ranged from 5 C to 31 C during the first 12-h, and from 31 C to 5 C in the next 12-h. This method was modified from He et al (2013) based on the designated program of Wang et al (2016). Furthermore, a button thermometer (DS1922L) was used to measure the actual soil temperature when we measured R S , providing accurate paired data for R S and soil temperature to calculate Q 10 (Wang et al, 2016).…”

Section: Measurement Of R S and Soil Propertiesmentioning

confidence: 99%

See 2 more Smart Citations

Asymmetric responses of soil heterotrophic respiration to rising and decreasing temperatures

et al. 2017

Soil Biology and Biochemistry

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The Temperature Sensitivity (Q10) of Soil Respiration: Controlling Factors and Spatial Prediction at Regional Scale Based on Environmental Soil Classes

Meyer

Welp

Amelung

2018

Global Biogeochemical Cycles

167

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The temperature sensitivity of heterotrophic soil respiration is crucial for modeling carbon dynamics but it is variable. Presently, however, most models employ a fixed value of 1.5 or 2.0 for the increase of soil respiration per 10°C increase in temperature (Q10). Here we identified the variability of Q10 at a regional scale (Rur catchment, Germany/Belgium/Netherlands). We divided the study catchment into environmental soil classes (ESCs), which we define as unique combinations of land use, aggregated soil groups, and texture. We took nine soil samples from each ESC (108 samples) and incubated them at four soil moisture levels and five temperatures (5–25°C). We hypothesized that Q10 variability is controlled by soil organic carbon (SOC) degradability and soil moisture and that ESC can be used as a widely available proxy for Q10, owing to differences in SOC degradability. Measured Q10 values ranged from 1.2 to 2.8 and were correlated with indicators of SOC degradability (e.g., pH, r = −0.52). The effect of soil moisture on Q10 was variable: Q10 increased with moisture in croplands but decreased in forests. The ESC captured significant parts of Q10 variability under dry (R2 = 0.44) and intermediate (R2 = 0.36) moisture conditions, where Q10 increased in the order cropland

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Soil microbial respiration rate and temperature sensitivity along a north‐south forest transect in eastern China: Patterns and influencing factors

Cited by 50 publications

References 65 publications

Strong pulse effects of precipitation events on soil microbial respiration in temperate forests

Strong pulse effects of precipitation events on soil microbial respiration in temperate forests

Asymmetric responses of soil heterotrophic respiration to rising and decreasing temperatures

The Temperature Sensitivity (Q10) of Soil Respiration: Controlling Factors and Spatial Prediction at Regional Scale Based on Environmental Soil Classes

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