Allocation of photosynthesized carbon in an intensively farmed winter wheat–soil system as revealed by 14CO2 pulse labelling

Sun, Zhaoan; Chen, Qing; Han, Xiao; Bol, Roland; Meng, Fanqiao

doi:10.1038/s41598-018-21547-y

Cited by 25 publications

(39 citation statements)

References 45 publications

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“…The belowground transfer of ca. 20 % of assimilated C for all cultivars is in line with previous studies, which have reported fractions of similar magnitude for wheat plants, when not accounting for rhizosphere CO2 respiration: 18 -25 % (Hirte et al, 2018), 18 % (as reviewed by Kuzyakov and Domanski (2000)), 15 % (Keith et al, 1986), 17 % (Gregory and Atwell, 1991) and 31 % (Sun et al, 2018). In contrast, reported values of the partitioning of belowground translocated carbon by wheat plants to (i) roots and/or (ii) net rhizodeposition are much more variable.…”

Section: Carbon Allocation By Wheat Plantssupporting

confidence: 91%

“…In contrast, reported values of the partitioning of belowground translocated carbon by wheat plants to (i) roots and/or (ii) net rhizodeposition are much more variable. The same studies reported net rhizodeposition carbon as a percentage of total belowground carbon (root carbon and net rhizodeposition carbon combined) for wheat plants to be between 23 (as summarized by Kuzyakov and Domanski (2000)) and 72 % (Sun et al, 2018). The results obtained here (68 %) are thus at the high end of reported values.…”

Section: Carbon Allocation By Wheat Plantssupporting

confidence: 58%

“…Therefore, plants are commonly labelled at fixed time intervals during the growing season (repeated pulse-labelling). This results in reliable estimates of the partitioning of assimilated carbon to different plant compartments, as well as into the soil (Kong and Six, 2010;Kuzyakov and Domanski, 2000;Sun et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

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The soil organic carbon stabilization potential of old and new wheat cultivars: a 13CO2 labelling study

Broek¹,

Ghiasi²,

Decock³

et al. 2020

Preprint

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Abstract. Over the past decades, average global wheat yields have increased by about 250 %, mainly due to the cultivation of high-yielding wheat cultivars. This selection process not only affected aboveground parts of plants, but in some cases also reduced the root biomass, with potentially large consequences for the amount of organic carbon (OC) transferred to the soil. To study the effect of wheat breeding for high-yielding cultivars on subsoil OC dynamics, two old and two new wheat cultivars from the Swiss wheat breeding program were grown for one growing season in 1.5 m-deep lysimeters and pulse-labelled with 13CO2, to quantify the amount of assimilated carbon that was transferred belowground and potentially stabilized in the soil. The results show that although the old wheat cultivars with higher root biomass transferred more assimilated carbon belowground compared to more recent cultivars, no significant differences in net soil organic carbon (SOC) stabilization were found between the different cultivars. As a consequence, the long-term effect of wheat cultivar selection on SOC stocks will depend on the amount of root biomass that is stabilized in the soil. Our results suggest that the process of wheat selection for high-yielding cultivars resulted in lower amounts of belowground carbon translocation, with potentially important effects on SOC stocks. Further research is necessary to quantify the long-term importance of this effect.

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Section: Carbon Allocation By Wheat Plantssupporting

confidence: 91%

Section: Carbon Allocation By Wheat Plantssupporting

confidence: 58%

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The soil organic carbon stabilization potential of old and new wheat cultivars: a 13CO2 labelling study

Broek¹,

Ghiasi²,

Decock³

et al. 2020

Preprint

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“…The hydrothermal conditions of a wheat-soil system are essential to the dynamic balance of heat, moisture, and organic matter within the entire system and the thriving of wheat (Yang, Shang & Guan, 2012; Sun et al, 2018). Because of complicated biological, physical, and chemical processes like soil respiration, soil evaporation, plant transpiration, and so on, soil temperature and moisture have a close dynamic relationship with each other.…”

Section: Introductionmentioning

confidence: 99%

Analyzing moisture-heat coupling in a wheat-soil system using data-driven vector autoregression model

Feng

Xia

Zhu

et al. 2019

PeerJ

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Soil temperature and moisture have a close relationship, the accurate controlling of which is important for crop growth. Mechanistic models built by previous studies need exhaustive parameters and seldom consider time stochasticity and lagging effect. To circumvent these problems, this study designed a data-driven stochastic model analyzing soil moisture-heat coupling. Firstly, three vector autoregression models are built using hourly data on soil moisture and temperature at the depth of 10, 30, and 90 cm. Secondly, from impulse response functions, the time lag and intensity of two variables’ response to one unit of positive shock can be obtained, which describe the time length and strength at which temperature and moisture affect each other, indicating the degree of coupling. Thirdly, Granger causality tests unfold whether one variable’s past value helps predict the other’s future value. Analyzing data obtained from Shangqiu Experiment Station in Central China, we obtained three conclusions. Firstly, moisture’s response time lag is 25, 50, and 120 h, while temperature’s response time lag is 50, 120, and 120 h at 10, 30, and 90 cm. Secondly, temperature’s response intensity is 0.2004, 0.0163, and 0.0035 °C for 1% variation in moisture, and moisture’s response intensity is 0.0638%, 0.0163%, and 0.0050% for 1 °C variation in temperature at 10, 30, and 90 cm. Thirdly, the past value of soil moisture helps predict soil temperature at 10, 30, and 90 cm. Besides, the past value of soil temperature helps predict soil moisture at 10 and 30 cm, but not at 90 cm. We verified this model by using data from a different year and linking it to soil plant atmospheric continuum model.

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“…The hydrothermal conditions of a wheat-soil system are essential to the dynamic balance of heat, moisture and organic matter within the entire system and the thriving of wheat (Yang et al 2012;Sun et al 2018). Because of complicated biological, physical and chemical processes like soil respiration, soil evaporation, plant transpiration and so on, soil temperature and moisture have a close dynamic relationship with each other.…”

Section: Introductionmentioning

confidence: 99%

Peer Review #1 of "Analyzing moisture-heat coupling in a wheat-soil system using data-driven vector autoregression model (v0.1)"

2019

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Soil temperature and moisture have a close relationship, the accurate controlling of which is important for crop growth. Mechanistic models built by previous studies need exhaustive parameters and seldom consider time stochasticity and lagging effect. To circumvent these problems, this study designed a data-driven stochastic model analyzing soil moisture-heat coupling. Firstly, three vector autoregression models are built using hourly data on soil moisture and temperature at the depth of10 cm, 30 cm, and 90 cm. Secondly, from impulse response functions, the time lag and intensity of two variables' response to one unit of positive shock can be obtained, which describe the time length and strength at which temperature and moisture affect each other, indicating the degree of coupling. Thirdly, Granger causality tests unfold whether one variable's past value helps predict the other's future value. Analyzing data obtained from Shangqiu Experiment Station in Central China, we obtained three conclusions. Firstly, moisture's response time lag is 25 h, 50 h, and 120 h, while temperature's response time lag is 50 h, 120 h, and 120 h at 10 cm, 30 cm, and 90 cm. Secondly, temperature's response intensity is 0.2004°C, 0.0163°C and 0.0035°C for 1% variation in moisture, and moisture's response intensity is 0.0638%, 0.0163% and 0.0050% for 1°C variation in temperature at 10 cm, 30 cm and 90 cm. Thirdly, the past value of soil moisture helps predict soil temperature at 10 cm, 30 cm, and 90 cm. Besides, the past value of soil temperature helps predict soil moisture at 10 cm and 30 cm, but not at 90 cm. We verified this model by using data from a different year and linking it to Soil Plant Atmospheric Continuum model.

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Allocation of photosynthesized carbon in an intensively farmed winter wheat–soil system as revealed by 14CO2 pulse labelling

Cited by 25 publications

References 45 publications

The soil organic carbon stabilization potential of old and new wheat cultivars: a <sup>13</sup>CO<sub>2</sub> labelling study

The soil organic carbon stabilization potential of old and new wheat cultivars: a <sup>13</sup>CO<sub>2</sub> labelling study

Analyzing moisture-heat coupling in a wheat-soil system using data-driven vector autoregression model

Peer Review #1 of "Analyzing moisture-heat coupling in a wheat-soil system using data-driven vector autoregression model (v0.1)"

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Allocation of photosynthesized carbon in an intensively farmed winter wheat–soil system as revealed by 14CO2 pulse labelling

Cited by 25 publications

References 45 publications

The soil organic carbon stabilization potential of old and new wheat cultivars: a &lt;sup&gt;13&lt;/sup&gt;CO&lt;sub&gt;2&lt;/sub&gt; labelling study

The soil organic carbon stabilization potential of old and new wheat cultivars: a &lt;sup&gt;13&lt;/sup&gt;CO&lt;sub&gt;2&lt;/sub&gt; labelling study

Analyzing moisture-heat coupling in a wheat-soil system using data-driven vector autoregression model

Peer Review #1 of "Analyzing moisture-heat coupling in a wheat-soil system using data-driven vector autoregression model (v0.1)"

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The soil organic carbon stabilization potential of old and new wheat cultivars: a <sup>13</sup>CO<sub>2</sub> labelling study

The soil organic carbon stabilization potential of old and new wheat cultivars: a <sup>13</sup>CO<sub>2</sub> labelling study