Sarker Rani, Jharna; Singh, Bhupinderpal Pal; He, Xinhua; Fang, Yunying; Li, Guangdi D; Collins, Damian; Cowie, Annette L

Author(s)

Sarker Rani, Jharna

Singh, Bhupinderpal Pal

He, Xinhua

Fang, Yunying

Li, Guangdi D

Collins, Damian

Cowie, Annette L

Publication Date

2017-09

Abstract

Carbon (C) and nitrogen (N) allocation and assimilation are coupled processes, likely infuencing C accumulation, N use efciency and plant productivity in agro-ecosystems. However, dynamics and responses of these processes to management practices in semi-arid agro-ecosystems are poorly understood. A feld-based 13CO2 and urea-15N pulse labelling experiment was conducted to track how C and N allocation and assimilation during canola growth from fowering to maturity were afected by short-term (2-year) tillage (T) and no-till (NT) with or without 100kg urea-N ha−1 (T-0, T-100, NT-0, NT100) on a Luvisol in an Australian semi-arid region. The T-100 caused greater (P<0.05) belowground C allocation and higher (P<0.05) translocation of soil N to shoots and seeds, compared to other treatments. Microbial N uptake was rapid and greatest in the fertilized (cf. non-fertilized) treatments, followed by a rapid release of microbial immobilized N, thus increasing N availability for plant uptake. In contrast, management practices had insignifcant impact on soil C and N stocks, aggregate stability, microbial biomass, and 13C retention in aggregate-size fractions. In conclusion, tillage and N fertilization increased belowground C allocation and crop N uptake and yield, possibly via enhancing root–microbial interactions, with minimal impact on soil properties.

Citation

Scientific Reports, v.7, p. 1-13

ISSN

2045-2322

Link

https://hdl.handle.net/1959.11/58260

Publisher

Nature Publishing Group

Rights

Attribution 4.0 International

Title

Tillage and nitrogen fertilization enhanced belowground carbon allocation and plant nitrogen uptake in a semi-arid canola crop–soil system

Type of document

Journal Article

Entity Type

Publication

Author(s)	Sarker Rani, Jharna Singh, Bhupinderpal Pal He, Xinhua Fang, Yunying Li, Guangdi D Collins, Damian Cowie, Annette L
Publication Date	2017-09
Abstract	<p>Carbon (C) and nitrogen (N) allocation and assimilation are coupled processes, likely infuencing C accumulation, N use efciency and plant productivity in agro-ecosystems. However, dynamics and responses of these processes to management practices in semi-arid agro-ecosystems are poorly understood. A feld-based <sup>13</sup>CO<sub>2</sub> and urea-15N pulse labelling experiment was conducted to track how C and N allocation and assimilation during canola growth from fowering to maturity were afected by short-term (2-year) tillage (T) and no-till (NT) with or without 100kg urea-N ha<sup>−1</sup> (T-0, T-100, NT-0, NT100) on a Luvisol in an Australian semi-arid region. The T-100 caused greater (P<0.05) belowground C allocation and higher (P<0.05) translocation of soil N to shoots and seeds, compared to other treatments. Microbial N uptake was rapid and greatest in the fertilized (cf. non-fertilized) treatments, followed by a rapid release of microbial immobilized N, thus increasing N availability for plant uptake. In contrast, management practices had insignifcant impact on soil C and N stocks, aggregate stability, microbial biomass, and <sup>13</sup>C retention in aggregate-size fractions. In conclusion, tillage and N fertilization increased belowground C allocation and crop N uptake and yield, possibly <i>via</i> enhancing root–microbial interactions, with minimal impact on soil properties.</p>
Citation	Scientific Reports, v.7, p. 1-13
ISSN	2045-2322
Link	https://hdl.handle.net/1959.11/58260
Publisher	Nature Publishing Group
Rights	Attribution 4.0 International
Title	Tillage and nitrogen fertilization enhanced belowground carbon allocation and plant nitrogen uptake in a semi-arid canola crop–soil system
Type of document	Journal Article
Entity Type	Publication

Tillage and nitrogen fertilization enhanced belowground carbon allocation and plant nitrogen uptake in a semi-arid canola crop–soil system

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