Nitrogen uptake and transfer in a soybean/maize intercropping system in the karst region of southwest China

Zhang, Hao; Zeng, Fuping; Zou, Zhigang; Zhang, Zhenqian; Li, Youzhi

doi:10.1002/ece3.3295

Cited by 26 publications

(23 citation statements)

References 29 publications

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“…In addition, the total biomass and the N uptake with no root barrier were significantly higher than those with the nylon net barrier. In conclusion, the root contact plays an important role in intercropping [14]. However, the maize/alfalfa intercropping system has no commercial applicability.…”

Section: N Transfer Between Maize and Alfalfamentioning

confidence: 94%

“…The main reason for the high nitrogen transfer with no N barrier may be that the close root contact of maize and alfalfa can stimulate the plants to release more N-containing compounds or generate more mycelial connections between the legume and the cereal plants [21]. Moreover, root contact reduces the travel distance of N compounds through mass flow [31], which efficiently promotes N transfer in soybean/maize intercropping systems [14]. In addition, root morphology and biomass influence the uptake and the utilization of soil water and nutrients and permit subsequent N transfers between cereals and legumes [23].…”

Section: N Transfer Between Maize and Alfalfamentioning

confidence: 99%

“…These benefits occur because N transfer between legumes and cereals can be an important source of nitrogen for cereal crops [7,8]. N transfer has been studied thoroughly in many cereal-legume intercropping systems, e.g., bean/maize [9], pea/barley [10], faba/wheat [11], peanut/rice [7], manures/lettuce [12], pea/maize [13], soybean/maize [14], and bean/garlic [15]. Literature data show that rates of N transfer range from 0 to 80% from legumes to cereal in mixed stands, depending on the legume species and the cultivar [16][17][18].…”

Section: Introductionmentioning

confidence: 99%

“…One study revealed that root contact improved N uptake by 26.3% [24]. Zhang et al found that soybean/maize intercropping could improve N transfer and uptake in the karst region of Southwest China [14]. However, it is unclear whether the high nitrogen transfer is associated with the total N uptake under maize/alfalfa root contact conditions.…”

Section: Introductionmentioning

confidence: 99%

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Root Contact between Maize and Alfalfa Facilitates Nitrogen Transfer and Uptake Using Techniques of Foliar 15N-Labeling

et al. 2020

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Belowground nitrogen (N) transfer from legumes to non-legumes provides an important N source for crop yield and N utilization. However, whether root contact facilitates N transfer and the extent to which N transfer contributes to crop productivity and N utilization have not been clarified. In our study, two-year rain shelter experiments were conducted to quantify the effect of root contact on N transfer in a maize/alfalfa intercropping system. N transfer occurred mainly one direction from alfalfa to maize during the growth period. Following the N0 treatment, the amount of N transfer from alfalfa to maize was 204.56 mg pot−1 with no root barrier and 165.13 mg pot−1 with a nylon net barrier, accounting for 4.72% and 4.48% of the total N accumulated in maize, respectively. Following the N1 treatment, the amount of N transfer from alfalfa to maize was 197.70 mg pot−1 with no root barrier and 139.04 mg pot−1 with a nylon net barrier, accounting for 3.64% and 2.36% of the total N accumulated in the maize, respectively. Furthermore, the amount of N transfer without no root barrier was 1.24–1.42 times higher than that with a nylon net barrier regardless of the level of N addition. Our results highlight the importance and the relevance of root contact for the enhancement of N transfer in a maize/alfalfa intercropping system.

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Section: N Transfer Between Maize and Alfalfamentioning

confidence: 94%

Section: N Transfer Between Maize and Alfalfamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Root Contact between Maize and Alfalfa Facilitates Nitrogen Transfer and Uptake Using Techniques of Foliar 15N-Labeling

et al. 2020

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“…shown the importance of root interaction to enhance the direct N transfer via root exudates in a maize-faba bean intercrop (Li et al, 2016) or via mycorrhizal hyphae network that increased direct N transfer from soybean to maize from 13.2 to 30.2% (Zhang et al, 2017). Mycorrhizas were not quantified in the current study, although the presence of soil may have provided mycorrhizal spores.…”

Section: Effects Of Soybean On Sugarcane Biomass and Nitrogen Accumulmentioning

confidence: 70%

Developing sugarcane - legume companion cropping systems to minimise nitrous oxide emissions

Cajas¹,

Elizabeth²

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Global efforts are underway to reduce greenhouse gas emissions (GHG) from anthropogenic activities. Nitrous oxide (N2O) emissions accounted for 13% of Australia's National GHG inventory over the period 2016-2017 (NGGI, 2017) with most N2O derived from agricultural soils. Sugarcane soils are high emitters of N2O, and this thesis explores whether legumes, grown as a companion crop with biological N2 fixation (BNF) capacity, can partially replace N fertiliser to lower the emissions of N2O from sugarcane soil. Chapter 2 synthesises published literature on sugarcane intercropping. Most research has focussed on the productivity of sugarcane with intercrops, including legumes. Intercropping can benefit sugarcane yield, have neutral or negative effects. This practice is common in subsistence agriculture, and farm income benefits, but environmental benefits intercropping have not been a research focus. Chapters 3 and 4 explore sugarcane-legume intercropping at three commercial farms in Australia. N2O emissions, soil and crop variables were quantified with different N fertiliser applications and in the presence or absence of legumes. The farms, two Rain-fed, one Irrigated, were located in the dry and wet tropics, and in the subtropics, representing different climate and agronomic settings. Industry-recommended (full) N fertiliser rates were compared with up to 50% reduced N fertiliser rates in the presence or absence of legume and benchmarked against a zero N fertiliser control. We hypothesised that reduced application of N fertiliser limits sugarcane growth and that legumes can alleviate N limitation. However, full and reduced N fertiliser treatments mostly generated similar sugarcane yields, confirming that industryrecommended full N fertiliser rates exceed sugarcane needs. In line with this notion, the reduced N+legume treatments did not improve sugarcane growth. N2O emissions in reduced N+legume were either similar to reduced N fertiliser sugarcane monoculture or higher and similar to the emissions observed with full N fertiliser rates. Soybean strongly benefitted sugarcane yield under N limiting conditions (zero N fertiliser) at one farm, increasing soluble soil N levels and nearly doubling sugarcane yield compared to zero-N sugarcane monoculture, and generating 6-times lower N2O emissions than the full N rate. At the Rain-fed sites, soil nitrate levels explained 81 and 64% of N2O emissions; at the Irrigated site, the interaction of soil nitrate and soil moisture explained 63% of N2O emissions. High N2O emissions factors at the subtropical site were associated with wet, low drainage soil (>70% water filled pore space over summer), conditions that promote denitrification. High N fertiliser rates in Irrigated, welliii draining soils had lower N2O emissions, possibly shifting N losses from gaseous to leaching. The promising findings observed with soybean under N limitation require further investigation to explore N2O mitigation options with a view of optimising legume facilitation and the 'tipping point' for N fertiliser...

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¹⁵N labeling technology reveals enhancement of nitrogen uptake and transfer by root interaction in cotton/soybean intercropping

et al. 2023

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BackgroundBiological nitrogen fixation in legumes and their transfer of nitrogen to non‐legumes in legume/non‐legume intercropping systems are considered to be important for the improvement of productivity. However, research on interspecific interaction and root nitrogen transfer in cotton/soybean intercropping systems has rarely been undertaken. In this study, the roots of cotton and soybean were separated with either complete root barriers (CB), using plastic film, or semi‐root barriers (SB), using nylon net. No root barrier (NB) was used as the control.ResultsThe results showed that cotton produced more above‐ground dry matter (DM) than soybean. The above‐ground DM and nitrogen uptake of cotton was greatest with the NB treatment. The above‐ground DM and nitrogen uptake of soybean was greatest with the CB treatment. At the harvest stage, the nitrogen transfer rate from soybean to cotton was 22.47% with the SB treatment and 40.41% with the NB treatment. Interspecific root interaction increased the nitrogen transfer amount, especially for the cotton roots in the 0–15 cm soil layer and for the soybean roots in the 0–30 cm soil layer. The root distribution of soybean was the key factor affecting nitrogen transfer amount, and nitrogen transfer amount was the key factor affecting nitrogen uptake of cotton in the cotton/soybean intercropping system.ConclusionThese results indicated that nitrogen transfer from soybean to cotton through root interaction improved cotton above‐ground DM and nitrogen uptake. © 2023 Society of Chemical Industry.

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Nitrogen uptake and transfer in a soybean/maize intercropping system in the karst region of southwest China

Cited by 26 publications

References 29 publications

Root Contact between Maize and Alfalfa Facilitates Nitrogen Transfer and Uptake Using Techniques of Foliar 15N-Labeling

Root Contact between Maize and Alfalfa Facilitates Nitrogen Transfer and Uptake Using Techniques of Foliar 15N-Labeling

Developing sugarcane - legume companion cropping systems to minimise nitrous oxide emissions

¹⁵N labeling technology reveals enhancement of nitrogen uptake and transfer by root interaction in cotton/soybean intercropping

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Nitrogen uptake and transfer in a soybean/maize intercropping system in the karst region of southwest China

Cited by 26 publications

References 29 publications

Root Contact between Maize and Alfalfa Facilitates Nitrogen Transfer and Uptake Using Techniques of Foliar 15N-Labeling

Root Contact between Maize and Alfalfa Facilitates Nitrogen Transfer and Uptake Using Techniques of Foliar 15N-Labeling

Developing sugarcane - legume companion cropping systems to minimise nitrous oxide emissions

15N labeling technology reveals enhancement of nitrogen uptake and transfer by root interaction in cotton/soybean intercropping

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¹⁵N labeling technology reveals enhancement of nitrogen uptake and transfer by root interaction in cotton/soybean intercropping