Your search keyword '"Tao, Hong-Yan"' showing total 22 results

1. Microplastics positively mediate soil multifunctionality in dryland

Author

Wang, Peng-Yang, Zhao, Ze-Ying, Siddique, Kadambot H.M., Xiong, Xiao-Bin, Tao, Hong-Yan, Ma, Yue, Mo, Fei, Chen, Yinglong, Song, Yajie, Burch, William R., Jr, Ma, Baoluo, Wang, Song, Kavagi, Levis, Yang, Fang-Kun, and Xiong, You-Cai

Published

2024

2. Yield loss of inferior crop species and its physiological mechanism in a semiarid cereal-legume intercropping system

Author

Wang, Wei, Zhao, Jian-Hua, Li, Meng-Ying, Zhang, Wei, Rehman, Muhammad Maqsood Ur, Wang, Bao-Zhong, Ullah, Fazal, Cheng, Zheng-Guo, Zhu, Li, Zhang, Jin-Lin, Tao, Hong-Yan, Wang, Wen-Ying, and Xiong, You-Cai

Published

2024

3. Arbuscular mycorrhiza changes plant facilitation patterns and increases resource use efficiency in intercropped annual plants

Author

Zhu, Shuang-Guo, Duan, Hai-Xia, Tao, Hong-Yan, Zhu, Li, Zhou, Rui, Yang, Yu-Miao, Zhang, Xiao-Lin, Wang, Wen-Ying, Zhu, Hao, Zhang, Wei, Wang, Ren-Qing, Tao, Xiu-Ping, and Xiong, You-Cai

Published

2023

4. Soil phosphorus availability mediates facilitation dynamic in maize-grass pea intercropping system

Author

Zhu, Shuang-Guo, Kiprotich, Wesly, Cheng, Zheng-Guo, Zhou, Rui, Fan, Jing-Wei, Zhu, Hao, Wang, Wen-Ying, Wang, Wei, Wang, Ren-Qing, Tao, Hong-Yan, and Xiong, You-Cai

Published

2023

5. Effects of interspecific interactions on soil carbon emission and efficiency in the semiarid intercropping systems

Author

Wang, Wei, Li, Meng-Ying, Zhou, Rui, Zhu, Shuang-Guo, Tao, Hong-Yan, Khan, Aziz, Uzamurera, Aimee Grace, Wang, Bao-Zhong, Jin, Jun-Ming, Ma, Yue, Li, Wen-Bo, Tao, Xiu-Ping, and Xiong, You-Cai

Published

2023

6. Plant facilitation improves carbon production efficiency while reducing nitrogen input in semiarid agroecosystem

Author

Wang, Wei, Li, Meng-Ying, Zhu, Shuang-Guo, Khan, Aziz, Tao, Xiu-Ping, Huang, Guang-Fu, Liu, Hai-Ying, Zhang, Wei, Tao, Hong-Yan, Gong, Dong-Shan, Song, Chao, and Xiong, You-Cai

Published

2023

7. Priming effects of nZVI on carbon sequestration and iron uptake are positively mediated by AM fungus in semiarid agricultural soils

Author

Yang, Yu-Miao, Naseer, Minha, Zhu, Ying, Wang, Bao-Zhong, Wang, Song, Ma, Yue, Zhang, Xiao-Lin, Zhao, Xu-Zhe, Wang, Wen-Ying, Zhu, Shuang-Guo, Tao, Hong-Yan, and Xiong, You-Cai

Published

2023

8. Thickness-dependent release of microplastics and phthalic acid esters from polythene and biodegradable residual films in agricultural soils and its related productivity effects

Author

Uzamurera, Aimee Grace, Wang, Peng-Yang, Zhao, Ze-Ying, Tao, Xiu-Ping, Zhou, Rui, Wang, Wen-Ying, Xiong, Xiao-Bin, Wang, Song, Wesly, Kiprotich, Tao, Hong-Yan, and Xiong, You-Cai

Published

2023

9. Environmental risk of multi-year polythene film mulching and its green solution in arid irrigation region

Author

Zhao, Ze-Ying, Wang, Peng-Yang, Xiong, Xiao-Bin, Wang, Yi-Bo, Zhou, Rui, Tao, Hong-Yan, Grace, Uzamurera Aimee, Wang, Ning, and Xiong, You-Cai

Published

2022

10. Phosphorus availability mediates plant–plant interaction and field productivity in maize-grass pea intercropping system: Field experiment and its global validation.

Author

Zhu, Shuang-Guo, Tao, Hong-Yan, Li, Wen-Bo, Zhou, Rui, Gui, Yan-Wen, Zhu, Li, Zhang, Xiao-Lin, Wang, Wei, Wang, Bao-Zhong, Mei, Fu-Jian, Zhu, Hao, and Xiong, You-Cai

Subjects

*INTERCROPPING, *CATCH crops, *COMPETITION (Biology), *NUTRIENT uptake, *SOIL productivity, *INDUCTIVE effect, *CORN

Abstract

Plant–plant competitive and facilitative interactions might strongly affect the biodiversity effect and field productivity of intercropping system under the condition of limited resources such as available phosphorus (P). To test this hypothesis, the maize–grass pea intercropping system with five P application gradients (from low- to high-P) was experimentally investigated and the global meta-analysis validation was simultaneously performed. The main objectives of this study included as: 1) to examine the characteristics of plant–plant interaction variations along soil P addition gradients; 2) to identify the shift from interspecific complementarity to selection effect regarding the productivity and nutrient uptake and its driving mechanism; 3) to verify the universality of above phenomenon via global meta-analysis and explore the general pattern of P-dependent plant–plant interactions in the intercropping systems. Regardless of growing seasons, the total net effect of intercropping system was always >0, showing net facilitative effects of plant–plant interactions on field productivity and nutrient uptake efficiency, relative to monoculture systems. On average, the yield, biomass, N and P uptake were elevated by 3.0–13.7%, 3.2–12.8%, 7.5–20.1% and 5.6–18.9% in intercropping respectively, relative to those of monoculture. On the other hand, the contribution of complementarity effect to the total net effect was up to 78.7%, much more than that of selection effect (21.3%). The relative interaction index tended to decline remarkably with increasing soil P availability (from 0.097–0.126 to 0.027–0.029), suggesting that the facilitation (rather than the competition) dominated in intercropping under the low-P condition. Furthermore, the intercropped grass pea decreased the harvest index and allocated more biomass to vegetative growth as a result of the enhanced interspecific competition under the P-sufficient condition. Finally, the meta-analysis demonstrated that intercropping system had greater relative benefits regarding field productivity and N/P acquisition and utilization than monoculture system. In the meanwhile, the intensity of interspecific facilitative effect was enhanced under the P-deficient condition. Field observations presented the evidences regarding the P-dependent plant-plant interactions and its effects on field productivity in the maize-grass pea intercropping system. The meta-analysis confirmed that high P application decreased the interspecific facilitative effects in terms of field productivity and nutrient utilization in the intercropping systems. But the low-P condition led to the opposite trend, i.e. facilitative effect dominated in the intercropping for greater productivity efficiency. Graphical abstract elucidates the plant-plant interaction pattern in maize-grass pea intercropping system according to field observation and meta-analysis [Display omitted] • Effect of interspecific competition & facilitation on field productivity along soil P gradients in intercropping system is unclear • To examine how the plant–plant interactions affected crop productivity and nutrient uptake via field observations & meta-analyses • Intercropping led to greater net effects on productivity and N/P uptake efficiency via facilitative interactions than monoculture • Complementarity effect was dominant to ensure productivity benefit in low-P soil, yet competitive effect dominated in high-P soil • P-dependent plant-plant interaction efficiently mediated relative field productivity and resource benefits in intercropping system. [ABSTRACT FROM AUTHOR]

Published

2023

11. Dual effects of nZVI on maize growth and water use are positively mediated by arbuscular mycorrhizal fungi via rhizosphere interactions.

Author

Yang, Yu-Miao, Naseer, Minha, Zhu, Ying, Zhu, Shuang-Guo, Wang, Song, Wang, Bao-Zhong, Wang, Jing, Zhu, Hao, Wang, Wei, Tao, Hong-Yan, and Xiong, You-Cai

Subjects

VESICULAR-arbuscular mycorrhizas, SCANNING transmission electron microscopy, RHIZOSPHERE, WATER use, PLANT growth, WATER efficiency

Abstract

Nanoscale zero-valent iron (nZVI) might generate positive and negative effects on plant growth, since it acts as either hazardous or growth-promotion role. It is still unclear whether such dual roles can be mediated by arbuscular mycorrhizal fungi (AMF) in plant-AMF symbiosis. We first identified that in 1.5 g kg−1 nZVI (≤1.5 g kg−1 positively), maize biomass was increased by 15.83%; yet in 2.0 g kg−1 nZVI, it turned to be declined by 6.83%, relative to non-nZVI condition (CK, p < 0.05), showing a negative effect. Interestingly, the inoculation of AMF massively improved biomass by 45.18% in 1.5 g kg−1 nZVI, and relieved the growth inhibition by 2.0 g kg−1 nZVI. The event of water use efficiency followed similar trend as that of biomass. We found that proper concentration of nZVI can positively interact with rhizosphere AMF carrier, enabling more plant photosynthetic carbon to be remobilized to mycorrhiza. The scanning of transmission electron microscopy showed that excessive nZVI can infiltrate into root cortical cells and disrupt cellular homeostasis mechanism, significantly increasing iron content in roots by 76.01% (p < 0.05). Simultaneously, the images of scanning electron microscopy showed that nZVI were attached on root surface to form an insoluble iron ion (Fe3+) layer, hindering water absorption. However, they were efficiently immobilized and in situ intercepted by extraradical hyphae in mycorrhizal-nZVI symbiosis, lowering iron translocation efficiency by 6.07% (p < 0.05). Herein, the optimized structure remarkably diminished aperture blockage at root surface and improved root activities by 30.06% (p < 0.05). Particularly, next-generation sequencing demonstrated that appropriate amount of nZVI promoted the colonization and development of Funneliformis mosseae as dominant species in rhizosphere, confirming the positive interaction between AMF and nZVI, and its regulatory mechanism. Therefore, dual effects of nZVI can be actively mediated by AMF via rhizosphere interactions. The findings provided new insights into the safe and efficient application of nanomaterials in agriculture. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2022

12. Farmers' participation into the recovery of waste agricultural plastic film: An application of the Theory of Planned Behavior.

Author

Zhao, Ze-Ying, Li, Wen-Bo, Wang, Peng-Yang, Tao, Hong-Yan, Zhou, Rui, Cui, Jin-Ying, Zhang, Jian, Tian, Tao, Zhao, Xu-Zhe, Wang, Yi-Bo, and Xiong, You-Cai

Subjects

*PLANNED behavior theory, *PLASTIC films, *AGRICULTURAL wastes, *PLASTIC scrap, *FILM theory

Abstract

• Waste plastic film recovery program of Old for New was investigated in northwest China. • Theory of planned behavior (TPB) was extended to explain farmers' participation. • The attitude was as a key factor influencing the intention of recycling behavior. • Plastic film usage & household characteristics evidently affected recycling behavior. • Role of TPB-based compulsory environmental education was highlighted in program. This study aims to address the lack of relevant researches in the field of waste recycling using the Theory of Planned Behavior (TPB). A village-scale social survey was conducted to investigate the degree of farmers' participation in a waste plastic film program, i.e. Old for New in northwest China. The program required farmers to recycle plastic film residues in exchange for new films. Survey results showed that 67.5% of farmers accepted the program, yet only 14.5% of them actually participated. Logistic regression analysis was used to analyze questionnaire data and identify the factors that significantly affected farmers' recycling behavior. Principal component and weight analysis further showed that farmers' participation was mainly influenced by their attitudes (p < 0.01), with a relative weight (RW) of 46.3%. Yet, subjective norms (p < 0.1) and perceived behavior control (p < 0.1) had less effect on the degree of participation, and their RWs were 4.2% and 4.1% only, respectively. Moreover, the RW of plastic film usage characteristics and household characteristics reached up to 13.2% and 6.4%, respectively. Interestingly, environmental awareness (β = 0.083) and compulsory environmental education (β = 0.130) as surface factors strongly affected the farmers' adoption and response, with the RW of 25.7%. As such, the extended TPB model was established to analyze the participation behavior of farmers for stronger explanatory power. This study highlighted a promising strategy based on TPB for waste plastic film recycling and similar environmental management practices. [ABSTRACT FROM AUTHOR]

Published

2023

13. Plastic footprint deteriorates dryland carbon footprint across soil–plant-atmosphere continuum.

Author

Li, Meng-Ying, Wang, Wei, Ma, Yue, Chen, Yinglong, Tao, Hong-Yan, Zhao, Ze-Ying, Wang, Peng-Yang, Zhu, Li, Ma, Baoluo, Xiao, Yun-Li, Li, Shi-Sheng, Ashraf, Muhammad, Wang, Wen-Ying, Xiong, Xiao-Bin, Zhu, Ying, Zhang, Jin-Lin, Irum, Momena, Song, Ya-Jie, Kavagi, Levis, and Xiong, You-Cai

Subjects

*ECOLOGICAL impact, *PLASTICS, *POLYLACTIC acid, *SOIL structure, *SOIL profiles

Abstract

[Display omitted] • High plastic footprint reduced photosynthetic C storage, regardless of degradability. • C emission intensity increased for elevated C source combined with reduced C sinks. • Decreased soil aggregate stability and net C rhizodeposition reduce soil C sinks. • High plastic footprint deteriorated C footprint for lower permanent C sequestration. Plastic fragments are widely found in the soil profile of terrestrial ecosystems, forming plastic footprint and posing increasing threat to soil functionality and carbon (C) footprint. It is unclear how plastic footprint affects C cycling, and in particularly permanent C sequestration. Integrated field observations (including 13C labelling) were made using polyethylene and polylactic acid plastic fragments (low-, medium- and high-concentrations as intensifying footprint) landfilling in soil, to track C flow along soil–plant-atmosphere continuum (SPAC). The result indicated that increased plastic fragments substantially reduced photosynthetic C assimilation (p < 0.05), regardless of fragment degradability. Besides reducing C sink strength, relative intensity of C emission increased significantly, displaying elevated C source. Moreover, root C fixation declined significantly from 21.95 to 19.2 mg m−2, and simultaneously root length density, root weight density, specific root length and root diameter and surface area were clearly reduced. Similar trends were observed in the two types of plastic fragments (p > 0.05). Particularly, soil aggregate stability was significantly lowered as affected by plastic fragments, which accelerated the decomposition rate of newly sequestered C (p < 0.05). More importantly, net C rhizodeposition declined averagely from 39.77 to 29.41 mg m−2, which directly led to significant decline of permanent C sequestration in soil. Therefore, increasing plastic footprint considerably worsened C footprint regardless of polythene and biodegradable fragments. The findings unveiled the serious effects of plastic residues on permanent C sequestration across SPAC, implying that current C assessment methods clearly overlook plastic footprint and their global impact effects. [ABSTRACT FROM AUTHOR]

Published

2024

14. Size and concentration effects of polythene plastic residues on soil physiochemical traits and maize productivity: A three-year appraisal.

Author

Zhao, Ze-Ying, Wang, Peng-Yang, Xiong, Xiao-Bin, Irum, Momena, Mo, Fei, Cao, Jing, Wang, Ning, Tao, Hong-Yan, Hao, Meng, Wang, Song, Xiao, Kai-Wen, Yang, Fang-Kun, Wang, Yang, Khan, Aziz, Wang, Wen-Ying, Grace, Uzamurera Aimee, and Xiong, You-Cai

Subjects

*POLYETHYLENE, *ARID regions agriculture, *CROP residues, *SOIL productivity, *PLASTIC films, *STRUCTURAL equation modeling, *CORN

Abstract

Extensive studies have been conducted on the impacts of plastic film residue on crop productivity in dryland agriculture. However, the relevant results were inconsistent or even opposite, which was most probably affected by both the size and concentration of residual films. To clarify this issue, a three-year (2019–2021) field experiment was conducted to examine plastic residue landfill effects on maize productivity using three sizes (0.4 × 0.4 cm2 (small), 4 × 4 cm2 (medium), and 10 × 10 cm2 (large)) under the low and high addition concentrations in an irrigated maize field. The data indicated that medium-sized residues significantly reduced maize yield by 7.3% and 13.8% in low and high addition levels respectively, relative to non-landfill group (CK) (p < 0.05). Large and small-sized residues under low level had no significant impact on yield (p > 0.05), while high amounts of small residues turned to positively influence yield. This trend was closely correlated with soil temperature, soil moisture, key enzyme activities, macroaggregate proportion, soil organic carbon and total nitrogen contents. Structural equation modelling and relative importance analyses demonstrated soil hydrothermal (27.4%), soil nitrogen (22.0%), and physical properties (21.1%) as primary drivers. A general trend was that the sizes of residues showed evidently greater impacts than their addition levels. Moreover, medium residues showed negative effects, while large and small ones had neutral or positive effects. For the first time, our findings confirmed the size- and concentration-dependent effects of plastic residues on crop productivity and provided a novel insight into plastic film pollution assessment & management in agricultural ecosystems. • Medium plastic residues evidently reduced maize yield across the concentrations. • Large and small plastic ones turned to neutrally and positively affect maize yield. • Soil hydrothermal and nutrient status were affected by residue size & concentration. • Residue size showed greater impacts on maize productivity than its concentration. • This study filled knowledge gap in understanding plastic residue production effect. [ABSTRACT FROM AUTHOR]

Published

2024

15. Microplastics affect soil bacterial community assembly more by their shapes rather than the concentrations.

Author

Wang, Peng-Yang, Zhao, Ze-Ying, Xiong, Xiao-Bin, Wang, Ning, Zhou, Rui, Zhang, Zhi-Ming, Ding, Fan, Hao, Meng, Wang, Song, Ma, Yue, Uzamurera, Aimee Grace, Xiao, Kai-Wen, Khan, Aziz, Tao, Xiu-Ping, Wang, Wen-Ying, Tao, Hong-Yan, and Xiong, You-Cai

Subjects

*BACTERIAL communities, *MICROPLASTICS, *SOIL microbial ecology, *BIOGEOCHEMICAL cycles, *ARID regions agriculture, *SOIL microbiology

Abstract

• The specific surface area of MPs is positively correlated with bacterial diversity. • The continuity between MPs and the soil interface influences bacterial diversity. • The shapes of MP dominate the assembly of soil bacterial communities. • The importance of MP concentration is not as high as expected. • Community assembly under MPs follows both stochastic and deterministic processes. Polyethylene film mulching is a key technology for soil water retention in dryland agriculture, but the aging of the films can generate a large number of microplastics with different shapes. There exists a widespread misunderstanding that the concentrations of microplastics might be the determinant affecting the diversity and assembly of soil bacterial communities, rather than their shapes. Here, we examined the variations of soil bacteria community composition and functioning under two-year field incubation by four shapes (ball, fiber, fragment and powder) of microplastics along the concentration gradients (0.01%, 0.1% and 1%). Data showed that specific surface area of microplastics was significantly positively correlated with the variations of bacterial community abundance and diversity (r=0.505, p <0.05). The fragment- and fiber-shape microplastics displayed more pronounced interfacial continuity with soil particles and induced greater soil bacterial α-diversity, relative to the powder- and ball-shape ones. Strikingly, microplastic concentrations were not significantly correlated with bacterial community indices (r=0.079, p >0.05). Based on the variations of the βNTI, bacterial community assembly actually followed both stochastic and deterministic processes, and microplastic shapes significantly modified soil biogeochemical cycle and ecological functions. Therefore, the shapes of microplastics, rather than the concentration, significantly affected soil bacterial community assembly, in association with microplastic-soil-water interfaces. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

16. Plant biomass mediates the decomposition of polythene film-sourced pollutants in soil through plastisphere bacteria island effect.

Author

Zhao, Ze-Ying, Wang, Peng-Yang, Xiong, Xiao-Bin, Zhou, Rui, Li, Feng-Min, Cheng, Zheng-Guo, Wang, Wei, Mo, Fei, Cheruiyot, Kiprotich Wesly, Wang, Wen-Ying, Uzamurera, Aimee Grace, Tao, Hong-Yan, and Xiong, You-Cai

Subjects

*PLANT biomass, *POLLUTANTS, *POLYETHYLENE, *ARID regions agriculture, *BACTERIAL communities

Abstract

The polyethylene (PE) film mulching as a water conservation technology has been widely used in dryland agriculture, yet the long-term mulching has led to increasing accumulation of secondary pollutants in soils. The decomposition of PE film-sourced pollutants is directly associated with the enrichment of specific bacterial communities. We therefore hypothesized that plant biomass may act as an organic media to mediate the pollutant decomposition via reshaping bacterial communities. To validate this hypothesis, plant biomass (dried maize straw and living clover) was embedded at the underlying surface of PE film, to track the changes in the composition and function of bacterial communities in maize field across two years. The results indicated that both dry crop straw and alive clover massively promoted the α-diversity and abundance of dominant bacteria at plastisphere, relative to bulk soil. Bacterial communities tended to be clustered at plastisphere, forming the bacteria islands to enrich pollutant-degrading bacteria, such as Sphingobacterium , Arthrobacter and Paracoccus. As such, plastisphere bacteria islands substantially enhanced the degradation potential of chloroalkene and benzoate (p < 0.05). Simultaneously, bacterial network became stabilized and congregated at plastisphere, and markedly improved the abundance of plastisphere module hubs and connectors bacteria via stochastic process. Particularly, bacterial community composition and plastic film-sourced pollutants metabolism were evidently affected by soil pH, carbon and nitrogen sources that were mainly derived from the embedded biomass. To sum up, plant biomass embedding as a nature-based strategy (NbS) can positively mediate the decomposition of plastic-sourced pollutants through plastisphere bacteria island effects. [ABSTRACT FROM AUTHOR]

Published

2023

17. Thickness effects of polyethylene and biodegradable film residuals on soil properties and dryland maize productivity.

Author

Uzamurera, Aimee Grace, Zhao, Ze-Ying, Wang, Peng-Yang, Wei, Yong-Xian, Mo, Fei, Zhou, Rui, Wang, Wen-Li, Ullah, Fazal, Khan, Aziz, Xiong, Xiao-Bin, Li, Meng-Ying, Wesly, Kiprotich, Wang, Wen-Ying, Tao, Hong-Yan, and Xiong, You-Cai

Subjects

*POLYETHYLENE films, *CORN, *SOIL moisture, *WATER efficiency, *SOIL depth, *DEEP brain stimulation

Abstract

Plastic film residuals are increasingly remaining in cultivated lands. However, it is a critical issue how residual plastic type and thickness affect soil properties and crop yield. To address this issue, in situ landfill was conducted using thick polyethylene (PEt1), thin polyethylene (PEt2), thick biodegradable (BIOt1), thin biodegradable (BIOt2) residues, and CK (control) with no residues landfill in a semiarid maize field. The findings demonstrated that the impact of various treatments on soil characteristics and maize yield varied considerably. Soil water content decreased by 24.82% in PEt1 and 25.43% in PEt2, compared to BIOt1 and BIOt2, respectively. BIOt2 treatment increased soil bulk density by 1.31 g cm−3 and lowered soil porosity by 51.11%, respectively; it also elevated the silt/clay proportion by 49.42% relative to CK. In contrast, microaggregate composition in PEt2 was higher (43.02%). Moreover, BIOt2 lowered soil nitrate (NO 3 −) and ammonium (NH 4 +) content. Compared with other treatments, BIOt2 resulted in significantly higher soil total nitrogen (STN) and lower SOC/STN. Finally, BIOt2 exhibited the lowest water use efficiency (WUE) (20.57 kg ha−1 mm−1) and yield (6896 kg ha−1) among all the treatments. Therefore, BIO film residues exhibited detrimental impacts on soil quality and maize productivity compared to PE film ones. Considering film thickness, thin residual films more evidently influenced soil quality and maize productivity than thick film ones. [Display omitted] • BIO enhanced soil bulk density and lowered porosity, while thick PE residues didn't. • BIO significantly reduced SOC/STN, but thick PE residues exhibited a minor effect. • Relative to thick PE and CK, BIO residue lowered soil inorganic nitrogen. • WUE and yield decreased under BIO residues, while thick PE ones had a slight effect. • Thick PE and thin BIO residues had the least and most harmful impact, respectively. [ABSTRACT FROM AUTHOR]

Published

2023

18. Can shallow-incorporated organic mulching replace plastic film mulching for irrigated maize production systems in arid environments?

Author

Zhao, Ze-Ying, Wang, Peng-Yang, Xiong, Xiao-Bin, Zhou, Rui, Zhu, Ying, Wang, Yi-Bo, Wang, Ning, Wesly, Kiprotich, Xue, Wei, Cao, Jing, Zhang, Jin-Lin, Tao, Hong-Yan, and Xiong, You-Cai

Subjects

*PLASTIC mulching, *PLASTIC films, *CLOVER, *NITROGEN fixation, *IRRIGATION scheduling, *POLYETHYLENE films

Abstract

Since the ridge-furrow farming with plastic film mulching has caused widespread environmental pollution in maize field, it is essential to explore a substitutive strategy to mitigate plastic residue pollution while the output remains unchanged. This study aimed to investigate the potentials of shallow-incorporated organic mulching in replacement of polyethylene film mulching regarding maize productivity maintenance and its driving mechanism. Two-year (2019–2020) field experiment was conducted in an arid irrigation site of northwest China. There were five mulching treatments as follows: 1) shallow-incorporated maize straw piece incorporating into soils across 10-cm depth; 2) living clover mulching; 3) plastic film mulching; 4) combined plastic film mulching and shallow-incorporated maize straw piece and 5) combined plastic film and living clover mulching. Conventional planting without mulching was the control. For each plot with straw pieces, maize straws were cut into small pieces by straw crusher, evenly spread on soil surface and incorporated into soils using rotary tiller. Shallow-incorporated organic mulching treatments, including straw mulching and clover mulching, substantially promoted maize water productivity by 29.9% in straw mulching and 14.4% in clover mulching respectively, compared with the control. They achieved similar productivity level as plastic mulching or dual mulching treatments did. Both straw mulching and clover mulching also prolonged crop growth cycle by 10–20 days, and elevated soil temperature from the middle to late growing stage, relative to the plastic-involved treatments. Moreover, they significantly reduced field evaporation and accordingly promoted soil water storage, maintaining relatively fine hydro-thermal status. Particularly, both straw decomposition and clover biological nitrogen fixation contributed to more nitrogen input into soils at maturity. This resulted in a steady nitrogen accumulation into soils for rapid recovery growth at the later stage, i.e. excessive compensation for insufficient growth at the early stage (over-compensatory effect). Critically, shallow-incorporated organic mulching harvested higher net economic benefit by 3.3% in sole straw mulching and 10.4% in sole clover mulching relative to sole plastic film mulching respectively, while dual plastic and organic mulching decreased economic and ecological benefits. Shallow-incorporated organic mulching can obtain similar water productivity and economic benefit as polythene film mulching, as a result of over-compensation and biological nitrogen input into soils at late growing season. Polyethylene film mulching was not indispensable, and organic mulching may act as a green solution to displace film mulching according to local irrigation scheduling in arid irrigation region. ● Shallow-incorporated (10-cm) organic mulching with straw & living clover was tested. ● Organic mulching promoted soil hydro-thermal status and nitrogen input in arid irrigated field. ● Organic mulching led to similar crop yield as plastic film mulching with same irrigation amount. ● The mechanism was over-compensatory effect at the later stage in organic mulching. ● Such organic mulching might replace plastic film mulching in arid irrigation site. [ABSTRACT FROM AUTHOR]

Published

2023

19. In situ degradation of low-density polyethylene film in irrigation maize field: Thickness-dependent effect.

Author

Xiong, Xiao-Bin, Zhao, Ze-Ying, Wang, Peng-Yang, Zhou, Rui, Cao, Jing, Wang, Jing, Wesly, Kiprotich, Wang, Wen-Li, Wang, Ning, Hao, Meng, Wang, Yi-Bo, Tao, Hong-Yan, and Xiong, You-Cai

Published

2023

20. Intercrop overyielding weakened by high inputs: Global meta-analysis with experimental validation.

Author

Zhu, Shuang-Guo, Zhu, Hao, Zhou, Rui, Zhang, Wei, Wang, Wei, Zhou, Yi-Ning, Wang, Bao-Zhong, Yang, Yu-Miao, Wang, Jing, Tao, Hong-Yan, and Xiong, You-Cai

Subjects

*INTERCROPPING, *CATCH crops, *ORGANIC fertilizers, *WATER supply, *NUTRIENT uptake, *SOIL moisture

Abstract

The relative intensity of facilitative effect among coexisting plant species is frequently affected by soil water and nutrient availability, such as nitrogen (N), phosphorus (P), potassium (K), and organic fertilizer. However, to date, the general pattern of nutrient gradient effects on plant–plant interactions remains inconsistent or even opposite in the intercropping systems. To address this issue, we performed a global meta-analysis and three experiments to investigate the production efficiency of intercropping along fertilizer input gradient (low vs. high) by assessing the land equivalent ratio (LER). Trial 1 included five P gradient in the maize–grass pea intercropping system. Trial 2 consisted of two N gradient in the maize–wheat, maize–soybean and wheat–soybean intercropping systems. Trial 3 contained two water and three P gradients in the same intercropping systems as Trial 1. The meta-analysis result indicated that the average LER for yield (LER Y), biomass (LER B), N uptake (LER N), and P uptake (LER P) were 1.49, 1.25, 1.35, and 1.66, respectively. It implied that intercropping would save 49 %, 25 %, 35 % and 66 % lands to achieve the same yield, biomass, N and P uptake amount as monoculture, respectively. Also, high fertilizer inputs significantly decreased the relative productivity and nutrient uptake. Average effect sizes of high inputs on LER Y , LER B , LER N , and LER P were up to − 0.0505 (−0.0550 to −0.0461), − 0.0267 (−0.0303 to −0.0230), − 0.0321 (−0.0395 to −0.0247) and − 0.0237 (−0.0370 to −0.0103), respectively. These negative values demonstrated that the LER markedly declined under the high-nutrient conditions. On the other hand, the results of Trial 1 confirmed that the LER Y , LER B , LER N , and LER P tended to decrease significantly with increasing P addition. In Trial 2 , the LER Y of intercropping systems tended to significantly decrease with increasing N application. In Trial 3 , the LER Y , LER B , LER N , and LER P also displayed a descending trend with increasing P addition and soil water availability. Collectively, the three trials confirmed the reliability and universality of the meta-analysis conclusions. This study provided a broad support for the hypothesis of the nutrient-dependent relative benefits in intercropping systems. [Display omitted] • Average land equivalent ratio was greater than 1 in meta-analysis database. • High nutrient input decreased the land equivalent ratio relative to low input. • Field and pot-culture trials confirmed the reliability of meta-analysis results. • Relative productivity benefits were species specific and context dependent. • Results confirmed the universality of stress gradient hypothesis in intercropping. [ABSTRACT FROM AUTHOR]

Published

2023

21. Soil phosphorus availability and utilization are mediated by plant facilitation via rhizosphere interactions in an intercropping system.

Author

Zhu, Shuang-Guo, Cheng, Zheng-Guo, Wang, Jing, Gong, Dong-Shan, Ullah, Fazal, Tao, Hong-Yan, Zhu, Hao, Duan, Hai-Xia, Yang, Yu-Miao, and Xiong, You-Cai

Subjects

*PHOSPHORUS in soils, *INTERCROPPING, *CATCH crops, *SOIL acidification, *PLASTIC films, *RHIZOSPHERE

Abstract

We hypothesized that soil phosphorus (P) utilization might be tightly associated with interspecific interactions. To clarify this issue, a maize-grass pea intercropping system was investigated in a rainfed field with P addition (P0 and P +), water (rain-fed and plastic film mulching) and isolation (root barrier and root intermingling) treatments. The data indicated that total net effect was higher than 0 under all the conditions, displaying facilitative effects of biodiversity on agroecosystem productivity. The dynamics of total land equivalent ratio demonstrated that the intensity of plant-plant facilitation became greater under P-deficient condition. Maize was the facilitated species consistently, while grass pea changed from facilitated species under low soil P and moisture to facilitator under high soil P and moisture. The driving mechanism was associated with soil acidification and microbial community promotion effect under P-deficient condition. Intercropped rhizosphere soil phosphatase activity was increased by 4.9–17.2%, and Olsen-P availability was evidently enhanced relative to monoculture. Interestingly, drought stress significantly enhanced this trend. Critically, root isolation confirmed that plant-plant facilitation was briefly driven by interspecific rhizosphere interactions. Conclusively, this study confirmed the context-dependent facilitation shift in agroecosystem and provided a novel insight into the importance of rhizosphere interaction on soil P availability and utilization. [Display omitted] • Plant-plant facilitation was observed in the maize-grass pea intercropping system. • The intensity of facilitation decreased from low to high P and water gradients. • P deficiency promotes rhizosphere phosphatase activity and acidification process. • Drought and P deficiency led to the optimal soil microbial biomass and activities. • Intercropped grass pea fostered soil P mineralization and resource use efficiency. [ABSTRACT FROM AUTHOR]

Published

2023

22. Plant facilitation shifts along with soil moisture and phosphorus gradients via rhizosphere interaction in the maize-grass pea intercropping system.

Author

Zhu, Shuang-Guo, Cheng, Zheng-Guo, Batool, Asfa, Wang, Yi-Bo, Wang, Jing, Zhou, Rui, Khan, Aziz, Zhu, Sai-Yong, Yang, Yu-Miao, Wang, Wei, Zhu, Hao, Wang, Bao-Zhong, Tao, Hong-Yan, and Xiong, You-Cai

Subjects

*SOIL moisture, *INTERCROPPING, *PHOSPHORUS in soils, *CATCH crops, *SOIL acidification, *RHIZOSPHERE

Abstract

Note: P (phosphorus), W (water), + (positive or increase), – (negative or decrease). [Display omitted] • Plant facilitation was found in the intercropping system of maize and grass pea. • Facilitation shifted from +/+, +/0 to +/- from low to high water and P gradients. • In low P, rhizosphere soil acidification of grass pea fostered P mineralization. • Soil microbial biomass P was improved for higher productivity in +/+ facilitation. • Soil water and phosphorus availability altered interspecific facilitation model. Plant-plant facilitation is widely studied to increase productivity and resource utilization in cereal-legume intercropping system. However, physiological and ecological mechanisms driving interspecific interaction shift along the environmental gradients is largely unknown. To clarify this issue, we first tested plant-plant facilitation along with four phosphorus (P) gradients in maize-grass pea intercropping system. Results illustrated a progressive transition of seed yield-based facilitation from mutually facilitated (+/+) to maize facilitated but grass pea as facilitator (+/-) along with low to high P gradients. Secondly, above trend was evidently enhanced when combining with drought stress gradients, in which severe drought amplified facilitative effects, whereas the magnitude of facilitation was relatively weak under well-watered condition. Interestingly, biomass-based facilitation transition did not synchronize with seed-based one, in which occurred in a broader threshold range of water and P gradients. Specifically, total yield, biomass, N and P uptake increased by 0.5%, 4.1%, 1.8% and 2.9% under the sufficient P and water availability, whereas these indicators increased by 25.3%, 18.5%, 20.5% and 21.4% in P and water deficient soils. And the total net effect was positive under all the environmental conditions. Rhizosphere interaction plays a crucial role in facilitation judgment, and the driving mechanism was associated with soil acidification and microbial community promotion under P-deficient condition. Under low soil moisture and available P, soil acidification and lower rhizosphere soil pH of intercropped maize were observed. Rhizosphere phosphatase secretion were significantly activated in P-deficient soils and accelerated the mineralization of soil organophosphorus, and the microbial biomass P was improved for stronger facilitation. Taken together, our findings confirmed the P and water driven facilitation shift along with stress gradients and highlighted the roles of rhizosphere interaction in affecting species diversity advantage. In conclusion, our work provided a relatively full picture for plant facilitation evaluation and more accurate management regarding intercropping productivity. [ABSTRACT FROM AUTHOR]

Published

2022