Combining nitrification inhibitor and urea can improve crop yield and nitrogen(N)use efficiency(NUE).However,the inhibitor easily gets inactivated in soil,making it difficult to achieve the desired effect.To develop a...Combining nitrification inhibitor and urea can improve crop yield and nitrogen(N)use efficiency(NUE).However,the inhibitor easily gets inactivated in soil,making it difficult to achieve the desired effect.To develop a synergistic urea for increasing the inhibitor action time,soil N supply,and wheat growth,dicyandiamide(DCD)was coated after granulation with epoxy resin and then mixed with urea to develop new resin-coated DCD(RCD)synergistic urea.Scanning electron microscopy(SEM)and hydrostatic release tests were used to evaluate the membrane microstructure and the controlled-release performance of RCD.Five fertilization treatments were set up in the field:zero-N control(CK),urea(U),urea+common DCD particles(SUD1),urea+RCD(SUD2),and urea+both common DCD particles and RCD(3:7,weight/weight)(SUD3)to investigate the effects of the DCD synergistic urea on wheat growth,yield,and NUE and soil available N content.The SEM results showed that RCD had a complete coating,smooth surface,and small and rugged channels for DCD release in the profile.The hydrostatic release test at 25?C showed that the release period of DCD was extended to ten days due to resin coating.In the three DCD synergistic urea treatments,only SUD3 resulted in a significant increase in wheat yield(18.47%)compared with U.The NUE in SUD3 was significantly higher than those in SUD2,U,and SUD1.The treatment SUD3 had higher soil available N content than the other treatments during the key wheat growth stages,while effectively reducing the risk of soil nitrate leaching during wheat maturity.In summary,SUD3,a mixture of urea,DCD particles,and RCD,was the best treatment for significantly increasing wheat growth,yield,and NUE and soil N supply.展开更多
There is a need for rice cultivars with high yields and nitrogen(N) use efficiency(NUE), but with low cadmium(Cd) accumulation in Cd-contaminated paddy soils.To determine the relative effects of rice genotype, soil ty...There is a need for rice cultivars with high yields and nitrogen(N) use efficiency(NUE), but with low cadmium(Cd) accumulation in Cd-contaminated paddy soils.To determine the relative effects of rice genotype, soil type, and Cd addition on rice grain yield and NUE, a pot experiment consisting of nine rice cultivars was conducted in two types of paddy soils, red soil(RS) and yellow soil(YS),without or with Cd spiked at 0.6 mg kg^(-1).The N supply was from both soil organic N pools and N fertilizers; thus, NUE was defined as the grain yield per unit of total crop-available N in the soil.Cd addition decreased grain yield and NUE in most rice cultivars,which was mainly related to reduced N uptake efficiency(NpUE, defined as the percentage of N taken up by the crop per unit of soil available N).However, Cd addition enhanced N assimilation efficiency(NtUE, defined as the grain yield per unit of N taken up by the crop) by 21.9% on average in all rice cultivars.The NpUE was mainly affected by soil type, whereas NtUE was affected by rice cultivar.Hybrid cultivars had higher NUEs than the japonica and indica cultivars because of their greater biomass and higher tolerance to Cd contamination.Reduction of NUE after Cd addition was stronger in RS than in YS, which was related to the lower absorption capacity for Cd in RS.Canonical correspondence analysis-based variation partitioning showed that cultivar type had the largest effect(34.4%) on NUE, followed by Cd addition(15.2%) and soil type(10.0%).展开更多
Dissolved organic nitrogen (DON) in soils has recently gained increasing interest because it may be both a direct N source for plants and the dominant available N form in nutrient-poor soils, however, its prevalence...Dissolved organic nitrogen (DON) in soils has recently gained increasing interest because it may be both a direct N source for plants and the dominant available N form in nutrient-poor soils, however, its prevalence in Mediterranean ecosystems remains unclear. The aims of this study were to i) estimate soil DON in a wide set of Mediterranean ecosystems and compare this levels with those for other ecosystems; ii) describe temporal changes in DON and dissolved inorganic nitrogen (DIN) forms (NH+ and NO3), and characterize spatial heterogeneity within plant communities; and iii) study the relative proportion of soil DON and DIN forms as a test of Schimel and Bennett's hypothesis that the prevalence of different N forms follows a gradient of nutrient availability. The study was carried out in eleven plant communities chosen to represent a wide spectrum of Mediterranean vegetation types, ranging from early to late successional status. DON concentrations in the studied Mediterranean plant communities (0-18.2 mg N kg-1) were consistently lower than those found in the literature for other ecosystems. We found high temporal and spatial variability in soil DON for all plant communities. As predicted by the Schimel and Bennett model for nutrient-poor ecosystems, DON dominance over ammonium and nitrate was observed for most plant communities in winter and spring soil samples. However, mineral-N dominated over DON in summer and autumn. Thus, soil water content may have an important effect on DON versus mineral N dominance in Mediterranean ecosystems展开更多
Plant diversity can be affected by both herbivore grazing and soil resources. However, it is unclear if the joint effects of herbivores and soil resources might vary with components of plant diversity. Here, we evalua...Plant diversity can be affected by both herbivore grazing and soil resources. However, it is unclear if the joint effects of herbivores and soil resources might vary with components of plant diversity. Here, we evaluated the relative and combined effects of herbivore assemblage and soil nitrogen(N) quantity and heterogeneity on the α and β components of plant diversity in a grassland that was subjected to four years of grazing under differing herbivore assemblages(no grazing, cattle grazing, sheep grazing, and mixed grazing). We found that herbivore assemblage combined with soil N quantity explained 41% of the variation in plant α-diversity, while herbivore assemblage combined with soil N heterogeneity explained 15% of the variation in plant β-diversity. The independent effects of herbivore assemblage explained more than those of soil N for both α-and β-diversity(α-diversity: 12% vs. 4%;β-diversity: 18% vs. 16%). We concluded that the effects of herbivores are stronger than those of soil N,and that grazing-induced changes in soil resources are important drivers of plant diversity change, especially α-diversity.Therefore, we suggest that managing herbivore species by accounting for the effects that their grazing can have on soil resources may be significant for plant diversity maintenance.展开更多
Background:Changes in foliar nitrogen(N)and phosphorus(P)stoichiometry play important roles in predicting the efects of global change on ecosystem structure and function.However,there is substantial debate on the efec...Background:Changes in foliar nitrogen(N)and phosphorus(P)stoichiometry play important roles in predicting the efects of global change on ecosystem structure and function.However,there is substantial debate on the efects of P addition on foliar N and P stoichiometry,particularly under diferent levels of N addition.Thus,we conducted a global meta-analysis to investigate how N addition alters the efects of P addition on foliar N and P stoichiometry across different rates and durations of P addition and plant growth types based on more than 1150 observations.Results:We found that P addition without N addition increased foliar N concentrations,whereas P addition with N addition had no efect.The positive efects of P addition on foliar P concentrations were greater without N addition than with N addition.Additionally,the efects of P addition on foliar N,P and N:P ratios varied with the rate and duration of P addition.In particular,short-term or low-dose P addition with and without N addition increased foliar N concentration,and the positive efects of short-term or low-dose P addition on foliar P concentrations were greater without N addition than with N addition.The responses of foliar N and P stoichiometry of evergreen plants to P addition were greater without N addition than with N addition.Moreover,regardless of N addition,soil P availability was more efective than P resorption efciency in predicting the changes in foliar N and P stoichiometry in response to P addition.Conclusions:Our results highlight that increasing N deposition might alter the response of foliar N and P stoichiometry to P addition and demonstrate the important efect of the experimental environment on the results.These results advance our understanding of the response of plant nutrient use efciency to P addition with increasing N deposition.展开更多
基金supported by the Major Agricultural Science and Technology Project of China(No.NK202218080315)the Project of Shandong Province Peanut Industry Technology System,China(No.SDAIT-04-06)。
文摘Combining nitrification inhibitor and urea can improve crop yield and nitrogen(N)use efficiency(NUE).However,the inhibitor easily gets inactivated in soil,making it difficult to achieve the desired effect.To develop a synergistic urea for increasing the inhibitor action time,soil N supply,and wheat growth,dicyandiamide(DCD)was coated after granulation with epoxy resin and then mixed with urea to develop new resin-coated DCD(RCD)synergistic urea.Scanning electron microscopy(SEM)and hydrostatic release tests were used to evaluate the membrane microstructure and the controlled-release performance of RCD.Five fertilization treatments were set up in the field:zero-N control(CK),urea(U),urea+common DCD particles(SUD1),urea+RCD(SUD2),and urea+both common DCD particles and RCD(3:7,weight/weight)(SUD3)to investigate the effects of the DCD synergistic urea on wheat growth,yield,and NUE and soil available N content.The SEM results showed that RCD had a complete coating,smooth surface,and small and rugged channels for DCD release in the profile.The hydrostatic release test at 25?C showed that the release period of DCD was extended to ten days due to resin coating.In the three DCD synergistic urea treatments,only SUD3 resulted in a significant increase in wheat yield(18.47%)compared with U.The NUE in SUD3 was significantly higher than those in SUD2,U,and SUD1.The treatment SUD3 had higher soil available N content than the other treatments during the key wheat growth stages,while effectively reducing the risk of soil nitrate leaching during wheat maturity.In summary,SUD3,a mixture of urea,DCD particles,and RCD,was the best treatment for significantly increasing wheat growth,yield,and NUE and soil N supply.
基金supported by the Modern Agricultural Industry Technology System of the Ministry of Agriculture of China(No.CARS-22-G-14)the Science and Technology Service Network Initiative of Chinese Academy of Sciences(No.KFJ-SW-STS-142)
文摘There is a need for rice cultivars with high yields and nitrogen(N) use efficiency(NUE), but with low cadmium(Cd) accumulation in Cd-contaminated paddy soils.To determine the relative effects of rice genotype, soil type, and Cd addition on rice grain yield and NUE, a pot experiment consisting of nine rice cultivars was conducted in two types of paddy soils, red soil(RS) and yellow soil(YS),without or with Cd spiked at 0.6 mg kg^(-1).The N supply was from both soil organic N pools and N fertilizers; thus, NUE was defined as the grain yield per unit of total crop-available N in the soil.Cd addition decreased grain yield and NUE in most rice cultivars,which was mainly related to reduced N uptake efficiency(NpUE, defined as the percentage of N taken up by the crop per unit of soil available N).However, Cd addition enhanced N assimilation efficiency(NtUE, defined as the grain yield per unit of N taken up by the crop) by 21.9% on average in all rice cultivars.The NpUE was mainly affected by soil type, whereas NtUE was affected by rice cultivar.Hybrid cultivars had higher NUEs than the japonica and indica cultivars because of their greater biomass and higher tolerance to Cd contamination.Reduction of NUE after Cd addition was stronger in RS than in YS, which was related to the lower absorption capacity for Cd in RS.Canonical correspondence analysis-based variation partitioning showed that cultivar type had the largest effect(34.4%) on NUE, followed by Cd addition(15.2%) and soil type(10.0%).
基金Supported by the Ministerio Espanol de Ciencia e Innovacio'n of the Spanish government (Nos.REN2003-08620-C02-01 and CGL2006-13665-C02-01)
文摘Dissolved organic nitrogen (DON) in soils has recently gained increasing interest because it may be both a direct N source for plants and the dominant available N form in nutrient-poor soils, however, its prevalence in Mediterranean ecosystems remains unclear. The aims of this study were to i) estimate soil DON in a wide set of Mediterranean ecosystems and compare this levels with those for other ecosystems; ii) describe temporal changes in DON and dissolved inorganic nitrogen (DIN) forms (NH+ and NO3), and characterize spatial heterogeneity within plant communities; and iii) study the relative proportion of soil DON and DIN forms as a test of Schimel and Bennett's hypothesis that the prevalence of different N forms follows a gradient of nutrient availability. The study was carried out in eleven plant communities chosen to represent a wide spectrum of Mediterranean vegetation types, ranging from early to late successional status. DON concentrations in the studied Mediterranean plant communities (0-18.2 mg N kg-1) were consistently lower than those found in the literature for other ecosystems. We found high temporal and spatial variability in soil DON for all plant communities. As predicted by the Schimel and Bennett model for nutrient-poor ecosystems, DON dominance over ammonium and nitrate was observed for most plant communities in winter and spring soil samples. However, mineral-N dominated over DON in summer and autumn. Thus, soil water content may have an important effect on DON versus mineral N dominance in Mediterranean ecosystems
基金supported by the National Natural Science Foundation of China (31772652, U1603235)the National Key Research and Development Program of China (2016YFC0500602)+1 种基金the Program for Introducing Talents to Universities (B16011)the Ministry of Education Innovation Team Development Plan (2013-373)
文摘Plant diversity can be affected by both herbivore grazing and soil resources. However, it is unclear if the joint effects of herbivores and soil resources might vary with components of plant diversity. Here, we evaluated the relative and combined effects of herbivore assemblage and soil nitrogen(N) quantity and heterogeneity on the α and β components of plant diversity in a grassland that was subjected to four years of grazing under differing herbivore assemblages(no grazing, cattle grazing, sheep grazing, and mixed grazing). We found that herbivore assemblage combined with soil N quantity explained 41% of the variation in plant α-diversity, while herbivore assemblage combined with soil N heterogeneity explained 15% of the variation in plant β-diversity. The independent effects of herbivore assemblage explained more than those of soil N for both α-and β-diversity(α-diversity: 12% vs. 4%;β-diversity: 18% vs. 16%). We concluded that the effects of herbivores are stronger than those of soil N,and that grazing-induced changes in soil resources are important drivers of plant diversity change, especially α-diversity.Therefore, we suggest that managing herbivore species by accounting for the effects that their grazing can have on soil resources may be significant for plant diversity maintenance.
基金supported by the National Natural Science Foundation of China(Grant Nos.31870602,31901295,and 32071745)the Program of Sichuan Excellent Youth Sci-Tech Foundation(20JCQN0145)+2 种基金the Chinese Postdoctoral Science Foundation(2020M673278)the CAS“Light of West China”Program(Y8C2021)Chengming You also acknowledges the China Scholarship Council for supporting a Ph.D.programme Grant(201806910030)。
文摘Background:Changes in foliar nitrogen(N)and phosphorus(P)stoichiometry play important roles in predicting the efects of global change on ecosystem structure and function.However,there is substantial debate on the efects of P addition on foliar N and P stoichiometry,particularly under diferent levels of N addition.Thus,we conducted a global meta-analysis to investigate how N addition alters the efects of P addition on foliar N and P stoichiometry across different rates and durations of P addition and plant growth types based on more than 1150 observations.Results:We found that P addition without N addition increased foliar N concentrations,whereas P addition with N addition had no efect.The positive efects of P addition on foliar P concentrations were greater without N addition than with N addition.Additionally,the efects of P addition on foliar N,P and N:P ratios varied with the rate and duration of P addition.In particular,short-term or low-dose P addition with and without N addition increased foliar N concentration,and the positive efects of short-term or low-dose P addition on foliar P concentrations were greater without N addition than with N addition.The responses of foliar N and P stoichiometry of evergreen plants to P addition were greater without N addition than with N addition.Moreover,regardless of N addition,soil P availability was more efective than P resorption efciency in predicting the changes in foliar N and P stoichiometry in response to P addition.Conclusions:Our results highlight that increasing N deposition might alter the response of foliar N and P stoichiometry to P addition and demonstrate the important efect of the experimental environment on the results.These results advance our understanding of the response of plant nutrient use efciency to P addition with increasing N deposition.
