Integrated agronomic optimization(IAO)adopts suitable crop varieties,sowing dates,planting density,and advanced nutrient management to redesign the entire production system according to the local environment,and it ca...Integrated agronomic optimization(IAO)adopts suitable crop varieties,sowing dates,planting density,and advanced nutrient management to redesign the entire production system according to the local environment,and it can achieve synergistic improvements in crop yields and resource utilization.However,the intensity and magnitude of the impacts of IAO on soil quality under long-term intensive production and high nitrogen use efficiency(NUE)require further clarification.Based on a 13-year field experiment conducted in Dawenkou,Tai'an,Shadong Province,China,we investigated the effects of four cultivation modes on the grain yield,NUE,and soil aggregate structure,as well as the fraction of organic matter(SOM)and soil quality,reflected by the integrated fertility index(IFI),during the winter wheat maturation periods in 2020–2022.The four cultivation modes were traditional local farming(T1),farmer-based improvement(T2),increased yield regardless of production cost(T3),and integrated soil–crop system management(T4).As the IAO modes,T2 and T4 were characterized by denser planting,reduced nitrogen(N)fertilizer application rates,and delayed sowing compared to T1 and T3,respectively.In this long-term experiment,IAO was found to maintain aggregate stability,increase SOM content(by increasing organic carbon and total nitrogen of the light fraction(LF)and the particulate organic matter fraction(POM)),and improve SOM quality(by increasing the proportions of LF and POM and the ratio of organic carbon to total nitrogen in SOM).Compared to T1,the IFI values of T2,T3,and T4 increased by 10.91,23.38,and 25.55%,and by 17.78,6.41,and 28.94%in the 0–20 and 20–40 cm soil layers,respectively.The grain yield of T4 was 22.52%higher than that of T1,and reached 95.98%of that in T3.Furthermore,the NUE of T4 was 35.61%higher than those of T1 and T3.In conclusion,our results suggest that the IAO mode T4 synergistically increases grain yield and NUE in winter wheat,while maximizing soil quality.展开更多
Lodging resistance of winter wheat(Trnticum aestivum L.) can be increased by late sowing.However, whether grain yield and nitrogen use efficiency(NUE) can be maintained with delayed sowing remains unknown. During the ...Lodging resistance of winter wheat(Trnticum aestivum L.) can be increased by late sowing.However, whether grain yield and nitrogen use efficiency(NUE) can be maintained with delayed sowing remains unknown. During the 2013-2014 and 2014-2015 growing seasons, two winter wheat cultivars were sown on three dates(early sowing on October 1, normal so,wing on October8, and late sowing on October 15) to investigate the responses of lodging resistance, grain yield,and NUE to sowing date. No significant differences in lodging resistance, grain yield, or NUE between early and normal sowing were observed. Averaging over the two cultivars and years,postponing the sowing date significantly increased lodging resistance by 53.6% and 49.6%compared with that following early and normal sowing, respectively. Lodging resistance was improved mainly through a reduction in the culm height at the center of gravity and an increase in the tensile strength of the base internode. Late sowing resulted in similar grain yield as well as kernel weight and number of kernels per square meter, compared to early and normal sowing.Averaging over the two cultivars and years, delayed sowing resulted in a reduction in nitrogen uptake efficiency(UPE) by 11.0% and 9.9% compared to early and normal sowing, respectively,owing to reduced root length density and dry matter accumulation before anthesis. An average increase in nitrogen utilization efficiency(UTE) of 12.9% and 11.2% compared to early and normal sowing, respectively, was observed with late sowing owing to a reduction in the grain nitrogen concentration. The increase in UTE offset the reduction in UPE, resulting in equal NUEs among all sowing dates. Thus, sowing later than normal could increase lodging resistance while maintaining grain yield and NUE.展开更多
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
The development of green technologies for improving winter wheat yield and nitrogen use efficiency(NUE)is crucial for ensuring national food security and reducing carbon footprint.This study outlines China wheat yield...The development of green technologies for improving winter wheat yield and nitrogen use efficiency(NUE)is crucial for ensuring national food security and reducing carbon footprint.This study outlines China wheat yield progress and establishes a three-stage theory for this.The key constraints from a soil-crop system perspective were identified:population-individual competition,dry matter accumulation and distribution,and soil quality degradation.To address these constraints,an optimized soil-crop system is proposed.(1)Adopting rational dense planting using optimal densities of 330-375 plants m^(-2) for large-spike cultivars and 225-270 plants m^(-2) for medium-spike cultivars to establish robust populations.(2)Enhancing soil quality and reducing carbon footprint by the adoption of straw return combined with a strategy of deep plowing and rotary tillage to improve soil fertility quality,reducing carbon footprint by 1.87 Mg CO_(2) eqv ha^(-1).(3)Using wide-space drill sowing of 6-8 cm sowing belts to minimize interplant competition,coupled with moderate density to stimulate deep-root nitrogen uptake.(4)Optimizing the canopy optimization by delayed sowing(mid-October to early-November)combined with density adjustment enhances light interception efficiency.This integrated soil-crop system management demonstrates long-term effectiveness,increasing grain yield,NUE and reducing carbon footprint.These findings provide practical solutions for green and efficient production of winter wheat.展开更多
基金jointly supported by the Key Research and Development Program of Shandong Province,China(LJNY202103 and 2023TZXD086)the National Major Agricultural Science and Technology Project,China(NK202218080315)+1 种基金the Project of Central Government Guiding Local Science and Technology Development,China(YDZX2022130)the Cooperative Promotion Plan of Major Agricultural Technologies of Shandong Province,China(SDNYXTTG-2023-10)。
文摘Integrated agronomic optimization(IAO)adopts suitable crop varieties,sowing dates,planting density,and advanced nutrient management to redesign the entire production system according to the local environment,and it can achieve synergistic improvements in crop yields and resource utilization.However,the intensity and magnitude of the impacts of IAO on soil quality under long-term intensive production and high nitrogen use efficiency(NUE)require further clarification.Based on a 13-year field experiment conducted in Dawenkou,Tai'an,Shadong Province,China,we investigated the effects of four cultivation modes on the grain yield,NUE,and soil aggregate structure,as well as the fraction of organic matter(SOM)and soil quality,reflected by the integrated fertility index(IFI),during the winter wheat maturation periods in 2020–2022.The four cultivation modes were traditional local farming(T1),farmer-based improvement(T2),increased yield regardless of production cost(T3),and integrated soil–crop system management(T4).As the IAO modes,T2 and T4 were characterized by denser planting,reduced nitrogen(N)fertilizer application rates,and delayed sowing compared to T1 and T3,respectively.In this long-term experiment,IAO was found to maintain aggregate stability,increase SOM content(by increasing organic carbon and total nitrogen of the light fraction(LF)and the particulate organic matter fraction(POM)),and improve SOM quality(by increasing the proportions of LF and POM and the ratio of organic carbon to total nitrogen in SOM).Compared to T1,the IFI values of T2,T3,and T4 increased by 10.91,23.38,and 25.55%,and by 17.78,6.41,and 28.94%in the 0–20 and 20–40 cm soil layers,respectively.The grain yield of T4 was 22.52%higher than that of T1,and reached 95.98%of that in T3.Furthermore,the NUE of T4 was 35.61%higher than those of T1 and T3.In conclusion,our results suggest that the IAO mode T4 synergistically increases grain yield and NUE in winter wheat,while maximizing soil quality.
基金supported by the National Basic Research Program of China (2015CB150404)Shandong Province Higher Education Science and Technology Program (J15LF07)Youth Science and Technology Innovation Foundation of Shandong Agricultural University (2014-2)
文摘Lodging resistance of winter wheat(Trnticum aestivum L.) can be increased by late sowing.However, whether grain yield and nitrogen use efficiency(NUE) can be maintained with delayed sowing remains unknown. During the 2013-2014 and 2014-2015 growing seasons, two winter wheat cultivars were sown on three dates(early sowing on October 1, normal so,wing on October8, and late sowing on October 15) to investigate the responses of lodging resistance, grain yield,and NUE to sowing date. No significant differences in lodging resistance, grain yield, or NUE between early and normal sowing were observed. Averaging over the two cultivars and years,postponing the sowing date significantly increased lodging resistance by 53.6% and 49.6%compared with that following early and normal sowing, respectively. Lodging resistance was improved mainly through a reduction in the culm height at the center of gravity and an increase in the tensile strength of the base internode. Late sowing resulted in similar grain yield as well as kernel weight and number of kernels per square meter, compared to early and normal sowing.Averaging over the two cultivars and years, delayed sowing resulted in a reduction in nitrogen uptake efficiency(UPE) by 11.0% and 9.9% compared to early and normal sowing, respectively,owing to reduced root length density and dry matter accumulation before anthesis. An average increase in nitrogen utilization efficiency(UTE) of 12.9% and 11.2% compared to early and normal sowing, respectively, was observed with late sowing owing to a reduction in the grain nitrogen concentration. The increase in UTE offset the reduction in UPE, resulting in equal NUEs among all sowing dates. Thus, sowing later than normal could increase lodging resistance while maintaining grain yield and NUE.
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 National Key Research and Development Program of China(2023YFD2300200)National Major Agricultural Science and Technology Project,China(NK202218080315)+1 种基金Key Research and Development Program of Shandong Province,China(2023TZXD086,LJNY202103,2022LZGC005-402)College Youth Innovation Technology Support Program of Shandong Province,China(2022KJ242).
文摘The development of green technologies for improving winter wheat yield and nitrogen use efficiency(NUE)is crucial for ensuring national food security and reducing carbon footprint.This study outlines China wheat yield progress and establishes a three-stage theory for this.The key constraints from a soil-crop system perspective were identified:population-individual competition,dry matter accumulation and distribution,and soil quality degradation.To address these constraints,an optimized soil-crop system is proposed.(1)Adopting rational dense planting using optimal densities of 330-375 plants m^(-2) for large-spike cultivars and 225-270 plants m^(-2) for medium-spike cultivars to establish robust populations.(2)Enhancing soil quality and reducing carbon footprint by the adoption of straw return combined with a strategy of deep plowing and rotary tillage to improve soil fertility quality,reducing carbon footprint by 1.87 Mg CO_(2) eqv ha^(-1).(3)Using wide-space drill sowing of 6-8 cm sowing belts to minimize interplant competition,coupled with moderate density to stimulate deep-root nitrogen uptake.(4)Optimizing the canopy optimization by delayed sowing(mid-October to early-November)combined with density adjustment enhances light interception efficiency.This integrated soil-crop system management demonstrates long-term effectiveness,increasing grain yield,NUE and reducing carbon footprint.These findings provide practical solutions for green and efficient production of winter wheat.
