植物营养与肥料学报

Optimum combination of planting density and fertilization mode for high yield, quality and nitrogen utilization of spring-sown fresh waxy maize

YAO Xiao-yu, QIU Wen, LU Hu-hua, GUO Jian, LU Da-lei

Accepted Manuscript doi: 10.11674/zwyf.2023220

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Objectives Coordinated plant density and fertilization mode is one of primary conditions for high yield, quality, and fertilization efficiency in crop production. We studied the effects of different plant density and fertilization combinations on spring-sown fresh waxy maize production in Jiangsu Province. Methods Field experiment with split design was conducted in Nantong, Jiangsu province in 2021 and 2022, the test maize cultivar was “Suyunuo 11”, a spring-sown waxy maize hybrid. The main plot was five plant densities, including 4.5×10⁴ (D1), 5.25×10⁴ (D2), 6.0×10⁴ (D3), 6.75×10⁴ (D4), and 7.5×10⁴ per hm² (D5); and the subplots were three fertilization modes under the same total N rate 225 kg/hm², including: basal applying compound fertilizer N 75 kg/hm² and topdressing urea N 150 kg/hm² at six-leaf stage (CF); applying all nitrogen fertilizer as basal fertilizer (SF-b), and as topdressing fertilizer at six-leaf stage (SF-t), using slow-release compound fertilizer; and a no fertilizer control under each density. The plant biomass and N content were investigated at pre- and post-silking stage, and the fresh ear and grain yield, and the grain quality indices were measured at milking stage. Results Under the same fertilization mode, D2, D3, D4, D5 increased the fresh ear yield by 4.14%, 7.48%, 11.68%, and 7.17%, increased grain yield by 6.09%, 7.48%, 12.19%, and 7.08% on average, compared to D1. D4 was recorded significantly higher fresh ear and grain yield, dry matter and N accumulation at pre- and post-silking stage than the other density treatments, thus achieved the largest partial productivity and recovery efficiency of nitrogen fertilizer. The grain starch, soluble sugar and protein contents decreased with the increase of plant density to different extent, and not improved by fertilization modes. Under the same plant density, SF-t was recorded significantly higher fresh ear and grain yields than CK and SF-b, but lower translocation of dry matter and N accumulation from pre-silking to post-silking stage; SF-b was recorded similar or higher fresh ear and grain yields, and dry matter and N translocation rate to CF mode. Among all the total 20 combinations, D4 combined with SF-t showed the highest yield and N use efficiencies, and not worst grain qualities. Conclusions Topdressing all the nitrogen fertilizer in once at 6-leaf stage of maize, using slow release compound fertilizer, could significantly increase the dry matter and nitrogen accumulation at post-silking stage, which is more effective for yield formation than translocating dry mater and N accumulated from pre-silking stage. Properly enhancing plant density plays pivotal roles in exerting population yield potential. Comprehensively, plant density 6.75×10⁴ per hectare combined with one topdressing of N 225 kg/hm² using slow-release fertilizer at six-leaf stage could be taken as the optimal cultivation measure for waxy maize production in Jiangsu.

Effects of natural wetland conversion to farmland on soil organic sulfur forms and arylsulphatase activities in karst areas

CHEN Yun-shuang, SHEN Yu-yi, CAO Yang, WANG Zi-hui, XU Guang-ping, SUN Ying-jie, HUANG Ke-chao, TENG Qiu-mei, MAO Xin-yue

Accepted Manuscript doi: 10.11674/zwyf.2023216

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Objectives Soil organic sulfur forms and arylsulphatase activities are sensitive indicators of changes in soil sulfur pool. We compared the soil organic sulfur forms and arylsulphatase activity characteristics among the land use types derived from the natural wetland, to assess the sustainability of land use types. Methods The study was carried out in the typical Huixian karst wetland in Guilin, Guangxi Zhuang Autonomous Region of China, 6 land use types including the natural marsh wetland and the derived paddy field, upland, orchard, breeding land and abandoned land were selected as research objectives. Soil samples were collected at depths of 0−10, 10−20, 20−30 and 30−40 cm for the analysis of organic sulfur forms and arylsulphatase activities, respectively. Results 1) Compared with the natural marsh wetland, soil total S stocks, the contents of ester bond sulfur, carbon bond sulfur and residual sulfur in the other five land use types showed a decreasing trend with the changes of land use type. The proportion of carbon bonded sulfur to organic sulfur was 39.08%−63.54%, the proportion of ester bonded sulfur to organic sulfur was 22.91%−34.28%, and the proportion of residual sulfur to organic sulfur was 15.19%−28.46%. The proportion of ester bonded sulfur and residual sulfur to total organic sulfur were decreased respectively, and the proportion of carbon bonded sulfur to total organic sulfur was increased(P<0.05). 2) The soil organic sulfur content of the Huixian karst wetland ranged 158−442 mg/kg, and the total sulfur ranged 180-511 mg/kg, total sulfur with an average content of 345.53 mg/kg, which were lower than that of the world soil total sulfur average value. The average organic and total sulfur in the 0−40 cm soil layers of land use types declined in the order of wetland>paddy field>upland>breeding land>orchard>abandoned land, and the differences between wetland and other land types was significant (P<0.05). 3) The arylsulphatase activities decreased with the increasing of soil depth under all the land use types. Compared with the natural marsh wetland, the arylsulphatase activities of the other five land types decreased by 18.19% (paddy field), 27.48% (upland), 39.72% (orchard), 33.81% (breeding land), and 51.77% (abandoned land), respectively. Soil organic carbon, total N, soil water content and arylsulphatase had higher correlation coefficient with soil organic sulfur form (P<0.05). Conclusions The reclamation of natural marsh wetlands led to the decrease of soil total and organic sulfur contents significantly (P<0.05), total sulfur content ranged 98.06−222.87 mg/kg and was less than the average total sulfur content (299 mg/kg) of soil in tilling layer in 10 provinces in Southern China. Soil organic carbon, total N, water content and arylsulphatase are the main factors causing the change of soil organic sulfur forms. Therefore, reducing the reclamation of karst wetland is important to maintain the balance of soil nutrients and ecosystem health of the Huixian karst wetland in the long term.

Mechanism of improving soil potassium balance and supply capacity in peanut-sweet potato rotation system by organic and chemical fertilizer combined application

YUAN Jie, YE Jia-min, WANG Ji-dong, LI Juan, ZHANG Li-cheng, ZHANG Ming-qing, XU Cong, WANG Lei, ZHANG Yong-chun

doi: 10.11674/zwyf.2023186

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Objectives Based on a long-term fertilizer experiment, we analyzed soil potassium (K) apparent balance, the K absorption site in minerals and the desorption dynamics of K as affected by long-term application of chemical fertilizer combined with different organic fertilizers, to clarify the mechanism of the beneficial effect differences of organic fertilizers in improving soil K fertility. Methods The long-term fertilization experiment of peanut-sweet potato rotation system was established in 2007, including five treatments: no fertilization (CK), merely chemical fertilizer (NPK), chemical fertilizer combined with commercial organic fertilizer (NPK+CM), pig manure (NPK+PM), and straw (NPK+RS). At sweet potato harvest in 2022 (the 16^th year of the experiment), the tuber yield and whole biomass were investigated, plants were sampled to analyze K content. The soil K apparent balance was calculated. At the same time, soil samples were collected for analysis of the soil K content in different forms, and adsorbed at different clay mineral sites by using continuous leaching method. The release characteristics of K was studied using organic acid and sodium tetraphene boron as extractants. Results In this peanut-sweet potato rotation system, the annual apparent balance of soil potassium under CK was in deficit, while under the four fertilizer treatments were in surplus. Compared with CK treatment, NPK+PM and NPK+RS increased non-exchangeable K (non-exch- K) by 260 and 188 mg/kg, exchangeable K (exch-K) by 72.3 and 75.0 mg/kg, and water-soluble K (H₂O-K) by 45.0 and 71.7 mg/kg, respectively (P<0.05). The interlayer (i-site), wedge edge (e-site) and surface (p-site) were the three main K adsorption sites. Compared with CK, NPK and NPK+CM treatment did not significantly changed the K adsorption amount and the ratio; NPK+PM and NPK+RS increased the p-site K content by 25 and 36 mg/kg, e-site K content by 58 and 66 mg/kg; NPK+PM treatment increased the i-site K content by 132 mg/kg; NPK+PM increased the K proportion at the e-site, while NPK+RS increased K proportion at p- and e-site but decreased that at i-site. In the K release experiment, NPK and NPK+CM treatment did not impact the rapid and total K release amount and rate regardless extractants; NPK+PM was recorded the highest rapid and total K release amount, which were significantly higher than NPK+RS under organic acid extraction, and had no significant difference from NPK+RS under sodium tetraphene boron extraction. Conclusions The long-term combination of chemical fertilizer with pig manure or rice straw could improve the contents of non-exchangeable, exchangeable and water-soluble K in soil effectively. Chemical fertilizer did not change the ratio of adsorbed K at the main clay sites, while chemical fertilizer combined with pig manure significantly increased the interlayer Kcontent, and chemical fertilizer combined with straw increased that at the wedge edge and mineral surface. Merely applying chemical fertilizer would not affect the bioavailability of soil K, long-term combining application of chemical fertilizer with pig manure or straw could increase the bioavailability of soil K, and the combination of chemical fertilizer with pig manure would be more effective than the combination of chemical fertilizer with straw under soil K deficient condition.

Screening of temperature-sensitive polyurethane materials to enhance the nutrient intelligent release of controlled-release fertilizers

LI Juan, QIAO Dan, WANG Ya-jing, LIN Ru, GU Dian-run, ZHOU Yuan-fang, LI Han, YANG Xiang-dong

doi: 10.11674/zwyf.2023168

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Objectives Temperature is one of the important factors affecting crop growth and nutrient release rate of fertilizer. The nutrient release of temperature-sensitive controlled-release fertilizers could match with the crop nutrient uptake more efficiently. So we screened the temperature-sensitive compounds and studied their coating properties primarily. Methods In this study, 18 different polyols, namely hexanedioicacid-1, 4-butanediol (PBA), polytetramethylene ether diol (PTMG), polycaprolactone diol (PCL) and polyethylene glycol (PEG) with varying molecular weights, were subjected to a one-step reaction with diphenylmethane diisocyanate (MDI) to prepare polyurethane (PU) films. Differential scanning calorimetry (DSC) was employed to assess the phase transition temperature of the films. A thermos-sensitive compound was chosen to prepare TSPU encapsulated urea, and the nutrient release period was tested. Results The release performance of CRU prepared from different polyols descended in order of PTMG > PCL > PBA > PEG. For the same series of CRUs, the controlled-release performance decreased with the increase in the molecular weight of the polyols. DSC testing results indicated that PU films prepared from low molecular weight polyols (below 2000) did not exhibit thermos-sensitivity, but did in the high molecular weight polyols. The critical transition temperatures for PTMG2000, PTMG3000, PCL2000, PBA2000, and PCL3000 were 13℃, 22℃, 27℃, 39℃, and 43℃, respectively. PCL2000 and PCL3000 were selected as thermos-sensitive materials, and mixed with polypropylene glycol (PPG) in molar ratio of 2∶8 to prepare two TSPU-coated urea fertilizers (PUCF1 and PUCF2). Both PUCF1 and PUCF2 showed temperature-dependent nutrient release rates, with daily release rate of 11.1% and 7.1% at 35℃, which was 13.2 and 6.0 times of that at 25℃. The nutrient release period of PUCF1 and PUCF2 was as long as 30 days at 25℃. Conclusions Polyols with high molecular weight exhibit thermos-sensitivity. Modification of them with diphenylmethane diisocyanate could improve the controlled release properties of the films made of the high molecular polyols. Under the experimental condition, the coated urea showed a certain thermos-sensitive characteristics and a controlled release period of up to 30 days. More researches are needed to design temperature-responsive controlled-release fertilizers.

Effects of controlled release mixed nitrogen fertilizer on nitrogen uptake, utilization, and yield of winter wheat

HAN Rui-feng, NIU Yu-xi, WANG Xin-yue, LI Guo-ming, LIN Xiang, WANG Rui, WANG Dong

doi: 10.11674/zwyf.2023141

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Objectives We investigated the effect of the combined application of controlled release urea (CRU) with common urea (CU) on promoting the yield, relocation of accumulated nitrogen to grains, and soil nitrate contents at different stage of winter wheat, to serve the efficient production of winter wheat in the Guanzhong Plain, Shaanxi Province. Methods A winter wheat field experiment was conducted in Xianyang, Shanxi Province from 2020 to 2022, and the nitrogen release period of the test controlled release fertilizer is 90 days. Two N application amounts 192 and 240 kg/hm² were set up, and under each N rate, the conventional urea was applied in base and topdressing as control (F1), and controlled release fertilizer and common urea were completely applied as base fertilizer in mix ratio of 30%+70% (F2), 50% +50% (F3), 70%+30% (F4), and 100%CRU (F5). At the main growth stages of winter wheat, 0−40 cm deep soil samples with one sample every 10 cm were collected for the determination of nitrate concentration, and at maturity stage, 0−200 cm soil samples were collected with one sample every 20 cm from 40−200 cm depth. At the overwintering, regreening, jointing, flowering, and maturing stages of wheat, the above ground part of wheat were sampled for biomass and N content analysis. At flowering stage, the plants were divided into three parts (ear, stem and sheath, and leaves), and at maturing stage were divided into four parts (grains, glume + rachis, stem + sheath, leaves). And yield and yield components were investigated at harvest. Results F2 treatment was recorded the highest NO₃⁻-N concentration in 0−20 cm soil layer before regreening stage; F4 and F5 treatment were recorded the lowest NO₃⁻-N at regreening stage, and in the 80−200 cm soil layer at harvest stage, while achieved significantly higher yield than the other treatments due to the higher number of spikes. F2 and F3 treatments achieved similar yield on average under both N2 and N1 rate. F4 and F5 treatments had higher yield under N2 rate than under N1 rate, thereby their net benefits under N2 increased by 10.08% and 6.41% than under N1 rate, and the nitrogen internal utilization efficiency were not changed significantly. Compared with F1 treatment, F4 treatment showed an average increase of 18.63% in reallocation amount of pre-anthesis N accumulation to grain, and 16.96% in N accumulation in grains. The 0−20 cm soil NO₃⁻-N at jointing stage was positively correlated with the reallocation amount of pre-anthesis N accumulation to grain. There was a significant positive correlation between 0−20 cm soil NO₃⁻-N at anthesis stage and nitrogen transport at pre-anthesis stage and nitrogen accumulation at post-anthesis stage. Conclusions Properly high N accumulation during anthesis stage is beneficial to the reallocation of nitrogen from vegetative organs to grains, and improves winter wheat yield and nitrogen utilization efficiency as result. Complete basal application of N 240 kg/hm² in ratio of 70% resin coated urea with 30% ordinary urea could maintain high nitrate concentration in 0−20 cm soil from regreening to anthesis stage of winter wheat, so promoting the total number of stems and spikelet, increasing the nitrogen accumulation of plants during anthesis period, and leave low NO₃⁻-N in 80−200 cm soil layer at harvest.

Non-destructive monitoring of Cephalotaxus mannii growth status at seedling stage based on canopy images

SHI Meng-meng, WANG Xue-feng, YUAN Ying, CHEN Fei-fei, HUANG Chuan-teng, WANG Peng, CHEN Xing-jing

doi: 10.11674/zwyf.2023182

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Objectives Cephalotaxus mannii is a state key protected plant. The construction of non-destructive growth monitoring method would provide an easy and instant tool for the warning of restricted growth conditions. Methods A pot experiment with L₉ (3⁴) design was conducted in Yunlong Town, Haikou City from 2021 to 2022 , using 1-year-old C. mannii as test materials. The three factors was irrigation rate (W), light transmission (S), and nitrogen rate (N). The large gradients of each factor levels were designed to make Cephalotaxus mannii seedlings grow differently, the irrigation levels were 2500, 5000, and 7500 mL; the light transmission rates were 70%, 40%, and 15%; the three N levels were 0, 5, and 10 mg/plant. Since the seedlings grow for one month, the seedling ground diameter, plant height, canopy length, lateral branch length, leaf chlorophyll content were monitored in frequency of every two months, and total 7 monitors. Based on ANOVA and multiple comparisons, the seedlings with significantly lower indices were defined as being in an unsuitable growth environment (record as 0), otherwise in a suitable environment (record as 1). Three representative seedling were chosen from each treatment for taking canopy images at the initial of monitoring, then the color feature parameters of the images were extracted as independent variables by segmenting the images. A classification model was constructed to diagnose whether the current environment suitable or not suitable for seedling growth. The chlorophyll relative content (SPAD) were estimated by partial least squares regression (PLSR) and stepwise regression (SR) models. Simultaneously, the dummy variables converted by binary classification was added into the model. Results The seedlings of C. mannii grew were impacted significantly by transmission rate and irrigation level, not by nitrogen application rate. The support vector machines (SVM) effectively identified seedlings under the unsuitable environments (the false positive rate was 14%). PLSR and SR models well estimated the SPAD values using image color feature parameters as independent variables, and PLSR model adapted better than SR model in solving the collinearity and dimensionality reduction problems. The conversion of two categorical variables into dummy variables did not improve the prediction accuracy of APSD values under suitable environment, but did that under unsuitable environments. Using this model to invert the SPDA of seedlings under unsuitable environments, the lower leaf tips appeared chlorosis, indicating the reliability of the prediction. Conclusions The growth of Cephalotaxus mannii seedlings is mainly impacted by light and irrigation rate, with significant effects on the lower leaf tips by light and irrigation. The color feature parameters captured from the canopy images are effective in diagnosing the growth status of Cephalotaxus mannii, especially under unsuitable environments like low light and poor irrigation. Additionally, the PLSR with dummy variables model can enhance the predictive ability of SPAD for class 0 samples. Therefore, the method can be used to non-destructive diagnose for the growth environment of Cephalotaxus mannii.

Effects of biostimulants on maize growth and soil microbial community structure

LI Bing-yan, SONG Da-li, WANG Xiu-bin, ZHAO Shi-cheng, ZHOU Wei

doi: 10.11674/zwyf.2023189

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Objectives Five biostimulants were studied on their yield promotion effect and possible influence on soil enzyme activity and microbial community structure, aims to provide academic base for their efficient application. Methods A field trial was conducted in calcareous tidal soil in Yuanyang County, Xinxiang City, Henan Province, China, with maize as the test crop. The tested biostimulants included trehalose, chitosan, humic acid, and γ-aminobutyric acid, all the stimulants were applied into soil in furrow before sowing, and no biostimulant application (CK) was used as control. At the six-leaf stage of maize (jointing stage), plant samples were collected to determine dry matter mass, and 0−20 cm soil layer samples were collected to determine soil enzyme activity and microbial community characteristics. At harvesting stage, maize yield and yield components were investigated. Results The five biostimulants showed different promotion effects on the yield and yield components. Compared with CK, humic acid significantly increased root, shoot and whole plant dry weight by 43.1%, 114% and 101%; all biostimulants did not show effect on grain number per ear; trehalose, chitosan and humic acid increased 1000-grain weight by 5.5%, 4.9% and 8.2%; chitosan and humic acid increased single era weight by 13.6% and 12.5%; humic acid increased yield by 10.2%, while the other biostimulants did not. Compared with CK, trehalose, chitosan, humic acid and γ-aminobutyric acid did not change urease activity significantly, but all increased the alkaline phosphatase activity; trehalose, chitosan and humic acid exhibited similar promotion effect on the dehydrogenase activities (P<0.05); humic acid increased soil microbial biomass by 29.3%, enhanced bacterial, gram-positive and gram-negative bacteria biomass by 43.9%, 48.8% and 40.5%, respectively, without change on the ratio of gram-positive to gram-negative bacteria. Pearson correlation analysis showed that maize yield was positively (P<0.05) correlated with soil microorganisms, bacteria, gram-positive bacteria, and the dry matter of root, shoot and whole plant (P<0.05), not significantly correlated with soil enzyme activity. Conclusions Trehalose, chitosan, humic acid, and γ-aminobutyric acid all showed promotion effect on the maize yield and yield components to different degree, humic acid showed the best promotion effect on the dry matter quality of maize roots and shoots, well as yield, because its wide promotion effect on the biomass of soil microorganisms, bacteria, gram-positive and gram-negative bacteria, and the soil alkaline phosphatase and dehydrogenase activities, so humic acid is the most prospective biostimulant in agricultural productin.

Non-synchronous response of rhizospheric and endophytic bacteria of corn to continuous cropping

FU Wen-jiang, ZHAO Yun-chen

doi: 10.11674/zwyf.2023149

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Objectives To explore the structure and function of bacterial communities in the rhizosphere and root of corn with different continuous cropping years, as well as the response mechanism of bacteria in the rhizosphere and root to continuous cropping effects. Methods Soil physicochemical properties were determined in seed production maize fields with different years of continuous cropping (1, 5 and 15 years), and high-throughput sequencing technology was used to analyze the changes in bacterial diversity, community composition characteristics, and community function in the rhizosphere and root of corn. Results Compared to 1 year, the soil bulk density, total phosphorus, total nitrogen, available phosphorus, available nitrogen, and pH significantly increased after 5 and 15 years cropping, while the total porosity, available potassium, and organic matter content significantly decreased (P<0.05). The composition of rhizospheric and endophytic bacterial community of corn changed, and the diversity and network complexity of bacterial community decreased with the increasing of continuous cropping years. The relative abundance of Acidobacteria, Proteobacteria, Bacteroidetes, Planctomycetes and Gemmatinonadota decreased in rhizosphere soil, while the relative abundance of Chloroflexi and Actinobacteriota increased. The relative abundance of beneficial Nitrospira, Sphingomonas, Lysobacter, Haliangium and Bryobacter decreased in rhizosphere soil. The relative abundance of inner phylum of Proteobacteria increased, while the relative abundance of Firmicutes, Bacteroidetes and actinomycetes decreased. The relative abundance of inner beneficial genera of Pseudomonas, Sphingomonas, Flavobacterium, Rhizobium and Pantoea decreased. In addition, the relative abundance of rhizospheric bacterial biosynthesis of antibiotics, amino acid biosynthesis, fatty acid synthesis, C5-branched dibasic acid metabolism, lipoic acid metabolism, pantothenate and CoA biosynthesis, peptidoglycan biosynthesis, D-alanine metabolism, lipopolysaccharide biosynthesis, cell cycle – caulobacter, and sulfur relay systems decreased with increasing years of continuous cropping. There was an overall decrease in the relative abundance of amino acid biosynthesis, pantothenic acid biosynthesis, biosynthesis of vancomycins, pantothenate and CoA biosynthesis, peptidoglycan biosynthesis, streptomycin biosynthesis, lipoate biosynthesis, alanine and glutamate metabolism within the root of corn, and an overall increase in relative abundance of biosynthesis of anisamycins, synthesis and degradation of ketone bodies, bacterial chemotaxis, and C5-branched dibasic acid metabolism. Conclusions Soil nitrogen and phosphorus content and bulk density and pH significantly increased with the increase of cropping years, while total porosity, organic matter and available potassium content significantly decreased in corn seed production. The composition and function of bacterial communities in the rhizosphere and root of corn were affected, and rhizospheric and endophytic bacterial diversity, complexity and function decreased. And rhizospheric bacterial communities were more variable than endophytic bacteria.

Effects of exogenous carbon addition on the effectiveness of phosphorus under two soil phosphorus levels

XU Da-jian, YANG Kai, MENG Peng-fei, LANG Ming, GUO Tao

doi: 10.11674/zwyf.2023130

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Objective Addition of exogenous carbon could promote phosphorus effectiveness and thereby unlock the phosphorus supply potential of the soil. We studied the mechanism from the changes in soil microbial community structure and function driven by the carbon addition. Methods Indoor incubation method was used, glucose was used as the exogenous carbon source, and the low and high P soils were collected from the maize and vegetable fields in Beibei District, Chongqing City. Each soil was divided into two groups, one group was added with glucose and the other was not, then incubated under shading condition at 60% of field water capacity. Soil samples were collected after 0, 2, 15, and 60 days of incubation, BBP phosphorus fractionation method, Olsen method, and ignition method were employed to measure different forms of phosphorus contents, and high-throughput sequencing of 16S rRNA was used to analyze the microbial community structures. Results The soil Olsen-P contents in glucose addition soil groups decreased after 2 and 15 days of incubation, then recovered to the original levels. Among the fractions by BBP method, CaCl₂-P, Enzyme-P, HCl-P, and Citrate-P content did not show obvious change during and at the end of incubation in low-P soils, regardless of glucose addition; the CaCl₂-P and Citrate-P contents in high-P soils were significantly decreased by glucose addition, while the Enzyme-P and HCl-P content did not show significant differences compared with the controls. Analysis of microbial community structure revealed that the bacterial community responded more strongly to glucose in low-P soil than in high-P soil. Glucose addition increased bacterial α-diversity in the low-P soil, leading to clear separation of bacteria communities from the control group on the PC1 axis in the PCoA plot. However, glucose addition did not cause significant separation in high-P soil. Results of the co-occurrence network analysis displayed a significant difference in the abundance of OTUs and a more pronounced modular pattern in the low-P soil after glucose addition compared to the control group. The species Paraburkholderia, which had been shown in related studies to possess phosphorus solubilization function, was the most explanatory species for the differences between the treatment and control groups in terms of sample processing. In contrast, no microorganism with proven phosphorus solubilization function was observed in the high-P soil after glucose addition. The plspm model results demonstrated that the addition of glucose induced changes in microbial community structure in soils with two phosphorus levels, resulting in differences in the changes of different phosphorus fractions. Conclusion The effect of exogenous carbon addition on phosphorus pool and bacteria community structure is more pronounced in low-P soil compared to high-P soil. Glucose addition causes greater fluctuations of P pools, increases the species richness and compositional differences of the microbial communities, enriches the known P soluble bacteria Paraburkholderia in low-P soil, resulting better effect in stimulate the bioavailability of soil P.

Effects of field-aged biochar on soil organic nitrogen fractions in dry farmland of Loess Plateau

PAN Zhan-dong, CAI Xue-mei, CAI Li-qun, DONG Bo, WU Jun, ZHANG Ren-zhi

Accepted Manuscript doi: 10.11674/zwyf.2023195

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Objectives The effects of field-aged biochar on soil organic nitrogen components and microbial biomass carbon and nitrogen were studied to provide scientific basis for improving soil fertility and improving nitrogen use efficiency in the Loess Plateau of central Gansu. Methods Based on the long-term positioning experiment of dry farming comprehensive experimental station of Gansu Agricultural University in 2015, six levels of corn straw biochar addition (CK: 0 t/hm², BC1: 10 t/hm², BC2: 20 t/hm², BC3: 30 t/hm², BC4: 40 t/hm², BC5: 50 t/hm²) were set up, and wheat was continuously planted for 5 years. The contents of soil organic nitrogen components and microbial biomass carbon and nitrogen in 0−5 cm, 5−10 cm and 10−30 cm soil layers were determined by Bremner method, and the changes of soil organic nitrogen components and microbial biomass carbon and nitrogen under aged biochar treatment were analyzed. Results Biochar treatment significantly increased the yield of spring wheat, and the yield of spring wheat treated with BC3 was the highest, which was 24.76% higher than that of CK. Compared with CK, biochar treatments significantly increased the soil total nitrogen and microbial biomass carbon by 6.55%−10.94% and 68.63%−139.74%, and microbial biomass carbon and nitrogen ratio (B_C/B_N) increased by 10.60%−202.44%, respectively. Organic nitrogen components: the proportion of AAN, non-acidolysable nitrogen (AIN), acidolysable ammonia nitrogen (AMN), unknown-acidolyzable nitrogen (UAN), amino sugar nitrogen (ASN) accounting for 27.46%−45.13%, 15.47%−31.14%, 19.00%−28.66%, 1.59%−18.54%, 2.76%−8.86% of soil total nitrogen, respectively. In acid hydrolysis nitrogen, biochar treatment showed: AAN>AMN>ASN; compared with CK, soil AAN and ASN contents in BC2, BC3, BC4 and BC5 treatments were significantly increased by 17.58%−81.51% and 43.60%−107.55%, respectively. Compared with CK, soil AMN content in BC2 and BC3 treatments was significantly increased by 15.46%−28.95%. Among them, under BC3 treatment, the content of total acid-hydrolyzed nitrogen, AMN and ASN was the highest, and the content of AIN was the lowest. Conclusions Soil total nitrogen and microbial biomass carbon are the main factors affecting the difference of organic nitrogen components. The tested biochar rate all significantly increased the soil total N and microbiomass carbon. Application of biochar 30 t/hm² showed significantly higher effect on increasing the total soil acidolyzable nitrogen, amino acid nitrogen, and ammonium nitrogen, thus the soil under this biochar rate had the highest nitrogen supply capacity, and achieved the highest spring wheat yield. Therefore, suitable biochar application amount could increase the soil nitrogen supply capacity in the long-run in Loess Plateau.

Innovation and industrial development of green efficiency fertilizers in China

ZHAO Bing-qiang, YUAN Liang

Accepted Manuscript doi: 10.11674/zwyf.2023221

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Green efficiency fertilizers are characterized of controlled nutrient supply, higher nutrient-sue efficiency, and low risk of environmental pollution, represent one of the development trends in global fertilizer industry. The research and development of green efficiency fertilizer in China started in 1970s and 1980s, and over more than 40 years of rapid development, the green efficiency fertilizer have realized industrialized production. The annual output of green efficiency fertilizers have reached 20 million tons, and applied in more than 500 million mu (33 million hectare) of farmland, increasing 10 billion kilograms of crop yield and saving 2 million tons of fertilizers. The green efficiency fertilizers in China are divided into four categories, according to their yield and nutrient efficiency promotion paths. The slow-release fertilizer by controlling nutrient release through coating technology; the stabilized fertilizer by addition of urease inhibitors and/or nitrification inhibitors to regulate urea/N transformation; the urea formaldehyde fertilizer by addition/condensation reaction to form UF slow-release fertilizers to slow down the hydrolysis of urea in soil; and the value-added fertilizer in which bioactive organic synergists were added to comprehensively coordinate the nutrient supply and absorption in the “fertilizer-crop-soil” system. The green efficient fertilizer research and production in the near future should focus on the following aspects: 1) Increase yield with equal and/less nutrient input, or maintain yield with less nutrient input. 2) Integrated yield increase function through harmonious “fertilizer-crop-soil” system, especially stimulate the root absorption ability. 3) Fertilizers with multiple beneficial functions in crop quality, resistance to stress, conservation and remediation of soil. 4) Research and usage of degradable natural/plant-sourced materials with characteristics of bioactivity, safe to humane and environment. 5) Increasing fertilizer efficiencies through the cross amalgamation of multiple disciplines, in multiple ways and mechanisms. 6) Trying to realize the simultaneous production of green efficiency fertilizers with common fertilizers device, to achieve high production capacity in low cost, avoiding the second procession. 7) Meeting the requirement of nutrient supply and simplified fertilization and mechanic operation at the same time.

Study of nitrogen fertilizer management and cultivation strategies in different rice planting areas of the Yangtze River Basin of China

XIAO Da-kang, DING Zi-juan, HU Ren, SHAO Di, MA Xiao-wei, LI Jin-tao, HOU Jun, ZHANG Wei-feng

doi: 10.11674/zwyf.2023160

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Objectives Nitrogen (N) fertilization plays important roles in yield and efficiency of rice production. We studied the suitable N management for different planting areas, rice varieties, and cultivation methods, etc., for the efficient rice production in the Yangtze River Basin, China. Methods Literatures were searched in CNKI and Web of Sciences, using key words N application rate, sum of base and tillering N fertilizer (BTN rate), planting area, rice variety, cropping system, transplanting density, soil property, etc. There were total of 56 published papers meet the requirement of N, and a total of 956 sets of qualified data were screened out from the field experiments of the papers. Meta-analysis was used to quantitatively analyze the effects of N fertilizer management on N uptake, aboveground dry matter weight (ADMW), and yield of rice under different N application rates, basal+tiller fertilizer rates (sum of basal and tiller fertilizers), planting areas, varieties, planting modes, transplanting densities, and soil properties. Results BOth the N uptake and ADMW of rice would not stop increasing with the enhancement of N fertilizer rate until the total N rate and the basal+tiller fertilizer rate beyond 300 and 180 kg/hm², when they were higher than 250 kg/hm² and 120 kg/hm², there was no significant yield increase. The grain yield increase caused by N fertilizer in the upper reaches of the Yangtze River Basin was 24.9%, significantly lower than those in the middle reaches (42.4%) and lower reaches (41.8%) of rice planting areas. Although there was no significant difference among rice varieties, hybrid rice varieties had an advantage in increasing N uptake and rice yield compared to japonica and indica rice, with an increase of 12.6%−15.2% and 3.5%−5.1%. N fertilizer significantly improved less N uptake, ADMW, and yield of single cropping rice compared to double cropping rice and rice -upland rotation. For example, the yield of single cropping rice was increased by 29.1%, while the yield of double cropping rice and rice-upland rotation were increased by 46.3% and 43.8%, respectively. When the transplanting density was controlled within 10⁶/hm², increasing the transplanting density could effectively improve the N uptake and ABDW of rice. Under high soil organic matter (>25 g/kg) and available P (>20 mg/kg), and low available N (<90 mg/kg) and potassium in soil (<80 mg/kg), rice yield responded the highest to N fertilizer, with rice yield increase ofv43.3%−48.5%, the total contribution rates of SOM, AP, AN, and AK to rice yield and nitrogen uptake reached 61.7% and 40.2%, respectively. N dry matter production efficiency, rice production efficiency, and harvest index all decreased when N rate exceeded 250 kg/hm², while N absorption use efficiency, agronomic use efficiency, and partial productivity all decreased with increasing nitrogen application rate. Conclusions Increasing the application of nitrogen fertilizer in the Yangtze River Basin can effectively improve rice yield. To decrease the risk of yield reduction and increase N use efficiency, the total N input should not exceed 250 kg/hm², the sum of base and tillering N should controlled within 120 kg/hm², and the gap with the total N input could be top dressed as ear fertilizer. In the upstream of the Yangtze River Basin, hybrid rice is preferred as the good variety advantages. Under single cropping system, the rice cultivars with long growth period should be chosen to reduce their dependence on N fertilizer. Double rice cropping or rice-upland rotation system is beneficial for improving soil fertility and achieving the goals of reducing N, increasing yield and N use efficiency. In the double rice cropping or rice-upland rotation system of the middle and lower reaches, reasonable increase of transplant density (< 10⁶/hm²) can further improve rice yield and N use efficiency.

Returning green manure to increase tobacco quality and soil fertility in the erosion area of Fuxian Lake in Yunnan Province

FENG Yu, CHEN Hua, FU Li-bo3, ZHOU Guo-peng, YIN Mei, WANG Zhi-yuan, CHEN Jian-feng, WANG Wei, YANG Yan-xian, CAO Wei-dong, LI Yong-mei

doi: 10.11674/zwyf.2023155

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Objectives Effects of planting and utilizing green manure on soil nutrients, yield, and quality of tobacco in the erosion area of Fuxian Lake in Yunnan, were studied to clarify the resources of suitable local green manure varieties, which provided reference for optimizing the local tobacco planting system. Methods The field experiment was conducted from 2019 to 2021, with four treatments: winter fallow, rape (Brassica campestris), common vetch (Vicia sativa L.), and smooth vetch (Vicia villosa Roth var. glabrescens). We measured the following indicators: soil properties after returning green manure to the field and harvesting flue-cured tobacco, agronomic traits of tobacco plants, yield of tobacco, proportion of top grade tobacco, chemical composition of tobacco leaves, appearance and sensory quality, and output value. Results In 2020, there was no significant difference in soil organic matter content before tobacco planting compared to winter fallow. The available nutrients, including alkali hydrolyzed nitrogen (AN), available phosphorus (AP) and available potassium (AK) slightly decreased. After tobacco harvest, soil organic matter increased by 3.2 g/kg, and the average available nutrients increased by 6.8 mg/kg, 10.1 mg/kg, and 84.8 mg/kg, respectively. The treatment of smooth vetch had the greatest increase in available nutrients. In 2021, both before and after tobacco planting and harvest, soil organic matter and available nutrient content of green manure treatment was significantly increased compared to winter fallow. Among them, soil organic matter content of rape treatment was the highest, and the available nutrient improvement effect of smooth vetch treatment was the best. The soil chlorine content in the winter fallow treatment was significantly higher than that in the green manure treatment. In 2020 and 2021, the average yield of tobacco treated with green manure increased by 13.8% and 22.6%, respectively, and the proportion of top grade tobacco increased by 11.2% and 24.7%, with the highest increase in yield observed in the treatment of smooth vetch. In 2021, the agronomic traits of tobacco were significantly improved, with the treatment of smooth vetch performing the best. Comparing to winter fallow, the plant height, stem girth, and maximum leaf width were increased by 26.6 cm, 2.2 cm, and 6.9 cm, respectively. The appearance quality of the middle and upper leaves of tobacco was improved by 5.0−5.7 points and 4.5−5.8 points respectively compared to winter fallow, and the sensory quality increased by 2.0−3.2 points and 3.6−4.2 points, respectively, with the highest score obtained from the treatment of smooth vetch. The average price of tobacco treated with green manure significantly increased by 7.4%−11.9% in the second year, and the output value significantly increased by 30.5%−38.0%. Among them, the economic benefits of the treatment of smooth vetch were the best. Retuning green manure reduced the difference in total sugar and reducing sugar content in tobacco leaves, and increased their potassium content. Random forest regression analysis showed that soil organic matter, chloride ion and available potassium content, as well as plant height, maximum leaf width and stem circumference of flue-cured tobacco were the key indicators affecting the yield of flue-cured tobacco. Conclusions Green manure and tobacco rotation can improve soil nutrient properties, and the effect is more significant in the second year. It can improve the proportion of high-quality tobacco and the quality of tobacco, significantly improving economic benefits. Overall, smooth vetch ( Vicia villosa Roth var. glabrescens ) can be the preferred green manure variety for tobacco rotation in the erosion area of Fuxian Lake in Yunnan Province.

Mechanism, influencing factors and practical application of organic acids in improving soil phytate bioavailability

CAO Xing–yuan, AI Wen–yan, WEN Si–ying, YANG Xiao–li, LIU Xue

doi: 10.11674/zwyf.2023134

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Phytate in soils mainly origins from plant residues and monogastric animal excrement. The phytate can only be mineralized to release P through hydrolysis and dephosphorylation, which are catalysed by specific enzymes-phytase (myo-inositol hexakisphate phosphohydrolase). Phytic acids or phytate, are important components of soil organic phosphorus, accounting for 50%–80% of total organic P. Phytic acids contain 6 phosphate groups and 12 dissociable protons, thus readily being adsorbed by soils or form insoluble complexes with metal ions. Consequently, phytic acids are prevented from interactions with phytase, their decomposition and mineralization efficiency are thus decreased greatly, hard to release P for plant uptake. Improving the solubility and bioavailability of phytate is one of the prerequisites to ensure the efficient P supply of soil to crops. Soil organic acids are derived from plant root excretes, microorganisms, and organic matter decomposition. Organic acids have plenty of functional groups, which can form more stable ligand complexes with metal ions, therefore, mobilize the adsorbed phytate or phytate-metal complexes through competitive adsorption, complexation, and fracturing organic matter-metal bridges. The kinds and contents of soil organic acids varied, depending on plant and microbe species. Besides, soil pH, organic matter content, the types and contents of soil minerals/metal oxides all influence the mobilization efficiency of organic acids-mediated phytate. As such, further studies should work on the following points: 1) Phytate mobilization efficiency of different organic acids in different types of soils. Quantitatively analyze phytate desorption and mobilization efficiency by different kinds and concentrations of organic acids; 2) Phytate-adsorped mineral surface is highly negative charged in a large pH ranges, which hinders the adsorption and displacement reactions of organic acids. Therefore, it is necessary to explore strategies to improve the mobilization of adsorbed-phytate; 3) Monitoring and evaluate the long-term performance of organic acids-mediated phytate mobilization.

Current situation and reduction potential of potato fertilization in China

WANG Xi-ya, SHENG Yin-sheng, HE Ping, XU Xin-peng, QU Xiao-jing, ZHOU Wei

doi: 10.11674/zwyf.2023137

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Objective Reasonable fertilization is required for the high yield, quality and profit of potato production. We investigated the fertilization situation of the main potato production areas around China, and the localized potential of fertilizer reduction. Methods A total of 1807 potato fields in the main potato producing areas were surveyed during 2019−2021 in China. The questionnaire included potato yield, fertilizer sources and ratios of nitrogen (N), phosphorus (P) and potassium (K) fertilizers, and the frequency of basal dressing and topdressing. The fertilizer nutrient reduction potential was evaluated using the fertilizer recommendation rate produced by Nutrient Expert (NE) system. Results On average across China, the annual total N, P₂O₅ and K₂O input for potato was 252, 219, and 224 kg/hm², respectively. N 187 kg/hm², P₂O₅ 164 kg/hm² and K₂O 175 kg/hm² were from chemical fertilizer, and the left from organic fertilizer. The organic nutrients accounted for 25.8%, 25.6%, and 21.4% of the total N, P₂O₅ and K₂O inputs. Compound fertilizer was the main chemical fertilizer source in the surveyed potato fields, supplied 84.6%, 95.7% and 92.8% of chemical N, P₂O₅ and K₂O nutrients. And 82.9% of organic fertilizer was from livestock and poultry manure. Compared with the fertilizer rate recommended by NE system, the fertilizer nutrient reduction potential across China was about 41.9%, of which the N, P₂O₅, and K₂O reduction potential in the monocropping area of North China were 24.1%, 59.7%, and 42.1%; the P₂O₅ and K₂O reduction potential in the monocropping area of Northeast China were 56.0%, and 44.8%, respectively; the N, P₂O₅, and K₂O reduction potential in the monocropping area of Northwest China were 30.6%, 69.2%, and 35.8%, respectively. The reduction potential of N, P₂O₅, and K₂O were 5.5%, 55.0%, and 37.2% in the mono/two cropping area of Southwest China, and 40.2%, 78.2%, and 70.4% in winter season area of South China, respectively. Conclusion The nutrient inputs in potato is generally high and unreasonable in nutrient ratios, particularly the low proportion of organic fertilizer nutrients. The promotion of the Nutrient Expert recommendation will save 41.9% of current fertilizer nutrient input in China, the reduction rate of N, P₂O₅, and K₂O nutrient is dependent on the cropping system, production areas, and fertilization method.

Using DNDC model to study the potential of nitrogen fertilizer reduction in spring maize production under long-term straw return

LI Xiao, JIANG Rong, HOU Yun-peng, HE Ping, ZOU Guo-yuan, XU Xin-peng, FAN Dai-jia, HE Xin, HE Wen-tian

Accepted Manuscript doi: 10.11674/zwyf.2023126

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Objectives This study focused on the potential of nitrogen fertilizer reduction as affected by straw return, aiming to provide a theoretical basis for efficient nutrient management in spring maize production of Northeast China. Methods A split plot experiment was carried out in Gongzhuling City, Jilin Province from 2017 to 2020. The treatments were under conditions of straw return and removal, nitrogen (N) fertilizer was applied at 6 rates, as: 0, 70, 140, 210, 280 and 350 kg/hm², respectively. The denitrification-decomposition model (DNDC) was calibrated and validated based on the field experimental measurements, then used to simulate the impact of straw return and removal on maize yield and N use efficiency, and predict the potential of N fertilizer reduction over a 30-year period (1991−2020). Results The calibrated DNDC model well simulated the spring maize yield, biomass, N uptake, and soil inorganic N content of the treatments, the normalized mean relative errors (nARE) averaged −5.7%−7.6% and the normalized root mean square errors (nRMSE) averaged 10.0%−28.5%. According to the simulations, long-term straw return increased the maize yield, N recovery efficiency, agronomic efficiency, and partial productivity of N under the maximum yield N rate by 6.0%, 5.5%, 2.7 kg/kg, and 6.7 kg/kg, respectively, and decreased N surplus rate by 36.3%, relative to those of straw removal. Straw returns reduced N fertilizer requirement by 35.5 kg/hm² (18.4%) to reach the maximum yield under straw removal. Compared to the N input under straw removal from 1991 to 2020, the N fertilizer reduction potential by straw return first increased and then decreased to a plateau level. The average reduction potential was as high as 23.6% during 7th−15th years, and then declined to 15.8% during 19th−30th years of straw return. The annual precipitation influenced the reduction potential of straw return, the average reduction potential was 20.5% in wet years, 18.7% in normal years, and 15.4% in dry years. Conclusions Long-term straw return increases the maize yield and N use efficiency, decreases the N fertilizer input and N surplus significantly. According to the DNDC model simulations, the relatively steady N fertilizer reduction rate by straw return is 10%−20%, depending on the annual precipitation in the spring maize area of Northeast China.

Rhizosphere management technology at the core of starter P fertilizer and ammonium sulfate topdressing increases lint yield and P efficiency in cotton production under mulched fertigation system

PENG Yi, WEI Xin, XU Jian-hui, YANG Guo-jiang, FENG Gu

Accepted Manuscript doi: 10.11674/zwyf.2023187

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Objective Excessive phosphorus (P) fertilizer application are common in the cotton production of Xinjiang, decreasing low P efficiencies and low benefit of cotton production. We established a rhizosphere management technology to reduce the P fertilizer input and maintain the high yield of cotton at the same time. Methods Field experiments were employed in five cotton (Gossypium hirsutum) production regions of Xinjiang, including Shihezi, Changji, 184 tuan, Beiwucha, and Liuhudi. The P inputs in the five regions are all far exceeded the recommendation. Two treatments were set up in all the five experimental sites: conventional fertilizer practice control (CK), and rhizosphere management (RM). The core of the RM was reducing total P input through applying P and ammonium sulfate (AS) before germination of cotton as starter fertilizer, and topdressing AS with drip irrigation at cotton bud and boll stage to induce rhizosphere acidification. The lint yield, and biomass of the organs were weighed at harvest, the N and P contents in the organs were analyzed, and the partial productivity of N (PFPn) and P (PFPp) fertilizer, P surplus and earnings were calculated, respectively. Results The RM treatments were recorded similar lint yields (3.26 t/hm²) as CK (3.29 t/hm²), without significant impaction on the aboveground biomass distribution, N and P uptake, and seed cotton P content, thereby increased PFPp by 81%. RM treatment reduced P surplus by 75% on average, the P surplus was as low as 3.6 kg/hm² under RM treatment in experimental site CJ where no basal P fertilizer. At the target lint yield level of 3.1～3.5 t/hm², RM treatment reduced 16.6% of N and 56.5% of P fertilizer input, thus decreased N and P fertilizer cost by 40.7%, saving 2082 ¥/hm², and improved net income by 1845 ¥/hm². In the high fertilizer input sites BWC and LHD, the RM treatment reduced N and P fertilizer cost by 3993, 4464 ¥/hm², and improved net income by 2931, 4367 ¥/hm². Conclusions The rhizosphere management technology reduced the total P application amount while kept the same high cotton lint yield, so increased the P fertilizer efficiency and decreased P surplus greatly. The cotton net profit was increased significantly as the decrease of fertilizer cost. So, the rhizosphere management technology is recommended in the nutrient management of cotton production.

Yield difference and growth adaptation characteristics of maize varieties under strip tillage with straw mulching

SHA Ye, ZHAO Si-yu, GUO Wen-qing, LIU Zheng, HAO Zhan-hong, KE Li-hua, HUANG Yi-wen, FENG Guo-zhong, MI Guo-hua

doi: 10.11674/zwyf.2023144

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Objectives Straw mulching combined with strip tillage (“strip tillage”) has been promoted as an effective measurement for black soil protection in Northeast China. In regarding to the exaggerated soil temperature heterogeneity, the adaptability of maize varieties was evaluated, for maintaining maize yield at the same time of soil protection. Methods The field experiment with split design was conducted in Lishu County, Jilin Province in 2020 and 2021. The main factor was two tillage methods under straw mulching: strip tillage (ST) and conventional tillage (CT); and the sub-factor was 10 maize varieties. The soil temperature of intra- and inter-rows, and the emergence time and rate were monitored, the periodical dry matter accumulation, yield and yield components of maize were investigated. The relative change of indices of maize varieties under ST was calculated using equation (ST–CT)/CT for the adaptive assessment and classification of maize varieties, and their growth dynamics were fitted with logistic equation. Results Compared with CT, ST treatment decreased soil temperature until 50–70 days after sowing in 2021 and 2022, with the total decrease of cumulative temperature by 305℃ and 107℃ in the intra-rows, and 450℃ and 355℃ in the inter-rows; postponed the emergence time of maize but did not affect the final emergence rate. The yield and yield components of maize varieties responded to the tillage methods differently. Compared to CT, the variety Zhengdan 958, Dika M753, and Dika M751 under ST treatment increased yield by 8.4%, 3.5%, and 2.1%, ranking strong adaptability varieties; Dika 517, Liangyu 99, Fumin 58, Hongshuo 899, and Tieyan 58 reduced average yields by 6.6%, 6.0%, 3.3%, 1.5%, and 0.7%, ranking weak adaptability varieties; the left two ranked moderate adaptability varieties. From the analysis of yield components, the ear number per unit area, the grain number per ear, and the 100-grain weight of high adaptability varieties increased by 1.2%, 4.3%, and 0.5%, respectively, the moderate adaptability varieties decreased by 0.0%, 1.1%, and 2.4%, respectively; and the weak adaptability varieties decreased by 1.7%, 3.9%, and 0.0%, respectively. The analysis of the Logistic growth fitting curve showed that, ST treatment reduced the growth rate of maize from V1 to V14 stage, accelerated the growth rate from V14 to R3 stage, exhibiting the “compensatory growth ability”, which was stronger in high adaptability varieties than the other varieties. The plant average growth rate during the rapid growth period under ST treatment was 6.1% higher than under CT, and the average grain number per ear was 4.3% higher. The correlation analysis showed that the grain yield was significantly positively correlated with the grain number per ear (r=0.65–0.66), the shoot dry weight at maturity (r=0.57–0.80), V1 (r=0.72–0.84), V2 (r=0.69–0.83) (P<0.05). Conclusion The main maize varieties are different in the adaptability to strip tillage. Although the low temperature and late emergence caused by strip tillage, the highly adaptive varieties have stronger "compensatory growth ability" in the rapid growth period, which improves the dry matter accumulation rate in the key growth period before silking stage, promotes the formation of grain number per ear, and finally achieves higher yield.

Plastic film and straw mulching improve yield and nitrogen use efficiency of spring maize

XU Zi-hang, WANG Rui, LIU Yu-wang, QIU Zi-jian, LIU Li-xia, LIU Xiao-lin, BAI Ju, WANG Yong-liang

doi: 10.11674/zwyf.2023145

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Objectives Water and fertilizer use efficiencies of spring maize production system are low in the valley plains of eastern Loess Plateau. For this reason, we studied the effects of different surface mulching measures on yield, nitrogen translocation efficiency, nitrogen use efficiency and economic benefit of spring maize, in order to provide scientific management measures for high yield and high efficiency of spring maize production in this region. Methods The study was based on a long-term experiment started in 2014 in the Dongyang Experimental Demonstration Base of Shanxi Agricultural University in Jinzhong City, Shanxi Province, with the tested maize cultivar ‘Dafeng 30’. Four treatments included fertilization without mulching (NM), with plastic film mulching (FM), and with straw mulching (SM), and control without mulching and fertilization (CK). In 2021 and 2022, the photosynthetic characteristics, dry matter and nitrogen accumulation of spring maize were measured at different growth stages, and the grain yield, and economic benefit were investigated at harvest. Results Compared to NM treatment, FM treatment improved the chlorophyll content, leaf area index, and effective light interception of spring maize at pre-silking periods, but significantly reduced those at the post-silking periods. Lodging rate was recorded more than 70% in FM treatment in 2021, 45.41% lower shoot N accumulation at post-silking periods, impacting the yield formation. SM treatment improved the chlorophyll content, leaf area index, and effective light interception across the growing period of maize, thus increased the dry matter and N accumulation at pre-silking periods, and increased the N uptake and nitrogen use efficiency of maize. Compared with NM treatment, FM and SM treatment increased grain yield by 6.18%−15.26%; FM treatment significantly increased the shoot N uptake, N recovery efficiency, agronomy efficiency and partial factor productivity by 21.84%, 31.59%, 28.86%, and 16.18% in 2022; SM treatment increased the shoot N uptake, N recovery efficiency, agronomy efficiency and partial factor productivity by 13.86%, 18.48%, 19.21% and 12.14% in 2021, and 25.54%, 36.92%, 33.86% and 18.99% in 2022, respectively. Compared with FM, SM treatment increased grain N uptake by 27.89% and 9.25% in 2021 and 2022, the grain N uptake and N recovery efficiency by 18.57% and 15.58%, and increased yield and economic benefit by 8.55% and 12.48%, respectively. Conclusion Straw mulching is better than plastic film mulching in coordinate the growth of pre- and post-silking stage, decreasing lodging rate, and improving nitrogen use efficiency, so resulting in higher yield and economic benefit of spring maize. In addition, straw can provide additional nitrogen for soil, and has no risk of micro-plastics pollution. Therefore, straw mulching should be used to replace plastic film for the efficient utilization of water and fertilizer in the spring maize production in the valley plain of eastern Loess Plateau.

Effects of nitrogen application methods on the growth and root development of Cinnamomum kanehirae seedlings

WANG Xian-bang, ZHOU Zai-zhi, HAN Qiang, PAN Dong-kang, WANG Dan-wei, HUANG Gui-hua

Accepted Manuscript doi: 10.11674/zwyf.2023213

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Objectives The quality of seedlings decides the rate of survivals during afforestation to some extent. We studied the suitable fertilization method and nitrogen fertilizer amount for the health Cinnamomum kanehirae seedlings. Methods A pot experiment was carried out inside green hours, taking 1-year old tissue culture seedlings of Cinnamomum kanehirae as test materials. The fertilizer treatment included two conventional methods at N rate of 200 mg/plant, i.e. averaged applied in two time, and in 10 time (denoted as CF1 and CF2); and 4 exponential fertilization methods with N rate of 200, 400, 600, and 800 mg/seedling (denoted as EF200, EF400, EF600 and EF800); and a no fertilizer control (CK). The nitrogen fertilizer was applied in 10 time, and the N amount of each application was calculated using classic Timmer formula. The seedling and root growth and development indexes, as well as nutrient absorption were measured after the fertilization as completed. Results Fertilization significantly improved the growth and development of seedlings. Compared with CF1 and CF2, EF200 treatment increased seedling height, ground diameter, biomass (stem and leaf), root system (length, volume, surface area, specific root length and specific root surface area), and N content of leaf, stem and root significantly. Under exponential fertilization, the biomass, and N content of leaves, stems and roots showed a trend of first increase and then decrease with the increase of N application rate, and EF400 was recorded the maximum and significantly higher values than the other treatments. Conclusions Nitrogen application has significant effect on the growth of Cinnamomum kanehirae seedlings, using exponential method to allocate nitrogen fertilizer with the growth of Cinnamomum kanehirae seedlings could achieve higher promotion effect than the conventional method. Comprehensively considering seedling growth and nutrient accumulation, N 400 mg/seedling is recommended for the cultivating of Cinnamomum kanehirae seedlings.

Effects of microbial fertilizer application on maize yield in China: A meta-analysis

GAN Yuan-wei, FENG Xiao-jie, LI Yong-hua, YANG Lu, NING Peng

Accepted Manuscript doi: 10.11674/zwyf.2023194

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Objectives Application of microbial fertilizers have displayed remarkable promotion effect on the growth and grain yield of maize, despite of fluctuations due to climate, soil conditions, managements, et al. Therefore, we searched the factors causing the fluctuations using Meta-analysis method. Methods There were total of 244 pairs of yield data were collected from 38 literatures published from January 2000 to May 2022 in the study. Yield responses were quantified using meta-analysis under various climate conditions, soil properties, and planting managements. The relative importance of each variable was compared based on Random Forest method. Results Application of microbial fertilizer increased maize grain yield by 13% on average in China. Compound microbial fertilizer outperformed single microbial fertilizer in terms of yield increase, in particular, either Bacillus or Trichoderma-contained compound microbial fertilizer increased maize yield by 22%–29%, Acfinobacteria and Proteobacteria-included ones increased maize yield by 17%. The magnitude of yield increase was higher under warmer or less rainfall climate. The yield increase was 12% and 15% in regions of annual mean temperature ≤10℃ and >10℃, and that was declined from 20% to 11% when the average annual rainfall raised from ≤600 mm to >600 mm. Relative to the controls, application of microbial fertilizer increased maize yield by 30% in low-yielding fields, and the increased declined to 10% and 9% in the medium- and high-yielding fields, respectively. In the insufficient nutrient input systems, i.e. N application rate less than 100 kg/hm², P₂O₅ or K₂O less than 50 kg/hm², application of microbial fertilizer could increase maize yield by 16%−28%, and under sufficient nutrient supply such yield benefits were only 9%−10%. Yield responses to microbial fertilizer application were more obvious under higher planting density than under lower plant density, the yield increase was 77% under planting density beyond 80,000 plants per hectare, but declined to 9%−10% under low densities. According to the random forest analysis, the key variables affecting maize yield responses to microbial fertilizer were annual mean temperature, planting density, soil pH, annual rainfall, N and P application rates, soil total nitrogen, soil available potassium, and organic matter, of which the annual mean temperature being the most dominant factor. Conclusions The application of microbial fertilizer is a reliable and green measurement for maintaining and further increasing maize yield, in practically under adverse environments. In all the main biological regions of maize production, Bacillus or Trichoderma-contained compound microbial fertilizer, and relatively higher plant density are conducive to optimize the maize yield benefits of microbial fertilizers.

Response of soil nutrients, enzyme activities, yield and saponin content of Panax notoginseng to different water and fertilizer combinations

WANG Zhao-yi, TUO Yun-fei, LIU Xiang-ning, SHI Xiao-lan, DING Ming-jing, LI Jian-qiang, XIANG Ping, HE Xia-hong, YANG Qi-liang

Accepted Manuscript doi: 10.11674/zwyf.2023133

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Objectives We studied the soil nutrient contents, enzyme activities, P. notoginsen yield and saponin content under different water and fertilizer combinations at the main growth stages of P. notoginseng, to optimize the water and fertilizer combination for the P. notoginseng production. Methods The experiment was conducted in the P. notoginseng Base of Luxi County, Yunnan Province, China, from 2018 to 2021. The treatment was composed of 3 watering (W) and four fertilization (F) quotas, forming 12 combination treatments: W1F1, W1F2, W1F3, W1F4, W2F1, W2F2, W2F3, W2F4, W3F1, W3F2, W3F3, and W3F4, taking the local irrigation and fertilization as control (CK). The three water quota was 120 mm (W1), 240 mm (W2), and 360 mm (W3); The four fertilizer quota were 48 kg/hm² (F1), 72 kg/hm² (F2), 96 kg/hm² (F3), and 120 kg/hm² (F4). Soil samples were collected at rooting, seedling, flowering and ripening stage for the measurement of nutrient content and enzyme activity. Plant samples were collected at the ripening stage for the analysis of yield and saponin content of P. notoginseng. The entropy weight method was used to calculate the weight of each measurement index, and the TOPSIS method was used to comprehensively evaluate the effect of each treatment combination. Results Water and fertilizer quota significantly affected the content of NO₃⁻-N, NH₄⁺-N, available P and available K, and the activities of urease, sucrase, acid phosphatase, and catalase (P<0.05). At rooting stage, the highest soil NO₃⁻-N, NH₄⁺-N, and available K content was all in W2F4 treatment (34.6 mg/kg, 21.0 mg/kg and 132.1 mg/kg). At seedling stage, the highest NO₃⁻-N content was in W2F4 (39.4 mg/k), and the highest NH₄⁺-N and available K content in W3F2 (25.4 mg/kg, 136.0 mg/kg). At flowering stage, the highest soil NO₃⁻-N, NH₄⁺-N, and available K content was appeared in W1F4 (49.9 mg/kg), W3F3 (30.2 mg/kg), and W2F4 treatment (178.1 mg/kg), respectively, and at ripening stage, appeared in W2F4 (41.8 mg/kg), W3F3 (25.7 mg/kg), and W2F4 treatment (158.0 mg/kg), respectively. The available P content increased with the increase of fertilizer application rate at the same irrigation level in all four growth stages, and the highest available P content at the rooting, seedling, flowering and ripening stage was all determined in treatment W3F4 in value of 23.6 mg/kg, 25.9 mg/kg, 30.1 mg/kg, and 26.7 mg/kg, irrespectively. The four enzyme activities had a tendency to increase with the increasing of fertilizer rate at the three irrigation quota, and the maximum activity of urease, sucrase, acid phosphatase and catalase was measured in treatment W3F4 at the four growth stages as well. The highest yield was in W2F4 treatment (2800 kg/hm²). Water use efficiency was maximum in W1F3 and W1F4 treatments (2.0 kg/m³, 2.0 kg/m³), and fertilizer partial productivity was highest in W2F1 and W3F1 treatments (1.7 kg/kg, 1.7 kg/kg). The Rg₁ and Rb₁ saponin contents were highest in the W3F2 treatment, while the Rd and R₁ saponin contents were highest in the W1F4 treatment. Yield and NO₃⁻-N, urease, acid phosphatase, catalase, sucrase, available P, available K and Re were significantly correlated (P<0.05), while Rg₁ and fertilizer partial productivity showed highly significant positive correlation (P<0.01). According to the TOPSIS analysis, W3F4 treatment ranked first in terms of soil nutrients, enzyme activities, and saponin content proximity at the rooting, seedling, and fruit stages, while W1F4 treatment ranked first at flowering stage. Conclusions Comprehensively evaluate the soil nutrient availability, enzyme activity, yield and saponin content of P. notoginseng, and the water and fertilizer use efficiency, water 360 mm and fertilizer 120 kg/hm² (W3F4 treatment) is the optimum combination.

Nitrogen application activates rhizosphere soil phosphorus and enhances the phosphorus accumulation of Pilea sinofasciata

TANG Rui, PU Yong, DAI Wen-ying, YU Hai-ying, LI Ting-xuan, YE Dai-hua

Accepted Manuscript doi: 10.11674/zwyf.2023192

Abstract(58)

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Objectives Phosphorus (P)-enriching plants can accumulate high levels of P, and nitrogen (N) fertilization has been fund to enhance the accumulation. In this study, we investigated the rhizosphere biochemical properties of a P-accumulating plant under N fertilization, aiming to provide a scientific basis for understanding how N nutrition promotes the remediation of P-excessive soils by P-accumulating plants. Methods A pot experiment was conducted using a P-accumulating plant, Pilea sinofasciata, with a mining ecotype (ME) and a non-mining ecotype (NME) under N doses of 0 and 140 mg/kg and P doses of 0, 400, 800, and 1200 mg/kg. The P accumulation in roots and shoots of the two ecotypes, as well as P composition, enzyme activity, and microbial activity in the rhizosphere and bulk soils, were analyzed. Results (1) When exposed to soil containing 800 and 1200 mg/kg of P, the growth and P uptake of both ecotypes were inhibited. N application increased their tolerance to high P treatments, with increased biomass and P accumulation. The biomass and P accumulation were respectively improved by 72.52% and 78.67% in ME, and 80.07% and 125.59% in NME by N application. Under N treatment, the maximum shoot biomass (27.23 g/plant) and P accumulation (193.82 mg/plant) of ME were recorded at P 800 mg/kg, which were 1.18 and 1.24 times higher than those of NME, respectively. (2) N application increased the concentrations of H₂O-P and NaHCO_3-Pi, and decreased the concentrations of NaHCO₃-Po, but did not significantly affect the concentrations of NaOH-P, HCl-P, and residual-P in the rhizosphere soil of both ecotypes. Under N treatment, the concentrations of H₂O-P and NaHCO₃-Pi in rhizosphere soil of ME were lower than those of NME. (3) N application increased the activities of acid phosphatase, alkaline phosphatase, and phytase in the rhizosphere soil of both ecotypes, as well as the concentrations of microbial biomass carbon and nitrogen in the rhizosphere soil and the intensity of soil respiration, indicating that N application could improve the phosphatase and microbial activity in the rhizosphere soil of both ecotypes. With N application, the activities of acid phosphatase, alkaline phosphatase, and phytase in the rhizosphere soil of ME were higher than those of NME, while microbial biomass carbon, nitrogen, and soil respiration intensity were not significantly different between the two ecotypes. Conclusions The growth and P accumulation ability of Pilea sinofasciata were inhibited at soil P content of 800 mg/kg and 1200 mg/kg without N application. N application could alleviate the growth inhibition caused by high P treatment, and increase rhizosphere P availability by promoting the activity of phosphatase, phytase, and soil microbial communities, further promoting the P accumulation of Pilea sinofasciata, especially that of the ME.

Cloning and functional analysis of PbHAK17 from Pyrus betulifolia in response to low potassium and salt stress

JIN Yu-meng, YANG Han, SHEN Chang-wei, XU Yang-chun, DONG Cai-xia

Accepted Manuscript doi: 10.11674/zwyf.2023114

Abstract(109)

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Objectives Pyrus betulifolia is a commonly cultivated rootstock with high salt tolerance. A potassium transporter gene, PbHAK17 that was screened out from Pyrus betulaefolia, seems respond to both K and salt stress. We studied its expression and function characteristics through bioinformatics, gene expression, and genetic transformation analysis. Methods Firstly, the PbHAK17 gene was cloned, and the protein structure and phylogenetic relationship were analyzed. Subcellular localization, K-deficient yeast, and transgenic Arabidopsis thaliana experiments were then employed to determine the function of the gene. The growth status, K⁺ and Na⁺ contents of overexpressed Arabidopsis lines and wild-type Arabidopsis lines were analyzed under normal and K deficiency (0 and 3 mmol/L K⁺), and salt stress (50 and 200 mmol/L Na⁺). Results The PbHAK17 is 2370 bp in length and encodes 789 amino acids, and the PbHAK17 protein was localized on the cell membrane. K deficiency and salt stress induced a significant up-expression of PbHAK17 in the root of Pyrus betulifoliaand. In conditions of potassium deficiency, the PbHAK17 yeast transformant showed significant promotion effect on the growth of deficient yeast through supplementing K, and restored the growth of deficient yeast under salt stress. The K⁺ content in leaves and roots of Arabidopsis overexpressing PbHAK17 was higher than that of wild-type Arabidopsis under low K treatment. Under the same Na⁺ concentration, PbHAK17 transgenic Arabidopsis had larger and denser leaves than wild-type Arabidopsis, and the K⁺/Na⁺ ratio of roots was significantly higher than that of wild-type Arabidopsis. Conclusions The pear potassium transporter gene PbHAK17 was localized in the plasma membrane of the cell, K deficiency and salt stress could induce the overexpression of PbHAK17 in the root system, increase K⁺ accumulation in root and leaves, and regulate the K⁺/Na⁺ ratio in plant, bring about stronger tolerance of Pyrus betulifolia to K deficiency and salt stress.

Interaction between plant phosphorus nutrition and abiotic stress responses and its potential application in agricultural production

ANG Ye-fei, GUO Yue, CHEN Hui-ying, LIU Ruo-yi, ZHU Qiu-qing, WANG Long, ZHU Yi-yong, YI Ke-ke, ZENG Hou-qing

Accepted Manuscript doi: 10.11674/zwyf.2023289

Abstract(245)

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Phosphorus homeostasis plays a crucial role in plant growth and development and resistance to environmental stresses. There are interactions among environmental stresses, soil phosphorus availability and plant phosphorus homeostasis. Phosphorus homeostasis is indispensable for the proper growth and development of plants and their resistance to environmental stresses. Abiotic stresses, such as drought, salt, low temperature, high temperature and heavy metals, not only influence the availability of phosphorus in soil, but also affect the absorption, transport and utilization of phosphate in plants. Increasing the supply of phosphate can reduce the inhibitory effect of abiotic stresses on plant growth under certain conditions and improve the resistance of plants to abiotic stresses. Studies have shown that abiotic stress can affect the phosphate signaling and influence the expression of phosphate responsive genes or proteins at the molecular level. Genetic modulation of the expression of genes, such as regulators in the phosphate signaling or phosphate transporters can improve the resistance of plants to abiotic stresses. In this paper, we summarized the effects and the underlying mechanism of drought stress, salt stress, temperature stress and heavy metal stress on phosphorus homeostasis, as well as the role and the underlying mechanisms of phosphorus homeostasis in abiotic stress resistance in plants. There are still many questions to be answered in the future. For example, which signal molecules and pathways are involved in the complex interaction between phosphorus nutrition and abiotic stresses in plants; what is the biological significance of the interaction between abiotic stress and phosphorus nutrition in plants, and what is the meaning from the ecological and evolutionary aspects; how to utilize or adjust the interaction between abiotic stress and phosphorus nutrition by means of transgenic and gene editing, so as to improve crop resistance to abiotic stress and phosphorus utilization efficiency simultaneously; what is the role of soil microorganisms in the interaction between phosphorus nutrition and abiotic stress. The answers to these questions will help us to understand the molecular mechanism of the interaction between phosphorus signaling and abiotic stress responses, and contribute to their application in agricultural production.

Effect of biochar combined with DMPP on reducing NH₃ and N₂O emission in paddy soil and its microbial mechanism

HE Li-li, HUANG Jia-jia, WANG Meng-jie, LIU Yu-xue, LÜ Hao-hao, WANG Yu-ying, YANG Sheng-mao

Accepted Manuscript doi: 10.11674/zwyf.2023117

Abstract(195)

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Objectives The effect and mechanism of biochar and nitrification inhibitor on reducing the emission of main active nitrogen gas in paddy soil and evaluate the mitigation effects of single or combined application of biochar and nitrification inhibitor. Methods a typical paddy soil in Zhejiang province was collected, and a potted experiment was conducted with airtight box gas chromatography to observe the effects of rice straw biochar and nitrification inhibitor (DMPP) on soil N₂O and NH₃ emissions during crop growth. Five treatments were set up: no nitrogen fertilizer (N0), urea (Urea), urea + nitrification inhibitor (DMPP), urea + biochar (BC), urea + nitrification inhibitor + biochar (BCDM), inorganic nitrogen content changes in surface and leakage water, N₂O emission and ammonia volatilization were observed during the critical fertilization period of crops. Fresh soil was collected to extract soil microbial DNA, and qPCR technology was used to analyze the number of key functional microorganisms (AOB, AOA and nosZ) in the production process of active nitrogen gas to reveal its microbial mechanism. Results After base fertilization, NH₄⁺-N concentration in surface water was not significantly increased in each treatment, after tillering and panicle fertilization, BC and DMPP treatment significantly increased NH₄⁺-N concentration in surface water, up to 35.44 mg/L. BCDM and DMPP treatments reduced NO₃⁻-N content of surface water up to 80.04% and 56.88%.Compared with Urea treatment, BC and DMPP alone or combined application significantly reduced the accumulated nitrogen loss in surface water up to 95.2% (BCDM).The results of nitrogen leakage at 20 cm and 40 cm soil depth of key fertilization periods (base fertilizer period, tillering period and ear fertilizer period) revealed that the cumulative leakage N loss in Urea was 3.67 kg N/hm², while BC, BCDM and DMPP treatments reduced cumulative leakage N loss by 16.5%, 27.9% and 37.4%. Compared with Urea treatment, BC, DMPP and BCDM treatment significantly reduced the cumulative N₂O emission by 31.50%, 64.04% and 57.60%, respectively, in the basal fertilizer stage and the intermediate drainage stage. DMPP significantly increased ammonia volatilization loss by 10.5%, while BC combined with DMPP or BC alone decreased ammonia volatilization loss by 25.2% and 21.6%. During the growth period of paddy field, the indirect N₂O emission caused by NH₃ emission in all treatments accounted for the main position of the total N₂O emission, the contribution rate of NH₃ to the total emission of N₂O treated in BC, BCDM, DMPP and Urea treatment was 83.9%, 90.2%, 90.5%, 52.9% and 82.0%, respectively. QPCR results showed that compared with Urea treatment, BC and DMPP alone or combined application significantly increased the amoA gene copy number of AOA by 48.0%−73.4%, and decreased the amoA gene copy number of AOB by 62.7%−95.6%; DMPP alone or combined with BC increased the copy number of nosZ gene by 3.7%-14.8%, thus promoting the N₂O reduction ability, and reducing N₂O emission. Conclusions In the growing stage of rice, the combined application of biochar and DMPP can significantly reduce the copy number of amoA-AOB gene in soil,decrease the nitrification process, and reduce NO₃⁻-N content, thus, reduce the inorganic nitrogen loss in surface and leakage water; it can increase the copy number of N₂O reductase nosZ gene, which is a key function of active nitrogen gas production process, thus reducing the total emission of N₂O (N₂O direct emission and NH₃ indirect emission) by 32.2%, and It is an effective combination of reduction of N₂O emission and NH₃ volatilization.

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