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2023 Vol. 29 No. 4

Journal of Plant Nutrition and Fertilizers (ISSN 1008-505X), a peer-reviewed sci-tech academic journal with English abstracts, key words and references, is superintended by the Ministry of Agriculture and Rural Affairs of China, sponsored by the Chinese Society of Plant Nutrition and Fertilizer, administered by the Institute of Agricultural Resources and Regional Planning, Chinese Academy of Agricultural Sciences.

Journal of Plant Nutrition and Fertilizers was started in September of 1994，and officially published in 1999. As one of the high-level academic journals in the field of integrated agricultural sciences in China, the journal has the highest impaction factor in both the fields of fundamental agricultural sciences and agronomy sciences in China since 2008. It has been honored a member of Core Sci-Tech Journal of China since 2013, and was one of the 100 Outstanding Academic Journals of China (2007), Outstanding S&T Journal of China (2008, 2011, 2017). The journal is accepted by some important international and national databases and retrieval systems, such as Chemical Abstract (CA) of USA, Centre Agriculture Bioscience International (CABI), Japanese Science Technology Agency (JST), Chinese Electronic Periodical Services (CEPS), Chinese Academic Journal Comprehensive Evaluation Database (CAJCED), FAO database (AGRIS), etc. as data source.

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Effects of fertilizer application methods on fungal communities in sweet potato rhizosphere

WANG Jing, YUAN Jie, WANG Lei, ZHAGN Hui, TANG Zhong-hou, ZHAO Peng, ZHANG Ai-jun, WANG Ji-dong, ZHANG Yong-chun

doi: 10.11674/zwyf.2022510

Abstract(102)

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Objectives Fungi play an important role in rhizosphere soil nutrient cycling. Effects of long-term phosphorus fertilizer application on the soil fungal communities in sweet potato rhizosphere were explored, in order to diminish the potential unfavorable impacts of P application methods in the rhizospheric microecological environment. Methods A long-term experiment was established in 2011 with sweet potato-wheat rotation system was conducted in Nanjing, Jiangsu Province. In 2020, three treatments were selected for this experiment: no phosphorus fertilizer (NK), chemical fertilizers (NPK), and organic and chemical fertilizers (NPKM). The rhizospheric soils of storage and fibrous roots were collected at the storage root expansion stage of sweet potato. The basic soil chemical properties were determined using standard chemical analytical methods, and the relative abundance, composition and diversity of fungal community were analyzed using Illumina Novaseq High-throughput sequencing technology. Results 1) Long-term P application altered chemical properties of rhizospheric soils. The organic carbon (SOC), dissolved organic carbon (DOC), available phosphorus (AP), and available potassium (AK) were all significantly increased by P application in both storage and fibrous rhizosphere. The SOC, DOC and AK contents were in order of NPKM>NPK>PK (P<0.05), while the AP was in order of NPK>NPKM>NK (P<0.05). Only the AP under NPK was significantly different between the two root types. The pH in fibrous and storage rhizosphere were found to be highest in NPKM, and lowest in NPK treatment. The fibrous rhizosphere pH was 0.81 units higher than that in storage rhizosphere under NPKM treatment. 2) The dominant fungi were Ascomycota (70.2%～77.9%), Basidiomycota (5.9%～8.5%), and Mortierellomycota (1.8%～8.1%), regardless of treatments. The relative abundance of Ascomycota in fibrous rhizosphere was similar among the three treatments, while that in the storage rhizosphere was significantly (P<0.05) higher in NK treatment than in NPKM treatment. The relative abundance of Basidiomycota and Mortierella was not significant different between NPK and NPKM treatments, nor between the two root types. While the relative abundance of Basidiomycetes and Mortierella in NK treatment decreased by 70.4% and 62.9% in NPK treatment, and decreased by 44.0% and 151% in NPKM treatment in storage roots. 3) The specific quantities of fungal OTUs were 122 and 113 in storage rhizosphere under NPKM and NPK treatments, respectively, while in NK treatment, it was only 86 lesser than NPKM and NPK treatments. The specific quantities of fungal OTUs were 160 in fibrous rhizosphere under NPKM treatment, and 114 and 127 in NPK and NK treatments, respectively. The observed species and Shannon diversity index were significantly higher in fibrous rhizosphere under NK treatment than those in storage rhizosphere (P<0.05). The observed species, and Shannon diversity index were highest under NPKM treatment. Topological network analysis showed that the relationships of fungal communities in the rhizosphere of storage roots were more complex, but those in fibrous rhizosphere had stronger interactions. Redundancy analysis indicated that the AP, SOC, and pH in rhizosphere soil were significantly (P<0.05) correlated with fungal community. Conclusions Long-term chemical phosphorous fertilization decreased pH, but significantly increased organic carbon and AP in rhizosphere soil. Combined application of chemical and organic fertilizers alleviated the decrease in pH, thus maintained higher abundance and diversity of fungi communities in the rhizospheric soils.

Effects of straw decayed products on inhibiting re-acidification of red soils and improving maize growth

XU Ying-hui, DU Jian-jun, FAN Ru-qin, YANG Xian-ting, HE Wen-bin, ZHOU Liang-zhuo, PAN Xiao-ying

doi: 10.11674/zwyf.2022607

Abstract(106)

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Objectives Straw decayed products have been found of improving soil acidity and resisting soil acidification. This study compared the effects of two straw decayed products, to provide technological base for choosing efficient straws to inhibit the re-acidification of red soil. Methods The lateritic red soil (pH 4.75) and latosol soil (pH 5.02), derived from granite and basalt respectively, were used as test soils, 2% of rice and pea straw decayed products (RSD, PSD) was added into the two soils to make four treatment soils. The control soils were prepared by adding Ca(OH)₂ to the same pH as the RSD and PSD treatments (RCK, PCK). All the eight soil samples were then cultured at dark for 30 days before used as the treatments of corn pot experiment. After corn harvest, soil acidity, cation exchange capacity, organic matter, available nutrient content, microbial diversity, plant aboveground and root growth and nutrient uptake were analyzed. Results Compared to before sowing, the lateritic red soil pH after harvest of maize in RSD, RCK, PSD, and PCK treatment decreased by 0.11, 0.60, 0.92, and 1.04 unit, the decrease in RCK, PSD, and PCK reached significant level. While the latosol soil pH after harvest in RSD increased by 0.22 unit, and that in RCK, PSD, and PCK decreased by 0.13, 0.16, and 0.36 unit, with significant decrease in PSD and PCK treatment. In lateritic red soil, there were no significant differences among the four treatments in exchangeable H⁺ and Al³⁺ content, while in latosol soil, the exchangeable Al³⁺ in RSD treatment was higher than in RCK, but that in PSD lower than PCK. The soil cation exchangeable capacity (CEC) in the RSD and PSD treatments were significantly higher than that in the corresponding lime treatment. The RSD and PSD increased the soil CEC by 27.11% and 17.69% in lateritic red soil, and increased soil CEC by 10.10% and 6.40% in latosol soil, respectively. Both RSD and PSD increased the content of soil organic matter, available N, P and K significantly, compared with lime controls. The application of straw decayed products enhanced the species abundance of Firmicutes, Actinobacteria, Ascomycota and Basidiomycota, stimulated the growth of maize plants and roots and the absorption of nutrients. Compared with lime treatment, the plant height, biomass, total root length, root surface area and root volume of maize treated by pea straw decayed product increased by 59.51%, 738.43%, 280.00%, 392.87%, 404.31% respectively in lateritic red soil, and those in latosol were 29.82%, 72.04%, 23.43%, 11.05% and 5.79%, respectively. Conclusions Compared with lime treatment, the application of rice and pea straw decayed products effectively prevented soil re-acidification, improved soil fertility, increased soil microbial community diversity, and promoted the growth of maize. The promoting effect of pea straw decayed product treatment was better than that of rice straw decayed product.

Construction and regulation of soil structure in root zone based on the theory of rhizobiont

LIU Xue-song, WANG Yi-fei, SHI Yuan-fei, ZHANG Fang-bo, WU Meng-qi, TANG Xiao-yan, SHEN Jian-bo, JIN Ke-mo

doi: 10.11674/zwyf.2022616

Abstract(99)

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In China, most agricultural soils have structural obstacles such as shallow plow layer, crust, and compaction, which seriously affect crop yields and threaten food security. Some methods such as deep plowing and deep loosening, application of organic fertilizer, returning straw to the field and adding biochar, are often used in modifying soil structure, and have resulted in obvious changes. However, the high cost and environmental risks brought about by these methods are not negligible. Recently, the biological potential of plant roots have caused concerns on their great potential to change soil pore characteristics through root growth and release of root exudates. As a "green" way to reduce soil barriers, root zone soil structure regulation has important theoretical and practical significance. Here, in this review, we summarize the characteristics of soil structure in the root zone, and the advantages and disadvantages of the existing measures to reduce soil structure barriers, and discuss the feasibility of exploring and strengthening root-soil interaction and using plant roots to reshape soil structure based on the theory of "Rhizobiont". Specifically, we focus on the design and construction of ideal soil structure from the perspective of soil pores. Different diameters of soil pores correspond to different functions. By selecting plants with specific root phenotypes to reshape the soil pore network, and then construct an ideal root zone soil structure to realize the coupling of soil structure and function.

Root morphology and nutrient efficiency of Tibetan barley and Peas in response to planting pattern and fertilization levels

GUO Tong-xin, YAO Xiao-hua, WU Kun-lun, YAO You-hua

Accepted Manuscript doi: 10.11674/zwyf.2022691

Abstract(16)

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Objectives We examined the root morphology and nutrient utilization of Tibetan barley (Hordeum vulgare var. coeleste Linnaeus) and Peas (Pisum sativum L) in mixed cropping systems under different fertilization levels. Methods The study used pot and field experimental methods at the Qinghai University experimental base. The cropping patterns included monoculture of Tibetan barley and Peas and mixed cropping of both crops. Fertilization levels were no fertilization (N₀P₀), low nitrogen and phosphorus (N₁P₁), and high nitrogen and phosphorus (N₂P₂). The root morphology, biomass, N and P contents of Tibetan barley and Peas, and estimated nutrient use efficiency of both crops. Results Compared with monoculture, mixed cropping (P<0.05) increased the shoot and root dry weight of Tibetan barley by 32.1% and 15.3%, decreased the root to shoot ratio by 13.1%, increased the total root length, root surface area, total root volume and root tip number by 21.7%, 43.7%, 79.6%, and 44.8%, increased root N content and total N uptake by 75.8% and 72.7% and root P content and total P uptake by 56.3% and 60%. On the contrary, mixed cropping (P<0.05) decreased peas shoot and root dry weight and the root-to-shoot ratio by 19.3%, 27.9%, and 9.7%, decreased the shoot and root N content and total N uptake by 24.7%, 32.5%, and 28.0%, and the shoot and root P content and total P uptake by 2.6%, 12.8%, and 6.9%, respectively. Compared with mono-cropping, the N accumulation in Tibetan barley shoot under mixed cropping (P<0.05) increased by 9.8%, 34.6%, and 39.6%, and those of P increased by 11.6%, 18.7%, and 16.5% at tillering, jointing, and maturity stages. Peas shoot N accumulation under the mixed cropping system decreased by 13.8%, 18.0%, and 17.5%; the shoot P accumulation decreased by 26.1%, 15.8%, and 19.9% at branching, flowering and podding stages. Multiple linear regression analysis showed that the root surface area, volume, and average root diameter (P<0.05) affected the N and P uptake of Tibetan barley under mono-cropping and mixed cropping. Under N₁P₁ condition, the root length and surface area of Tibetan barley (P<0.05) increased in the mixed cropping system, promoting the absorption of N and P, but showed an opposite effect on Pea's root development. Conclusions The N and P uptake of Tibetan barley and peas positively correlate with the root surface area and volumes. Inefficient N and P supply changed the root morphology in the mixed cropping system. Mixed cropping increased the root morphology indexes of Tibetan barley but decreased Peas' root surface area and volume. Hence, Tibetan barley is the "beneficiary" while Pea is the "contributor". The mixed cropping system increased grain yield and nutrient utilization more than mono-cropping. Under sufficient fertilization, the mixed cropping system did not influence the two crops' root morphology, with less benefit from the system.

The spatiotemporal variation of soil available phosphorus and phosphorus application strategy in Dali tobacco field in Yunnan

CHENG Xiaomei, WANG Fei, SUN Nan, KUAI Yan, FAN Zhiyong, XU Minggang, LI Jianhua

Accepted Manuscript doi: 10.11674/zwyf.2022656

Abstract(17)

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Objectives This study investigated the spatiotemporal variation of soil available phosphorus (AP) in tobacco-growing areas of Dali Prefecture, Yunnan province, aimed to provide a scientific basis for phosphorus management friendly to high-quality tobacco production and sustainable environment. Methods The total tobacco planting area in Dali Prefecture of Yunnan is around 3.23 ×10⁵ hm². In 1999, 2012, 2018 and 2022, 256, 633, 1244 and 2332 soil samples in total were collected from five typical tobacco planting counties of Dali for determination of soil available P content. Geostatistics and GIS technology were used to analyze the spatiotemporal variation of soil AP in the five counties over five time periods (1982, 1999, 2012, 2018 and 2022) spanning four decades. Finally, a general phosphorus application strategy was proposed based on the soil AP content in 2022. Results The average soil AP content in the tobacco-growing areas of Yunnan-Dali trended to increase over the last 40 years. The AP increased from 8.09 mg/kg in 1982 to 43.92 mg/kg in 2022, with an increase of 5.42 times. The soil AP content in most tobacco planting area belonged to 'low' grade (<20 mg/kg) in 1982, and over 50% of soil belonged to 'medium' grade (20～40 mg/kg) in 1999～2022. The nugget effect of soil available nutrients increased from less than 25% to 41.45% over the last 40 years, indicating a weakening influence of natural factors such as topography and an increasing impact of human factors such as fertilization. Based on the of soil AP content in 2022, 34.21% of the total area are high and even extremely high in soil AP, mainly distributed in the north of Midu, west of Xiangyun, southwest and northeast of Binchuan. Conclusions The soil AP content in Dali tobacco-growing areas has significantly increased on average over the past four decades, due to fertilization. Most tobacco fields should reduce or even stop phosphorous fertilizer application.

Effects of Candidatus Liberibacter asiaticus on assimilate accumulation and mineral nutrient transport in citrus leaves

SHI Ya-man, ZENG Ji-xing, XUE Jin-jun, JIA Shu-gang, WANG Min, GUO Shi-wei

doi: 10.11674/zwyf.2022528

Abstract(105)

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Objectives Huanglongbing is one of the most devastating citrus bacterial diseases worldwide, mainly caused by Candidatus Liberibacter asiaticus (C. Las) infection. This study was conducted to investigate the relationship between leaf mineral elements and the development of Huanglongbing to provide a theoretical basis for revealing the pathogenesis of the disease. Methods The surveyed citrus orchard was located in the Huanglongbing Disease Research Center, Yangshuo, Guangxi Province. Six healthy and diseased plants were selected, and the twigs in the middle part of the citrus trees with 6 to 8 leaves were chosen for leaf sampling. X-ray fluorescence spectroscopy (XRF) method was used to measure leaf temperature, assimilate distribution in different parts of the leaves, and the ICP-MS method was used to determine the nutrient contents in the leaf parts. Results The C. Las mainly colonized in the vicinity of sieve tubes and companion cells in the leaves (i.e., midrib). The pathogen's cycle threshold (Ct value) in the midrib (P<0.05) decreased. Compared with healthy citrus leaves, the infected leaves were mottled yellow, with reduced chlorophyll content and increased leaf temperature. The starch, total soluble sugar and fructose (P<0.05) increased in the mesophyll and midribs, while the sucrose (P<0.05) increased in phloem. The accumulation of nutrient elements in different parts of the leaves significantly changed between the healthy and ill leaves. Ca and Fe accumulated in mesophyll, K in midrib, and Zn, Cu, and Mn were lacking in mesophyll. There was a (P<0.05) positive correlation between Cu and Zn in the mesophyll and a negative correlation between Ca and Mn and Cu in midrib. In the linear mixed effect model, the pathogen concentration had a (P<0.05) effect on K, Ca, Fe, Cu, Mn, and Zn, showing a positive effect on K, Cu, and Mn and a negative effect on Ca and Fe. Conclusions The pathogen of Huanglongbing mainly colonized the midrib of leaves, blocked the transport of starch and total soluble sugar from mesophyll, midrib and phloem to xylem of the leaves. The mineral elements balance the nutrition through synergistic or antagonistic relationships to resist the growth of pathogens. The number of pathogens is positively correlated with K, Cu, and Mn content and negatively correlated with Ca and Fe in mesophyll. Therefore, Ca and Fe nutrition is essential for dealing with the Huanglong disease of citrus.

Using discrete element simulation and microstructure observation to study the urea surface modification and nutrients release performance of coated urea

TIAN Hong-yu, DONG Jing-jing, XIE Chen-shuo, CUI Jing, DUAN Jian-hang, ZHANG Tian-jiao, DAI Jia-ying, WANG Shuo, ZHANG Li-li, WEI Zhan-bo, WU Liang, GUO Wu-song, LIU Zhi-guang, ZHANG Min

doi: 10.11674/zwyf.2022495

Abstract(105)

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Objectives Surface modification is a key step towards realization of nutrient-release control of coated urea production. We tested several abrasives, and studied the basis for modification in improving the coating property. Methods In this study, large granular urea (3–5 mm, N 46%) was used as the fertilizer core, while the tested abrasives included brown-fused alumina, white-fused alumina, zirconia beads, alumina porcelain beads, and aluminum porcelain column. By measuring the repose angle of polished urea after polishing with the abrasives, alumina porcelain beads with a bulk density of 1.336 g/cm³ and a diameter of 6 mm were chosen as the abrasive in the later research stage. 1 kg urea and 1.5 kg alumina porcelain beads were loaded into a drum granulator, discrete element software (EDEM) was used to simulate the motion, collision, force and distribution of abrasive friction and urea particle self-friction. The surface and sectional structure and the roughness of modified urea were scanned using electron microscopy. The microstructure of the coating was observed using atomic force microscopy (AFM). The nutrient release characteristics of polished and ordinary urea, coated with 3%, 5% and 7% of nano-SiO₂ modified castor oil-based polyurethane, were determined by static water dissolution method. Results According to the simulation of EDEM, the urea particles near the bottom moved fast (1.125 m/s), and those at the edge moved slowly (0.00309 m/s), causing the segregation of small particles at the bottom of the drum during the mixing process. The self-friction force of pure urea was about 0.035N, while the total friction force when mixed with the abrasive increased to about 0.042 N. This enlarged force increased the collision number of urea-abrasive mix system by 13.0% than that of the self-friction system, thus creating more efficient modification. The modification significantly reduced the surface average roughness (Ra) by 79.2% within 1 μm² of detection area. From the electric micro-morphology images we could see, common urea surface was rough, film material filled into the low parts causing extra consume of film materials and obstructing the close bonding of coating layer with the urea chip, thereby the coating film was fragile during transportation or long-time storage and lost controlling capacity of nutrient release. While the modified urea surface was smooth, preventing the waste of film materials. The film layer was even in thickness and uniform in intersecting surface, and closely bonded with the core. For urea coated nano-SiO₂ modified castor oil-based polyurethane with 5% coating rate, the nutrient release period increased by 6 times from 24 days before polishing to 169 days after polishing. Conclusions According to the simulation of EDEM discrete element software, the mixture of alumina porcelain beads and urea greatly increased the modification efficiency, reduced the surface roughness of urea significantly. The surface microstructure of the modified urea core of controlled release fertilizer was significantly improved, the amount of coating material was reduced, and the nutrient release period was prolonged under the same coating rate.

Influence of over-expression of AngdhA gene on growth and nitrogen use efficiency of transgenic rice lines

LIANG Cheng-gang, WANG Yan, LI Tian, OHSUGI Ryu, AOKI Naohiro

Accepted Manuscript doi: 10.11674/zwyf.2022572

Abstract(64)

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Objectives We studied the effect of over-expressing Aspergillus niger gdhA gene on the growth, expression of key enzyme genes related to nitrogen metabolism, carbon and nitrogen contents, nitrogen use efficiency, yield, and salt tolerance of transgenic rice lines, aiming to provide scientific support for breeding rice with high efficiency, yield, and tolerance. Methods Transgenic rice lines TG3 and TG13 (expressing Aspergillus niger gdhA gene), and wild-type (WT) were used as materials in hydroponic experiments. Seedling samples at the 3-leaf stage under normal cultural condition were used to analyze gene expression of glutamine synthetase and glutamate synthase, carbon and nitrogen contents and samples at harvest used for investigation of yield traits and nitrogen use efficiency. Salt stress treatment was simulated by adding 0, 50, and 100 mmol/L NaCl to the nutrient solution, and the relative growth rate, proline content, leaf wilting rate, and organ biomass of seedlings at the 3-leaf stage were analyzed after subjected to salt stress for 0, 2, and 4 days. Results PCR amplification and electrophoresis analysis confirmed that Aspergillus niger AngdhA gene was successfully introduced into TG3 and TG13 lines of rice. The expression levels of AngdhA gene in TG3 and TG13 lines were 248-fold and 41-fold compared to the reference gene UBI, respectively by qRT-PCR detection. However, the expression of key enzyme genes in nitrogen metabolism, including OsGS1;1, OsGS1;2 and OsGOGAT, was slightly affected in both TG3 and TG13 lines. Only OsGS2 in TG13 was extremely significantly down-expressed compared to WT. The N, C contents and C/N ratio in leaf and root at seedling stage, and in grain, shoot and root at harvest were not significantly different among the three rice lines. However, TG3 and TG13 had significantly higher C and N accumulation than WT in plants, particularly in grains. TG3 and TG13 increased NUE by 14.67% and 44.12%, NGPE by 26.96% and 39.83%, and NPP by 24.53% and 39.67% over WT, respectively, with significant or highly significant increase in panicle number, grain number, and yield per plant. The relative growth rates of TG3 and TG13 under 50 mmol/L NaCl were higher than that under the control (0 mmol/L NaCl). The proline content in rice was sharply increased under salt stress. Compared to WT, TG3 and TG13 elicited significant higher proline content under 50 mmol/L NaCl, but extremely significant lower proline content under 100 mmol/L NaCl. Conclusions Aspergillus niger AngdhA gene was successfully introduced into TG3 and TG13 lines of rice without apparent disturbance of carbon-nitrogen balance. However, the exogenous AngdhA gene promoted nitrogen uptake, utilization, and remobilization, thus improving nitrogen use efficiency, yield, and salt tolerance of rice; while the over-expression of AngdhA gene in TG3 might have increased substrate cycle in glutamate synthesis and catabolic pathway and bring down the increment of nitrogen uptake and utilization and yield. The differential accumulation of proline might be related to the different response and tolerance of rice to salt stress.

Effects of chemical fertilizer reduction on rice yield and soil fertility in yellow-mud paddy field under the continuous return of milkvetch

HE Chun-mei, WANG Fei, HUANG Yi-bin, LIU Cai-ling, CAO Wei-dong, Li Qing-hua, ZHANG Hui

Accepted Manuscript doi: 10.11674/zwyf.2022516

Abstract(27)

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Objectives We studied the effect of different chemical fertilizer reduction rates on rice yield and paddy field fertility under the long-term return of milkvetch (Astragalus sinicus) for efficient and sustainable rice production. Methods The field experiment was carried out in Fujian province from 2009 to 2019, with single-rice cultivation after milkvetch return cropping system. There were seven fertilization treatments: no fertilizer application (CK, control), conventional chemical fertilization rate (100%F), applying 100%, 80%, 60% and 40% of the conventional chemical fertilization rate under the return of milkvetch (M+100%F, M+80%F, M+60%F, M+40%F), and milkvetch (M) only. Rice grain and straw samples were collected at the rice harvest stage to detect the N, P, and K content, rice grain yield and amino acid content from 2017 to 2019. Soil samples at 0-20 cm depth were collected in 2019 at tillering and maturity stage for the determination of soil bulk density, pH, organic carbon, microbial biomass nitrogen (MBN) and soluble nitrogen. Results Compared with CK, the rice grain and straw yields in all the fertilizer treatments (P<0.05) increased by 11.4%～21.3% and 17.1%～39.0%, respectively. Compared with 100%F, M+100%F and M+80%F increased rice yield by 3.7% and 3.0%, straw yield by 5.1% and 5.6%, while the other treatments produced similar grain and straw yields. M+80%F increased N uptake by 22.5% and 5.1% at peak tillering and maturity stage, increased the total and essential amino acid contents in grains by 5.2% and 6.7%, while the M+ less than 60%F decreased the total and essential amino acid contents. Compared with the 100%F treatment, M increased soil nutrient contents by 3.6%−24.1%, soil MBC by 0.3%−23.5%, total N by 9.4%−14.1%, and organic matter by 8.2%−12.0%. Conclusions On the basis of annual returning of 18000−22500 kg/hm² milkvetch to the soil, applying over 60% of the conventional rate of chemical fertilizer in the middle and low paddy field could maintain rice grain and straw yield. Applying 80% of the conventional chemical fertilizer rate improves soil properties, stimulates rice N uptake, yield and nutritional quality, making it the optimum application rate.

Effects of no-tillage mulching and biochar application on the stability and humus properties of black loam soil aggregate

ZHOU Ming-xing, FAN Jun, WANG Xi, DAI Zi-jun, GOU Guo-hua

Accepted Manuscript doi: 10.11674/zwyf.2022519

Abstract(115)

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Objectives We studied the effects of different soil mulching methods and biochar addition on soil aggregate stability and humus properties under no-tillage conditions in Weibei dryland. We aim to provide a theoretical basis for selecting suitable farming management measures. Methods The field experiment lasted 18 consecutive years; we collected soil samples at 0−10 cm and 10−20 cm depth from the five no-tillage treatments, namely, no mulching control (NT), biochar application (NB), straw mulching (NS), plastic film mulching (NP), and straw plastic film binary mulching (NSP). Dry-sieving and wet-sieving methods were used to divide the soil aggregate into four fractions: silty-clay (<0.053 mm), microaggregate (0.053−0.25mm), macroaggregate (0.25−2 mm), and large macroaggregate (>2 mm), and the contents of organic carbon and humus components in the aggregates of each fraction were determined. Results 1) Compared with NT, NS had the highest humin acid content (0.93%−92.6%) and fulvic acid content (1.8%−327.5%) across the four aggregate sizes; NSP increased the organic carbon by 1.6%−30.5%; organic carbon increased by 39.9%−161.8% in soil aggregate of NB treatment NB recorded a higher increase in humin content in 0−10 cm soil layer (87.2%−271.7%). NB, NS, and NSP improved soil aggregate stability and maize seed yield, with the most remarkable effect recorded for NSP. Compared with NT, NSP increased the mean weight diameter (MWD) of soil aggregate in 0−10 cm and 10−20 cm soil layers by 48.6% and 73.5%, the geometric mean diameter (GMD) in 0−10 cm and 10−20 cm soil layers by 59.2% and 63.1%, and the corn grain yield by 25.8% in 2021. 2) Humin was dominant in the organic carbon, accounting for 37.6%−91.3% of the total organic carbon in the water-stable aggregates in different particle sizes. NB (P<0.05) increased the ratio of humic to fulvic acid (HA/FA) in most water-stable aggregates, with the maximum increase (80.2%) recorded in micro-aggregates in 0−10 cm soil layer. Plastic film mulching (NP and NSP) decreased the HA/FA of humus (6.8%−27.6%), and the humic acid E4/E6 in silty clay (P<0.05 ) decreased (4.2%−6.6%). Conclusions Under no-tillage, both straw mulching and biochar application (NS, NSP, and NB) can improve aggregate organic carbon content, stability, and corn yield, but their effect on the humification degree of organic carbon is different. Straw mulching (NS) is the most effective for humic and fulvic acid content in humus. Biochar application is the most effective in increasing the humin content and its proportion in organic carbon. Straw and plastic film binary mulching (NSP) improves aggregate stability, organic carbon content, and corn grain yield, proving the best treatment under the test condition and area.

The study of intelligent fertilizer recommendation method for rice based on yield response and agronomic efficiency

XU Xin-peng, DING Wen-cheng, HE Ping, ZHOU Wei

Accepted Manuscript doi: 10.11674/zwyf.2023116

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Objectives The early version of Nutrient Expert for Rice did not differentiate rice types, reducing the precision of fertilizer recommendation at times. We optimized the version by establishing Nutrient Expert for Rice targeted to specific rice type. Methods The yield and nutrient uptake data were collected and summarized from multi-year and -site rice field experiments from International Plant Nutrient Institute (IPNI) China Program, our research group and relevant published articles. QUEFTS model was used to analyze the nutrient uptake of different rice types, to establish the intrinsic relationship between rice yield response and agronomic efficiency, construct a fertilizer application model and develop nutrient expert system for rice. A total of 452 field experiments were conducted in eight provinces in the main rice producing areas from 2013 to 2020 to calibrate and improve the system. Each experiment included six treatments: fertilizer recommendation based on Nutrient Expert (NE), farmers’ practices (FP), conventional recommendation based on soil testing (ST), and N omission, P omission and K omission based on the NE treatment. Rice yield, economic benefit, nutrient use efficiency and fertilizer agronomic efficiency were investigated. Results The result of the relationship between rice yield and nutrient uptake based on QUEFTS model showed that the N, P and K requirements at above-ground dry matter to produce 1 ton of grain yield were 14.2, 3.9 and 14.3 kg for single-season rice, respectively, and 16.9, 3.3 and 20.9 kg for early, middle, late rice, respectively. The yield responses to N, P and K fertilizer application were 3.1, 1.1 and 1.0 t/hm2 for single-season rice, 2.3, 1.0 and 1.0 t/hm² for early rice, 2.3, 0.9 and 1.0 t/hm² for middle rice, 1.9, 0.8 and 0.8 t/hm² for late rice, respectively. The agronomic efficiency of N, P and K fertilizer were 17.6, 15.3 and 9.8 kg/kg for single-season rice, 14.6, 15.3 and 10.1 kg/kg for early rice, 11.4, 12.4 and 9.1 kg/kg for middle rice, and 11.5, 14.8 and 9.2 kg/kg for late rice, respectively. The NE treatment applied 12.6%, 9.6% and 21.4% less N, P and K fertilizer than FP treatment, and 7.6% less N and 15.6% less K fertilizer than ST treatment. Compared with FP and ST treatments, the NE treatment increased yield by 0.5 and 0.3 t/hm²; net profit by 1627 and 893 yuan/hm²; increased N recovery rate by 13.1 and 9.3 percentage points, and increase agronomic efficiency by 4.1 and 2.7 kg/kg; increased P recovery rate by 7.8 and 5.0 percentage points; increased agronomic efficiency by 6.6 and 3.3 kg/kg; increased K recovery rate by 14.6 and 9.5 percentage points; and increased agronomic efficiency by 5.6 and 4.9 kg/kg, respectively. Conclusions The newly constructed Nutrient Expert for Rice, based on the intrinsic relationship of yield response, agronomic efficiency and relative yield of different rice types, is recommended for efficient in further optimal fertilizer rate, improved rice yield and fertilizer use efficiency, and increased farmers' income. The nutrient expert for rice is a feasible fertilizer application method for small farmers in China

Effects of coupled water and nitrogen on soil organic carbon fractions and enzymes in a drip-irrigated cotton field

HAO Hai-bo, XU Wen-xia, HOU Zhen-an

doi: 10.11674/zwyf.2022440

Abstract(157)

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Objective The effects of irrigation and nitrogen application on soil organic carbon, nitrogen content, and organic carbon pool stability in drip-irrigated cotton fields were studied to provide a theoretical basis for achieving efficient cotton production and sustainable development in Xinjiang. Methods A two-factor three-level complete random field experiment was conducted using cotton as the test material. The three irrigation volumes (W) were low (360 mm), medium (480 mm), and high (600 mm), and the three nitrogen rates (N) were low (0 kg/hm²), medium (300 kg/hm²), and high (450 kg/hm²), giving a total of 9 treatment combinations. After harvesting the cotton, we collected 0– 20 cm soil samples to measure soil organic carbon (SOC), water soluble organic carbon (WSOC), microbial biomass carbon (MBC), easily oxidized organic carbon (EOC), stable organic carbon (NOC), soil urease (URE), β- Glucosidase (BG), and N-acetyl-β-D-glucosidase (NAG) activity. The soil organic matter decomposition rate and soil carbon pool management index (CPMI) were measured using the net nylon bag method at the in-situ landfill on the field. Results SCompared with W600N450, W480N300 increased soil organic carbon by 8.9% and 10.9%, C/N by 16.2% and 16.3%, EOC and NOC by 11.8%–15.4% and 14.3%–20.8%, while WSOC decreased by 35.5% and 21.8% in 2015 and 2016, respectively. It was shown that reasonable water and nitrogen management was beneficial to increasing soil organic carbon and stable organic carbon content, reducing water-soluble organic carbon, and improving soil carbon pool stability. Compared with W480, W360 (P<0.05) reduced MBC, while W600 reduced WSOC and NOC. The EOC content in W360 (P<0.05) decreased by 2.1% and 5.3% in two years, while that in W600 decreased by 4.1% and 7.6%, respectively. Compared with N300, the N0 treatment reduced MBC by 41.8%, while N450 reduced NOC. The EOC in the N0 treatment decreased by 20.2% and 16.7% in two years, while that in N450 decreased by 3.8% and 2.4%, respectively. The results showed that the effect of nitrogen application rate on soil organic carbon was greater than the irrigation level. Simultaneously, excessive irrigation and nitrogen application reducer stable organic carbon and increased microbial biomass carbon, which was not conducive to soil organic carbon accumulation. High irrigation (600 mm) and nitrogen (450 kg/hm²) (P<0.05) increased soil enzyme activity and decreased soil carbon management index. The activities of urease, β-glucosidase, and N-acetyl-β-D-glucosidase in W480N300 were 1.0%, 22.4%, and 32.6% higher than in W360N0. The correlation analysis showed that CPMI was positively correlate with active organic carbon (MBC, EOC) in different degrees and negatively correlate with NOC. Conclusion Under drip irrigation conditions in Xinjiang, excessive irrigation and nitrogen application rates reduce soil organic carbon, stable organic carbon, soil carbon pool activity, and carbon pool management index. In contrast, it increases microbial biomass carbon and enzyme activity, which is not conducive to maintaining soil organic carbon stability. In this study, 480 mm irrigation combined with 300 kg/hm² nitrogen application is conducive to promoting soil organic carbon accumulation and improving soil organic carbon activity in drip-irrigated cotton fields.

Effects of potassium application rate on the yield and quality of oilseed rape (Brassica napus L.)

GU He-he, CUI Xin, LI Jing, ZHOU Yang-guo, LU Zhi-feng, ZHANG Yang-yang, CONG Ri-huan, LI Xiao-kun, REN Tao, LU Jian-wei

Accepted Manuscript doi: 10.11674/zwyf.2022553

Abstract(108)

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Objectives Most farmlands in China have low effective soil potassium (K), and this deficiency has become a major limiting factor for oilseed rape production in some areas. Here, we investigate the effect of different K fertilizer application rates on oilseed rape yield and seed quality to provide theoretical support for the rational application of K fertilizer in winter oilseed rape production for high yield and quality. Methods A field trial was conducted for two consecutive years from 2019−2021 in Wuxue City, Hubei Province, with five K₂O application levels of 0 (K₀), 60 (K₆₀), 120 (K₁₂₀), 180 (K₁₈₀), and 240 (K₂₄₀) kg K₂O /hm². The yield, yield components, oil content, protein content, fatty acid composition, glucosinolate content, seed nitrogen (N) and K, silique's N and K dynamics, and photosynthetic parameters were analyzed. Results (1) K fertilizer application (P<0.05) increased rapeseed yield. Compared with K₀, the K application treatments increased rapeseed yield by 62.9%−103.7% and 31.0%−59.2% in 2020 and 2021, respectively. The rapeseed yield (P<0.05) increased with an increase in the K₂O application rate, and no further yield increase was observed at K₂O 120−180 kg/hm². K application increased the number of siliques per plant and the number of seeds per silique, thereby increasing rapeseed yield. (2) K fertilization application improved rapeseed's nutritional and feeding quality. Compared with K₀, rapeseed oil content in K₁₈₀ in 2020 and K₁₂₀ in 2021 (P<0.05) increased by 4.8% and 6.9%, while the protein content showed a decreasing trend with an increasing K₂O rate. The protein content of K₁₈₀ and K₂₄₀ in 2020 and K₂₄₀ in 2021 decreased by 9.1%, 14.2%, and 12.1%, respectively, compared with K₀. With the increase in K₂O rate, the oleic acid in rapeseed showed an increasing trend, while the glucosinolate content decreased. K fertilizer application (P<0.05) increased rapeseed oil and protein yield. There was no further increase in rapeseed oil yield at 180 K₂O kg/hm² and above. There was no significant difference (P>0.05) in protein yield between the K application treatments. K application (P<0.05) reduced the seed N content, with 13.1%−21.9% and 15.9%−22.0% reduction in 2020 and 2021, respectively, compared to K₀. Seed K content (P<0.05) increased with increasing K₂O rate, recording 8.1%−37.8% and 6.3%−27.1% in 2020 and 2021. Seed N and K dynamics during silique development showed that seed N in K₀ was higher than in K₁₂₀, while seed K was lower than in K₁₂₀. K fertilizer application also increased the photosynthetic capacity of silique, and the net photosynthetic rate (A_n) of K₁₂₀ silique increased by 21.1% compared with the K₀. Conclusions K fertilizer application increased the number of siliques per plant and the number of seeds per silique, thereby increasing rapeseed oil yield. K application reduced rapeseed N, increased the K content and photosynthetic capacity of silique, oil synthesis and rapeseed protein yield, improved the composition of fatty acids, and reduced glucosinolate content. K₂O rate between 131−160 kg/hm² improved rapeseed’s nutrition and feeding quality while recording higher oil and protein yields.

Spatio-temporal variation of relative yield gap of rice and its response to nitrogen fertilizer in China

SHEN Zhe, HAN Tian-fu, HUANG Jing, QU Xiao-lin, MA Chang-bao, LIU Kai-lou, WANG Hui-ying, LIU Li-sheng, LI Dong-chu, LI Ya-zhen, WANG Qiu-ju, ZHANG Hui-min

doi: 10.11674/zwyf.2022480

Abstract(142)

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Objectives To explore the spatial-temporal variation characteristics and driving factors of relative yield gap of rice across China in 15 years (2004−2019) and the response of relative yield gap to nitrogen application rate under different soil productivity levels, so as to provide theoretical basis for rational application of nitrogen fertilizer in rice. Methods Based on the long-term monitoring database of Farmland Fertility, the Ministry of Agriculture and Rural Affairs of China, the difference of rice yield between fertilized and non-fertilized plot was defined as relative yield (RY), the highest relative yield (HRY), the average relative yield (ARY) and the relative yield gap (G_RY) were obtained by using the statistical method of high-yielding households, and the effects of fertilization and soil factors on the relative yield gap were determined using the random forest model, and soil productivity level was divided according to the yield of non-fertilized area. The relationship between the relative yield gap of rice and nitrogen application rate under different soil productivity levels was quantified. Results Within the 15 years of observation, the HRY of rice in China was 4.98−6.86 t/hm^/2. ARY was 3.06−3.47 t/hm², and G_RY was 1.92−3.41 t/hm². In terms of different regions, HRY and G_RY trends were in order of southwest China (rice−other crop)>Yangtze River Delta (rice−other crop)>south China (early rice)>northeast China (single rice)>middle of the Yangtze River (rice−other crop)>south China (late rice)>middle of the Yangtze River (early rice)>middle of the Yangtze River (late rice). In low and medium soil productivity levels, the G_RY decreased and then stabilized with increasing nitrogen fertilizer application rate, but it did not change significantly in high productivity soils. Except the low and medium productivity soils in the southwest China and the low productivity soils in the northeast China, the inflection points of nitrogen application rate appeared in the low and medium productivity soils in other regions. For low and medium productivity soils, the inflection points of nitrogen application rate for early and late rice in the middle of the Yangtze River were 187.5, 165.0 kg/hm² and 183.5, 152.5 kg/hm², respectively; early and late rice in south China were 195.0, 153.0 kg/hm² and 169.0, 157.0 kg/hm², respectively; rice-other crop rotation system in the middle of Yangtze River and Yangtze River Delta were 199.5 kg/hm², 184.5 kg/hm² and 202.0 kg/hm², 171.0 kg/hm², respectively; and 146.5 kg/hm² for the medium productivity soil in northeast China. Nitrogen application rate (NF), soil organic matter (SOM) and total nitrogen (TN) were relatively important factors affecting G_RY in low and medium productivity soils. In high productivity soils, SOM and TN had significant effects on G_RY, and potassium application (KF) significantly affected G_RY of early rice in the middle of the Yangtze River and south China. Conclusions The relative yield gap of rice in southwest (rice−other crop) was the highest, and that of late rice in middle reaches of Yangtze River was the lowest. Nitrogen application rate, soil organic matter and total nitrogen are important factors affecting the relative yield of rice. Nitrogen fertilizer should be reduced appropriately in high productivity soil as nitrogen application rate has no significant effect on relative yield gap. For low and medium productivity soils, increasing nitrogen application could significantly reduce the relative yield gap and increase yield potential within the inflection point (146.50−202.00 kg/hm²). Potassium fertilizer application requires more attention at high soil productivity in middle of Yangtze River and south China.

Interactive effects of potassium and magnesium on nutrient uptake, accumulation and allocation of tomato

QU Shuai, LI Hui-xia, ZHANG Tian-yi, KOU Gui-xiang, CHEN Ping, YANG Yan-mei

Accepted Manuscript doi: 10.11674/zwyf.2022526

Abstract(131)

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Objective The effects of K and Mg and their interactions on nutrient uptake of tomato were studied. Methods A hydroponic trial was conducted with cherry tomato 'Bijao' as the test crop. On the base of Yamazaki nutrient solution for tomato, Mg concentrations of 0 and 1.5 mmol/L (Mg₀, Mg_1.5), and K concentrations of 4, 40 and 200 mmol/L (K₄, K₄₀, K₂₀₀) were tested as individual treatments and as treatment combinations. At seedling, flowering stage, and fruiting setting, the root, stem and leaf samples were collected to analyze biomass, K, Ca and Mg contents. Results The average biomass of tomato root, stem, and leaves in all three stages were in the order of K₄>K₄₀>K₂₀₀, and those of root and leaf biomass at flowering and fruit setting stages were Mg_1.5>Mg₀. The K content in all the plant parts across the three stages was K₄₀>K₄ under both Mg levels, while tomato plants were depleted and decayed at fruit setting stage under K₂₀₀. The Ca and Mg contents in the whole growth period showed K₄>K₄₀>K₂₀₀. The highest Ca content in all organs was recorded in Mg_1.5K₄ at fruiting stage, while the Mg content in all the plant parts across the three stages was higher in Mg_1.5 than in Mg₀. Highest K uptake occurred under K₄₀ at flowering and fruit setting stages. K-Mg interactions significantly affected the stem K, leaf Ca content at fruit setting stage, and Mg content in whole plant at flowering and fruit setting stages (P<0.01). At different levels of K concentration, K accumulation at seedling and flowering stages was in order of K₄₀>K₄>K₂₀₀, and Ca and Mg accumulation was in order of K₄>K₄₀>K₂₀₀. K accumulation in all organs at fruiting stage were higher in Mg_1.5 than in Mg₀. Ca and Mg accumulation in all organs were higher in Mg_1.5 than in Mg₀. The K and Mg interactive treatments had significant reciprocal effects on K, Ca and Mg accumulation at flowering and fruiting stages (P<0.01). Compared to seedling stage, the K allocation to leaf tent decreased at flowering and fruiting stages, and Mg allocation to roots under K₂₀₀ tent decreased at flowering stage. The main component scores of Mg_1.5K₄ at flowering and fruiting were higher than that of other treatments. Conclusions Excessive K concentration inhibited the absorption, accumulation and rational distribution of K, Ca and Mg in various organs of tomato, and caused plant death at fruit setting stage. Suitable Mg supply concentration promotes the accumulation of biomass, and K, Ca and Mg nutrients. Mg deficiency aggravated the adverse effects of excess K on tomato plants, especially at fruiting period, while excess K inhibits the absorption of Mg, which in turn affects the absorption of Ca. Therefore, adequate mineral nutrition, especially the balanced supply of K and Mg, should be used for tomato cultivation.

Effects of different amounts of stover mulching on improving photosynthetic characteristics and yield of maize in Mollisol of Northeast China under long-term no-tillage

LU Yue, BAO Xue-lian, HUO Hai-nan, Yang Ya-li, ZHAO Yue, XIE Hong-tu, LIANG Chao, HE Hong-bo

Accepted Manuscript doi: 10.11674/zwyf.2022507

Abstract(96)

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Objectives This study investigates maize yield and photosynthetic characteristics under the influence of stover mulching and long-term no-tillage in the mollisol of Northeast China. We aim to propose a suitable no-tillage and stover mulching technology system in the study region. Methods The conservation tillage field experiment started in 2007 with a single maize cropping system. The treatments included conventional tillage (CT) and no-tillage combined with stover mulching at 0, 33%, 67%, and 100% of the harvested maize stovers, denoted as NT-0, NT-33%, NT-67%, and NT-100%, respectively. We measured the net photosynthetic rate (Pn), stomatal conductance (Gs), transpiration rate (Tr), chlorophyll content, and leaf area at the maize seedling, jointing, and tasselling stages in 2021. Maize yield and yield components were measured at the maturity stage. Results Compared with CT, the four no-tillage treatments improved the Pn of seeding stage, Pn, Gs, and Tr across the jointing stage and tasseling stage. NT-67%、NT-100% (P<0.05) decreased the intercellular CO₂ concentration at the jointing and tasselling stages, while NT-67% and NT-100% maintained higher chlorophyll content at the tasselling stage. NT-100% recorded the highest photosynthetic efficiency at the jointing and tasselling stages, followed by NT-67%, with (P<0.05) higher values than CT, NT-0, and NT-33%. All the NT with stover mulching (NT-33%, NT-67%, NT-100%) increased the kernel number per row, 100-kernel-weight, and grain yield, and there was no significant difference (P>0.05) in yield between NT-0 and CT. The Pn values were (P<0.01) correlated with maize yield. Conclusions No-tillage combined with stover mulching was effective in increasing chlorophyll content, Pn, Gs, Tr, and the capacity of utilize intercellular CO₂ at the tasselling stage, which enhances maize yield. No-tillage combined with 67%～100% of the harvested maize stover showed a good potential for maize net photosynthetic efficiency, making it a promising approach under the no-tillage condition in the Mollisol of Northeast China.

Using waterborne polymer coated urea to realize input reduction and one-time basal application of nitrogen fertilizer in summer maize production in Shandong Province

SUN Dong-xu, MA Xiao-xiao, SHANG Qi-huan, BIAN Wen-xin, YANG Yue-chao, SHEN Tian-lin

Accepted Manuscript doi: 10.11674/zwyf.2022511

Abstract(92)

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Objectives We studied the effect of N nutrition on summer maize across the growth period under one-time basal application and 30% reduction of N input of the two slow-release urea products. Methods The release properties of urea coated with waterborne polymers (WF) and polyethylene terephthalate (PF) were studied by field release method, and the theoretical optimal blended ratio of the two coating urea products was calculated. Field experiments were carried out from 2018 to 2020 in Qingzhou and Huantai, Shandong. Conventional N rate (N225 kg/hm², level 1) and 30% reduction (N157.5 kg/hm², level 2) were setup, and ordinary urea (BF), WF, PF and WF to PF in 1∶0.52 (MF) were used as N resource treatments under each N level, with no N fertilizer as control (CK). Common urea BF1 and BF2 treatment were applied two times (basal and topdressing), while the coated urea products were all basal-applied one time. Soil N content in the key growing stages of maize were determined. The yield, N uptake and urea use efficiency of summer maize were investigated at harvest. Results The total N release rates of WF (>90%) was higher than that of PF (80%) during the whole maize growing period in the two fields, and the release characteristics of WF was more consistent with the nitrogen demand of summer maize at the early growth stage. In Qingzhou and Huantai, the average maize yield of three seasons among the fertilizer treatments, except BF2, were not significantly different. The maize yield in BF2 was significantly lower than in BF1, and only WF2 produced higher (p<0.05) yield than BF2. Compared with BF1, all the six coating urea treatments increased the average apparent nitrogen utilizationof three seasons in the two experimental sites. WF2 and PF2 in Qingzhou increased the average agronomic efficiency by 49% and 32.5%, while only WF2 in Huantai increased that by 40.9%. At tasseling and maturing stages of maize in Qingzhou, the soil NH₄⁺-N content in WF1, WF2, PF1 and PF2 treatments were significantly higher than in BF1; the soil NO₃⁻-N content in WF1 and PF1 were higher than BF1, and those in WF2 and PF2 were similar with BF1. In Huantai, the soil NH₄⁺-N contents were similar among all the treatments at tasseling and maturing, while the soil NO₃⁻-N contents in the PF and WF treatments were significantly higher than in BF1. Conclusions Compared with resin coated urea, the new waterborne-polymer coated urea has higher N release rate, and more consistent release characteristics with the N requirements of summer maize. Under the condition of reducing 30% conventional N input and one-time basal application, both kinds of the coated urea can provide higher N supply at the tasseling and maturing stage of maize, thereby maintaining a stable yield and N uptake of summer maize, and improving the nitrogen use efficiency and agronomic efficiency. The new waterborne-polymer coated urea showed more stable effect on yield and agronomic efficiency than polyethylene terephthalate coated urea.

Soybean-corn intercropping increases fungal community structure and diversity in red soil aggregates

YANG Ji-fen, LI Yong-mei, LI Chun-pei, LU Mei, ZHAO Ji-xia

doi: 10.11674/zwyf.2022522

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Objectives We studied the fungal community structure and diversity in different soil aggregate particle sizes under intercropping conditions. We aimed to understand the beneficial effect of intercropping from the perspective of microbial properties. Methods The long-term positioning experiment started in 2013 and was located at the experimental base of Yunnan Agricultural University. The maize and soybean test cultivars were Qiaodan 6 and Diandou 7. The cropping pattern treatments were soybean and maize intercropping (MD), maize monoculture (MM), soybean monoculture (DD), and fallow (CK). At the maize tasselling stage in 2021, 0−20 cm soil samples were collected, and the wet sieving method was used to screen the soil aggregates into 2−1 mm, 1−0.25 mm, and <0.25 mm particle size groups. The percentage of each aggregate group in the total soil aggregate and their mean weight diameter (MWD) were determined. The organic carbon, total N, and available N, P, and K were analyzed in each group. The fungal community structure was analyzed using Illumina MiSeq Next Generation sequencing. Results MD (P<0.05) increased the percentage and MWD in 2−1 mm aggregates, the organic carbon content in 2−1 mm aggregates, anf alkali-hydrolyzed N in 1−0.25 mm and <0.25 mm aggregate. All the DD, MM, and MD treatments increased the Chao1 index and OTU number in 2−1 mm and 1−0.25 mm aggregates than CK. The relative abundance of Basidiomycota in 2−1 mm and 1−0.25 mm aggregates in MD was 85.7% and 133.3% higher than in DD, and 194.1% and 69.7% higher than in MM, respectively. The relevant abundance of Chytridiomycotal in MD was 20.0% and 333.3% higher than in MM, Chaetomium in 2−1 mm, 1−0.25 mm, and <0.25 mm aggregates in MD was 68.7%, 80.0%, and 53.2% higher than in MM, respectively. MD had 60.0% and 72.4% higher relative abundance of Mortierellomycotaand Mortierella than MM in 2～1 mm aggregate. PCoA analysis showed that the fungal community significantly differed among particle sizes and planting modes. RDA showed that soil organic carbon, available N, total N, and α-diversity index were significantly correlated. The heatmap analysis showed that basidiomycetes were (P<0.05) correlated with soil total N, alkali-hydrolyzed N, and organic carbon. Conclusions Soil organic carbon, total N and alkali-hydrolyzed N are the main drivers of variation in the structure and diversity of the fungal community. Compared with monoculture, intercropping promoted the formation and stability of macroaggregates. It also increased soil organic carbon, available N, dominant fungi and diversity of macroaggregates. Thus, soybean-corn intercropping pattern changes the distribution of aggregates, along with changes in soil fungal community and diversity, which is conducive to improving soil microenvironment, quality, and health.

Effects of boron application rate on double-low rapeseed yield and quality

GENG Guo-tao, LU Zhi-feng, ZHANG Yang-yang, REN Tao, XIAO Guo-bin, LU Jian-wei

doi: 10.11674/zwyf.2022470

Abstract(214)

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Objectives The main winter oilseed rape production areas in China are generally deficient in boron, which seriously affecting rapeseed yield and quality. This study analyzed the effects of different borax application rates on the yield and quality of rapeseed. Methods Field experiments were conducted in Chizhou of Anhui, Wanzhou of Chongqing, and Nanchang of Jiangxi from 2020 to 2021. The soil in the three experimental sites was B-deficient, and the tested rapeseed cultivars were low in erucic acid and sulfur glycosides. Four borax application rates were set up, including 0, 4.5, 9.0, and 13.5 kg/hm², and denoted as B0, B4.5, B9.0, and B13.5. The yield, seed boron concentration, main quality parameters, and fatty acid fractions of rapeseed were determined, and the correlations among the factors were analyzed. Results Compared with B0, B13.5 recorded the highest yields in Chizhou, Wanzhou, and Nanchang, with 296, 818, and 715 kg/hm² increase, corresponding to 20.7%, 42.6% and 38.3%, respectively. However, the yields among the three B treatments were not (P>0.05) different. The yield increase was attributed to the increased pod number per plant and the seed number per pod. Compared with B0, B4.5, B9.0, and B13.5 (P<0.05) increased harvest density and 1000-seed-weight by 30.5% and 7.4% in Nanchang and Wanzhou, respectively, but not in Chizhou. Compared to B0, all other treatments (P<0.05) increased the oil, oleic, and linolenic acid contents in rapeseed, with a maximum increase of 10.3%, 15.8%, and 22.7%, respectively. Similarly, a maximum reduction of 19.4%, 36.1% and 14.1% in linoleic, palmitic, and stearic acid contents were recorded. Whereas rapeseed’s protein content did not change, the oil and protein yield (P<0.05) increased significantly, reaching a maximum of 53.4% and 53.2%, respectively. B application showed the risk of increasing erucic acid and sulfur glycosides. Compared to B0, B4.5 increased erucic acid and sulfur glycosides by 19.1% and −3.0% on average and 57.3% and 35.8% by B13.5. However, the contents were within the designated thresholds by the national standards for edible rapeseed oil and forage cake meal for double-low rapeseed (13.5 kg/hm²). Boron application increased rapeseed B content, with the highest increase of 56.9%, 26.3%, and 33.8% in Wanzhou, Chizhou, and Nanchang, respectively. Rapeseed B content was (P<0.05) positively correlated with oil, protein, oleic, and linolenic acid and negatively correlated with linoleic and palmitic contents. Rapeseed B content indirectly increases the oil or protein yield by increasing yield and oil content. Conclusions Boron application effectively enhances the yield of double-low oilseed rape by increasing the plant’s productivity. Further, it improves the quality and quantity of oilseed derived from the plant, which enhances protein yield. Considering the linoleic and palmitic acid risk, the recommended boron application rate is 4.5−9.0 kg/hm².

Effects of exogenous regulatory substances on physiological characteristics and gene expression of rice seedlings under alkali stress

SHI Ya-fei, MIN Wei-fang, BAI Xiao-rong, SHE Yang-mengfei, TIAN Hao-tian, LUO Cheng-ke

doi: 10.11674/zwyf.2022582

Abstract(286)

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Objectives High content of alkaline salt is the main obstacle restricting rice growth and development in alkaline soils. Here, we compared the effects of three commonly used exogenous regulatory substances on rice seedling growth, physiological characteristics, and related gene expression under alkali stress. Methods The experiment was conducted using a hydroponic method. Zhonghua 11 was used as the test material, and exogenous regulatory substances included glycine betaine (GB), sodium nitroprusside (SNP), and melatonin (MT). Standard nutrient solution was used as control (CK), and alkaline nutrient solution with CO₃²⁻ and HCO₃⁻ concentrations of 20 mmol/L and pH 8.65 was used as alkaline stress (AS). Rice seedlings were grown for 21 days and sprayed with distilled water, GB, SNP, and MT under CK and AS conditions including eight treatments. After three days of continuous treatment, rice seedlings were harvested to determine phenotypic, physiological indexes, and gene expression levels. The relief effects of exogenous regulatory substances on rice alkaline stress were evaluated using principal component analysis and weighted comprehensive evaluation combined with membership function. Results Compared with AS, AS+GB, AS+SNP, and AS+ MT (P<0.05) reduced leaf curl rate, increased seedling survival rate, and the fresh and dry weight of shoot and root of rice seedlings. These treatments also decreased the content of malondialdehyde (MDA) and reactive oxygen species (H₂O₂,

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) in rice seedlings while increasing the content of proline (Pro) and soluble sugars (SS), as well as the activities of SOD, POD, and CAT in the rice seedlings. Furthermore, the expression levels of proline synthase gene OsP5CS and antioxidant enzyme synthesis genes OsCu/Zn−SOD, OsPOX1, and OsCATC were (P<0.05) induced. Under alkali stress, exogenous regulatory substances affected the expression levels of endogenous GB, NO, and MT-related synthetic enzyme genes in rice seedlings, with the SNP significantly decreasing the expression level of the OsNOA1 gene and increasing that of the OsNIA2 gene. MT (P<0.05) increased the expression level of the OsASMT1 gene and decreased the expression level of the OsSNAT gene, and GB (P<0.05) decreased the expression level of the OsBADH1 and OsCMO genes. Correlation analysis showed that OsCu/Zn−SOD was (P<0.05) positively correlated with SOD, CAT, and shoot fresh weight. Similarly, SOD was significantly and positively correlated with fresh shoot weight, and OsP5CS was positively correlated with Pro and shoot dry weight. H₂O₂ and

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were negatively correlated with OsCu/Zn−SOD, SOD, and fresh shoot weight. In contrast, H₂O₂ was (P<0.05) positively correlated with leaf curl rate, while

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was negatively correlated with soluble sugars (SS). Principal component analysis integrated the 16 measurement indicators into six components, with a cumulative contribution rate of 87.91%. The membership function combined with the weight method was used for a comprehensive evaluation; the D value of SNP was the largest, followed by those of GB and MT. Conclusions GB, SNP, and MT can alleviate alkali stress and enhance rice alkali tolerance by regulating rice seedling morphology, physiological characteristics, and gene expression. The order of efficiency of alkali stress alleviation by the treatments was SNP>GB>MT.

Mechanism of elicitors on increasing plant biomass and bioactive compound accumulation in Cyclocarya paliurus

LIN Quan, WANG Shu-yang, FAN Wen-jie, XU Xian-gang, FU Xiang-xiang

Accepted Manuscript doi: 10.11674/zwyf.2022487

Abstract(110)

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Abstract:
Objectives Cyclocarya paliurus is one of the important herbs in China. In this study, we explored the effects of elicitors on the growth, resistance, and medicinal qualities of C. paliurus to provide a theoretical basis for its efficient cultivation. Methods A pot experiment was conducted using 2 years-old container seedlings of C. paliurus. The tested bio-elicitors were fungal elicitor (Trichoderma asperellum, F), bacterial elicitor (Bacillus amyloliquefaciens, B), and abiotic elicitor was Chitosan (C), and the combination of biotic and abiotic elicitors (FC and BC), and an equal amount of water control (CK). Upon harvesting of C. paliurus, the plant height and ground diameter, root, stem, and leaf biomass were measured. The leaf C, N, and P contents, superoxide dismutase (SOD), peroxidase (POD) activity, and bioactive compound contents were measured. The cultivation substrate samples were taken to analyze the pH, total N, and available N and P contents. Results Compared with CK, the elicitors did not (P>0.05) impact the relative growth rate of seedlings but significantly increased the leaf biomass; F exhibited the highest relative growth increase, B, C, and FC had similar but higher effect than BC. The five elicitors (P<0.05) increased leaf SOD activity in the order FC>F≈C>BC>B>CK; only F and FC (P<0.05) stimulated POD activity. The elicitor treatments showed a different effect on the bioactive component and yield of C. paliurus. F, FC, B, and BC increased the yield and total flavonoids, triterpenes, and polyphenols. Notably, the effect of F and B were higher than FC and BC, respectively. Only F and C treatments increased the total polysaccharides, with the effect of C higher than F. Cyclocaric acid B is a unique triterpenoid monomer in C. paliurus, and F and B increased its content by 77.8% and 200%, compared with CK. The application of elicitors changed the chemical properties of cultivation substrates. F and FC elicited (P<0.05) alterations in the pH of the cultivation substrate, whereas B and BC resulted in substrates with 163% and 167% higher available phosphorus and nitrogen contents, respectively, compared to CK. According to the results of the correlation analysis, the leaf N and P contents were positively correlated with the availability of soil nutrients (P<0.05). The total flavonoids in biologically active substances also showed a significant positive correlation with available soil nutrients, while the total triterpenoid was positively correlated with soil available nutrients and leaf P content (P<0.05). Furthermore, the total polyphenols exhibited a positive correlation (P<0.05) with SOD and POD activities, but negative correlation (P<0.01) with leaf N/P ratio. The total polysaccharide content was positively correlated with SOD activity (P<0.05). Conclusions The fungal, bacterial, and chitosan elicitors enhanced the leaf yield and quality of C. paliurus efficiently. The fungal elicitor, Trichoderma asperellum, could improve the soil pH and total N, enhance the SOD and POD activity, and stimulate bioactive compound accumulation in Cyclocarya paliurus leaves. The bacteria elicitor, Bacillus amyloliquefaciens, could enhance leaf enzyme activity and bioactive accumulation by improving available soil N and P, which is beneficial for leaf growth. The bacteria elicitor showed a weaker effect than the fungal elicitor in bioactive compound accumulation, while Chitosan did not show a satisfactory effect except for the accumulation of leaf polysaccharides. Fungal elicitor is recommended for C. paliurus cultivation.

Effects of lignin-based humic acid liquid fertilizer on soil biochemistry and banana seedling growth

LIANG Jia-min, HUO Peng-ju, GUO Tao, ZHANG Li-dan, FAN Xiao-lin, SUN Shao-long

Accepted Manuscript doi: 10.11674/zwyf.2022465

Abstract(229)

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Abstract:
Objective The effects of humic acid liquid fertilizer supplemented with lignin (lignin-based humic acid liquid fertilizer: LHF) on nutrients, enzyme activities, microorganisms of red soil in southern China and banana seedling growth were studied to provide reference for the improvement of soil fertility and the utilization of papermaking by-products. Methods The seeds of banana were cultured in pot experiment. The tested soil was red soil of Guangzhou, and the tested banana seedling was at 5-true-leaves stage. There were 6 treatments in the experience, which were no fertilizer (CK), conventional liquid fertilizer (CF), humic acid liquid fertilizer (HF), LHF with ligin 10 g/L (LHF₁₀), 30 g/L (LHF₃₀), and 50 g/L (LHF₅₀), respectively. All kind of fertilizers contain the same amount of nitrogen, phosphorus and potassium. The plants and soil were sampled and stored when seedlings have been cultivated for three months. And then the physiological indexes of plant growth, soil physical and chemical properties, soil enzyme activities and soil microbial quantity were measured. Result 1) Compared with CK, all fertilization treatments could significantly increase the contents of soil total nitrogen, ammonium nitrogen, available phosphorus and available potassium. With increased content of lignin, the content of soil ammonium nitrogen, nitrate nitrogen and total nitrogen appeared a decreasing trend. Compared with the CF treatment, low concentration of lignin significantly increased content of ammonium and total nitrogen in the soil, while high concentration of lignin clearly decreased content of nitrogen in the soil. The content of available potassium in the soil decreased with increased content of lignin , treatments of LHF₃₀ and LHF₅₀ were obviously lower than treatments of CF and HF. Compared with CF treatment, treatment of HF and all treatments of LHF visibly augmented available P in the soil (10.45%−22.43%), and the content of available P in LHF₅₀ treatment was distinctly higher than that in HF treatment. The organic matter content of soil improved with increased content of lignin, but the organic matter content of lignin-based humic acid liquid fertilizer was lower than that of HF treatment. 2) In terms of soil enzyme activity, compared with the CF treatment, the urease activity of each LHF treatment was markedly decreased (21.58%−31.29%). The activity of sucrase and acid phosphatase were improved by ligin-based humic acid liquid fertilizer. For sucrase activity, treatment of LHF₃₀ visibly enhanced by 49.35% compared with CF treatment. The activity of acid phosphatase in each LHF treatment was higher than that in CF treatment, but lower than that in HF treatment. The nitrate reductase activity of LHF₅₀ treatment was lower than that of CF treatment, and the other fertilization treatments were higher than that of CF treatment. Compared with CF treatment, HF treatment and LHF₁₀ treatment significantly increased the nitrate reductase activity by 40.0% and 32.0%, respectively. 3) The quantity of three kinds of soil microorganisms in the experiment was: CK<CF<HF<LHF. The number of bacteria and actinomycetes in LHF₃₀ treatment was the highest, while the number of fungi in LHF₅₀ treatment was the highest. Both bacteria, fungi and actinomycetes, LHF treatments were higher than the number of CF treatment and HF treatment. 4) Regarding the plant height and stem diameter of banana seedlings, treatments of LHF were higher than the CF treatment, among which there was a significant difference in plant height, but no significant difference in stem diameter. Both fresh weight and dry weight of plants in LHF treatments were higher than those in CF treatment, and shoot fresh and dry weight of LHF treatments were higher than that in HF treatment. In both aboveground and underground parts, the absorption and accumulation of phosphorus and potassium in lignin-based humic acid liquid fertilizer treatments were higher than those in CF and HF treatment. Conclusion Applying lignin based humic acid liquid fertilizers could improve the contents of mineral nitrogen, total nitrogen, available phosphorus, the activities of sucrase, acid phosphatase and nitrate reductase in soil, but obviously reduced the activity of soil urease, which also markedly promoted the growth and reproduction of soil microorganisms. For crops, the application of lignin-based humic acid liquid fertilizer could promote the growth and development of banana, and promoted the absorption and accumulation of nutrients in banana seedlings.