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Effects of compound water retention agent on soil nutrients and soil microbial diversity of winter wheat in saline-alkali land

Abstract

Water retention agents have been applied to agricultural fields to improve the growing conditions of crops, but the potential of these agents in saline soils is poorly understood. The effects of compound water retention agents on nutrient content and soil microbial diversity of saline winter wheat soils were investigated in a field experiment with no water retention agent (CK) and 30 kg hm2 of commercial attapulgite water retention agent (T4) as control and different amounts of compound water retention agents as treatments (15 kg hm2-T1, 30 kg hm2-T2, 45 kg hm2-T3). The study showed that the application of water retention agents increased the soil water content. From anthesis to harvest stage, the decreases in soil alkali-hydrolyzed nitrogen, available phosphorus, available potassium and organic matter content were greater in T2 and T3 than in the other treatments. At harvest stage, the alkali-hydrolyzed nitrogen content of T2 was significantly lower than that of CK and T4 6.19–8.83% and 4.62–5.39%, respectively. The soil available phosphorus content of T2 was significantly lower than that of CK 8.14–8.83%. The relative abundance of Actinobacteria, Proteobacteria and Acidobacteria as well as the Shannon and Simpson indices of T2 reached their maximum at harvest stage. T2 showed the best performance in terms of overall number of OTUs. The compound water retention agent may regulate soil nutrient content and accelerate plant nutrient accumulation by regulating soil water content and soil microbial abundance composition.

Graphical abstract

Introduction

Wheat is one of the most important food crops in the world [1, 2], the nutritional value and economic value of which are very considerable as it provides vital quantities of high-quality starch, protein, vitamins, and other nutrients [3, 4]. As the world’s largest producer and consumer of wheat, the development of wheat industry in China is of great significance to guarantee not only social stability, but also world food security [5, 6]. However, there are still many typical abiotic stresses affecting the sustainability of wheat production worldwide, soil salinization is one of the most challenging problems that restricts the normal growth and production of wheat. In China, saline-alkali land accounts for more than 20% of the total arable land area, and problems such as soil compaction, poor permeability, slow nutrient release, and changes in soil physical and chemical properties are prevalent [7], as well as plant osmotic stress, nutrient deficiency due to salt-related imbalance and oxidative stress on plants [8]. Therefore, there are many problems in planting wheat on saline-alkali land, such as low yield and poor quality [9].

Water retention agent, also called soil amendment, and super absorbent resin, is a kind of super water absorption, water retention performance of the new polymer resin, its principle is mainly the use of natural polymer materials, adding monomer, initiator, crosslinking agent polymerization [10]. Water retention agent can quickly absorb and maintain a lot of water, and can repeatedly lose water and absorb water, applied to the soil can play the role of water storage and moisture retention, can effectively improve the soil structure, promote the formation of soil aggregates [11]. It is a novel product widely accepted by farmers after chemical fertilizer, pesticide and plastic film, which can effectively improve the drought resistance of crops and save water resources [12]. Water retention agent used in field production can fully absorb and maintain a large amount of water under the condition of sufficient rain or irrigation, while when the soil is dry and short of water, it can slowly release water for crop utilization and improve water use efficiency [13, 14]. Therefore, water retention agent is a new kind of polymer chemical water saving material with broad application prospect [15].

Water retention agent has been used in saline-alkali land improvement and saline-alkali land cultivation due to its excellent functions of water storage and soil structure improvement, but there are few relevant types of research and the mechanism is not completely clear [16,17,18]. Therefore, this study explored the effects of compound water retention agent on soil nutrients and soil microbial diversity of winter wheat in saline-alkali land, providing theoretical and practical basis for the improvement of saline-alkali land by water retention agent and the application of water retention agent in winter wheat cultivation in saline-alkali land.

Materials and methods

Experimental location

The field experiments were conducted in the experimental base of Qingdao Agricultural University (N37°0 ′27.24″, E119°22′ 15.79″) from October 2019 to June 2020 and from October 2020 to June 2021. The soil was moderately saline-alkali soil (salt content 0.32%), pH value 8.4, alkali-hydrolyzed nitrogen 81.2 mg kg−1, available phosphorus 22.5 mg kg−1, available potassium 171.4 mg kg−1, organic matter 12.0 g kg−1. Precipitation during wheat growth period is shown in Fig. 1. Precipitation from April to June of 2021 is higher than that from April to June of 2020.

Fig.1
figure 1

Precipitation and air temperature during wheat growth period

Materials

Jimai 44 (Triticum aestivum L.) was used as experimental material. The compound fertilizer (N–P2O5–K2O:18–20–7) and attapulgite water retention agent were provided by Sinochem Shandong fertilizer Co., Ltd. and Dongying Huaye New Materials Co., Ltd. Attapulgite (chemically pure), bentonite (chemically pure) and rare earth (chemically pure) were purchased from Fujian youqiyi Pharmaceutical Trading Co., Ltd. Biochar (superior pure, Zhengzhou Niute Agricultural Technology Co., Ltd) was sieved through 300 meshes and then dried for standby. Acrylic acid and acrylamide (analytical pure, Macklin Biochemical Co., Ltd, Shanghai, China), span 60 (chemically pure, Sinopharm Chemical Reagent Co., Ltd, Shanghai, China), potassium persulfate (analytical pure, Kermel Chemreagent, Co., Ltd., Tianjin, China), and N, N'-methylene bisacrylamide (analytical pure, BASF Chemical Co., Ltd, Tianjin, China) were used as purchased.

Preparation of the hydrogel

The compound water retention agent was made using the method of Dong with minor modifications [19]. Mix the right amount of acrylic acid and acrylamide, add the right amount of attapulgite (58%), rare earth (14%), biochar (14%), bentonite (14%), and span 60 in turn, stir and mix, pass nitrogen gas for 30 min, then add cross-linker and initiator in a nitrogen atmosphere, dry to constant weight at 75 ℃ after the completion of the polymerization reaction, mechanical crushing and spare.

Experimental design

A randomized block design was used. A total of 5 treatments were set, with 3 repetitions. Each plot was 15 m2 (3 × 5 m). All treatments were fertilized with 750 kg hm2 of compound fertilizer as the base. Treatments were: Control (CK): no application of water retention agents; Treatment 1 (T1): application of 15 kg hm2 of compound water retention agent; Treatment 2 (T2): application of 30 kg hm2 of compound water retention agent; Treatment 3 (T3): application of 45 kg hm2 of compound water retention agent; Treatment 4 (T4): application of 30 kg hm2 of commercialized attapulgite water retention agent.

The application rate of the water retention agent was developed based on the results of previous studies [20]. Before sowing, the compound fertilizer and water retention agent will be fully mixed and evenly, and then evenly spread in each district, the way of tillage it into the soil. The sowing rate was 150 kg hm−2. All fertilizers were used as base fertilizer for one time fertilization, and no topdressing operation was carried out later.

Determination items and methods

Samples were taken from anthesis stage to harvest stage at an interval of 10 days. Two soil layers of 0–20 cm and 20–40 cm between wheat rows were drilled with soil. After natural air drying, it will be broken, respectively, through 0.25 and 1 mm screen for reserve. It was used to determine the content of alkali-hydrolyzed nitrogen, available phosphorus, available potassium and organic matter in soil. Another 20 g was quickly put into the aluminum box and closed, and brought back immediately to measure the soil moisture content. Soil samples of 0–20 cm layer were taken into a 5-ml centrifuge tube, placed in liquid nitrogen immediately, and then transferred to a refrigerator at – 80 ℃ for storage.

The aluminum box method was used for soil moisture content. The aluminum box containing fresh soil samples was dried at 105 ℃ for 12 h and weighed. The alkali-hydrolyzed nitrogen (a general term for ammonium nitrogen, nitrate nitrogen, and organic nitrogen that is readily hydrolyzed) content in soil was determined by alkali diffusion method. The content of available phosphorus in soil was determined by molybdenum–antimony resistance colorimetry. The content of soil available potassium was determined by flame photometer with ammonium acetate extraction.

Soil microbial diversity was measured, sequenced and analyzed using Illumina Miseq high-throughput sequencing platform by Shanghai Personalbio Biotechnology Co., LTD. A highly variable V3V4 region of about 468 bp in length of 16S rRNA gene was used. NEB Q5 DNA high-fidelity polymerase was used for PCR. Sequencing primers were: 338F (5′-barcode + ACTCCTACGGGAGGCAGCA-3′), 806R (5′-GGACTACHVGGGTWTCTAA T-3′). PCR system is shown in Table 1.

Table 1 PCR system

TruSeq Nano DNA LT Library Prep Kit of Illumina was used to build the Library. Two-terminal sequencing of 2 × 250 bp was performed using MiSeq Reagent Kit V3 (600cycles) on a MiSeq machine. First, the library (Index not repeatable) needed to be used on the computer was diluted to 2 nM by gradient, and then the sample was mixed in proportion to the required amount of data. The mixed library was denatured into a single chain by 0.1 N NaOH for computer sequencing.

Data processing

Microsoft Excel 2019 and SPSS 26 software were adopted for data processing and one-way ANOVA. Duncan’s new multiple range method was applied for multiple comparisons (P ≤ 0.05). SigmaPlot 14.0 and Origin 2022 software were used for graphing.

Results and analysis

Soil moisture

As shown in Fig. 2a, the soil moisture content of the 0–20 cm soil layer in the different treatments differed relatively significantly in each period from 2019 to 2020. Overall, treatments with water retention agent application (T1, T2, T3, and T4) were higher than CK, with T3 reaching the maximum soil moisture content in all periods and T2 the second highest. The soil moisture content of T2 and T3 was significantly higher than that of CK from anthesis to maturity of wheat. At anthesis, the soil moisture content of T2 was significantly higher than that of T4. The changes in different treatments in soil moisture content in the 0–20 cm soil layer from 2020–2021 were basically the same as those in 2019–2020 (Fig. 2c). As illustrated in Fig. 2b, d, soil moisture content in the 20–40 cm soil layer of different treatments did not differ significantly in all periods and performed basically the same in both years.

Fig. 2
figure 2

Effects of water retention agents on soil moisture of winter wheat in saline-alkali land. Different letters above the error line indicate that the difference between treatments reached a significant level (P < 0.05)

Soil nutrient contents

Soil alkali-hydrolyzed nitrogen

As indicated in Fig. 3, the soil alkali-hydrolyzed nitrogen content in different treatments showed a decreasing trend with the increase of days after anthesis in both 0–20 cm and 20–40 cm soil layers, and the content and the reduction of soil alkali-hydrolyzed nitrogen in 0–20 cm soil layer were greater than that in 20–40 cm soil layer. The two soil layers, 0–20 cm and 20–40 cm, showed the greatest decrease from 10 days after anthesis to 30 days after anthesis, and the decrease in soil alkali-hydrolyzed nitrogen was significantly greater in all treatments (T1, T2, T3, and T4) with water retention agent application than in CK. As demonstrated in Fig. 3a, c, the decreases in alkali-hydrolyzed nitrogen for each treatment in the 0–20 cm soil layer in 2019–2020 were T2 (34.4%) > T3 (31.3%) > T4 (27.9%) > T1 (26.0%) > CK (20.3%), and the decreases in alkali-hydrolyzed nitrogen for each treatment in the 0–20 cm soil layer in 2020–2021 were T2 (30.4%) > T3 (29.3%) > T1 (23.8%) > T4 (23.6%) > CK (20.5%). In 2019–2020, the alkali-hydrolyzed nitrogen content of T2 and T3 was significantly higher than that of CK, and that of T2 was significantly higher than that of T4 in the 0–20 cm soil layer at anthesis. At 20 days after anthesis, the alkali-hydrolyzed nitrogen content of T2 was not significantly different from that of CK. At harvest, the alkali-hydrolyzed nitrogen content of T2 was significantly lower than that of CK and T4 by 8.83% and 5.39%, respectively, and the difference between T2 and T3 was not significant. In the 20–40 cm soil layer, soil alkali-hydrolyzed nitrogen content was significantly lower in T2 and T3 than in CK and T4 at 20 days after anthesis and at harvest. The trend of alkali-hydrolyzed nitrogen content in different treatments in 2020–2021 was similar to that in 2019–2020. At harvest, the alkali-hydrolyzed nitrogen content of T2 in the 0–20 cm soil layer was significantly lower than that of CK and T4 by 6.19% and 4.62%, respectively.

Fig. 3
figure 3

Effects of water retention agents on soil alkali-hydrolyzed nitrogen content of winter wheat in saline-alkali land. Different letters above the error line indicate that the difference between treatments reached a significant level (P < 0.05)

Soil available phosphorus

From the beginning of the anthesis of wheat, the soil available phosphorus content in 0–20 cm and 20–40 cm soil layers showed a decreasing trend with the increase in the number of days after anthesis, with a greater decrease from 10 days after anthesis to 30 days after anthesis. 0–20 cm soil layer had higher available phosphorus content than 20–40 cm soil layer (Fig. 4). In 2019–2020, from the anthesis stage to 10 days after anthesis, soil available phosphorus content was significantly higher in the 0–20 cm soil layer in T2 and T3 than in CK, and higher in T2 than in T4, but the differences were not significant. From 20 days after anthesis to the harvest stage, the soil available phosphorus content of T2 was lower than that of the other treatments. At the harvest stage, the soil available phosphorus content of T2 was significantly lower than that of CK by 8.14% (Fig. 4a). In the 20–40 cm soil layer, the available phosphorus content of T3 was significantly higher than that of CK from the anthesis to 10 days after anthesis, and the difference between T2 and T4 was not significant. At the harvest stage, the soil available phosphorus content of T2 was lower than that of CK and T4 by 8.5% and 4.39% (Fig. 4b). The trend of soil available phosphorus content in 2020–2021 was basically the same as that in 2019–2020 (Fig. 4c, d).

Fig. 4
figure 4

Effects of water retention agents on soil available phosphorus content of winter wheat in saline-alkali land. Different letters above the error line indicate that the difference between treatments reached a significant level (P < 0.05)

The changes of soil available phosphorus content in the 0–20 cm soil layer are shown in Fig. 4a, b, and the specific reduction of soil available phosphorus content in the 0–20 cm soil layer from 2019 to 2020 was T2 (40.4%) > T3 (36.1%) > T1 (34.4%) > T4 (31.5%) > CK (25.5%). And the reduction of soil available phosphorus content for each treatment in 2020–2021 was specifically shown as T2 (34.6%) > T3 (32.7%) > T4 (31.3%) > T1 (29.3%) > CK (25.6%). Furthermore, the changes of soil available phosphorus content in the 20–40 cm soil layer are presented in Fig. 4c, d. The decrease of soil available phosphorus content in each treatment from 2019 to 2020 was specifically shown as T2 (37.8%) > T3 (35.5%) > T4 (34.0%) > T1 (33.8%) > CK (28.1%), and the decrease of each treatment from 2020 to 2021 was specifically shown as T2 (36.9%) > T3 (33.1%) > T1 (28.2%) > T4 (26.3%) > CK (23.4%).

Soil available potassium

Soil available potassium content of different treatments showed a gradual decrease with the increase of days after anthesis in wheat, with a greater decrease from 10 days after anthesis to 30 days after anthesis (Fig. 5). In 2019–2020, the soil available potassium content of T2 and T3 in the 0–20 cm soil layer was significantly higher than that of CK and T4 from the anthesis stage to 10 days after anthesis. At 20 days after anthesis and 30 days after anthesis, the differences in available potassium content among CK, T1, T2, and T3 were not significant, but all were lower than that of T4 (Fig. 5a). In the 20–40 cm soil layer, from 10 days after anthesis to harvest, the differences in the available potassium content between T2 and CK and T4 were not significant (Fig. 5b). The trend of soil available potassium content in 2020–2021 was basically the same as that in 2019–2020 (Fig. 5c, d).

Fig. 5
figure 5

Effects of water retention agents on soil available potassium content of winter wheat in saline-alkali land. Different letters above the error line indicate that the difference between treatments reached a significant level (P < 0.05)

As shown in Fig. 5a, b, the decreases in soil available potassium content were significantly greater in all treatments from 2019 to 2020 than in CK, with larger decreases of 21.8% and 19.5% in T3 and T2, respectively. The decreases in soil available potassium content were greater in T3 (22.9%) and T2 (20.9%) than in CK (12.8%) and T4 (14.3%) from 2020 to 2021. Figure 5c, d demonstrates the trend of changes in soil available potassium content in the 20–40 cm soil layer with increasing days after anthesis. And the decrease in soil available potassium content for each treatment from 2019 to 2020 was shown as T3 (24.1%) > T2 (21.7%) > T4 (17.0%) > T1 (16.9%) > CK (14.5%). The decrease of available potassium content in each treatment from 2020 to 2021 was shown as T3 (25.2%) > T2 (22.1%) > T4 (18.2%) > T1 (17.3%) > CK (14.8%).

Soil organic matter

The organic matter content of the different treatments in the 0–20 cm and 20–40 cm soil layers trended downward as the number of days after anthesis increased in both years. The soil organic matter content of the 0–20 cm soil layer was higher than that of the 20–40 cm soil layer in all stages (Fig. 6). The decrease in soil organic matter content was significantly greater in all treatments than in CK in the 0–20 cm soil layer. As depicted in Fig. 6a, the decrease in soil organic matter content was greater in both T3 (11.8%) and T2 (10.8%) than in CK (8.8%) in 2019–2020. In 2020–2021, the greatest decrease in soil organic matter content was observed in T3 with a decrease of 12.1% (Fig. 6c). The treatments in the 20–40 cm soil layer showed inconsistent decreases in both years. The decrease in soil organic matter content with increasing number of days after anthesis was T3 > T2 > CK > T4 > T1 in 2019–2020 (Fig. 6b), and T2 > T3 > T4 > T1 > CK in 2020–2021 (Fig. 6d).

Fig. 6
figure 6

Effects of water retention agents on soil organic matter content of winter wheat in saline-alkali land. Different letters above the error line indicate that the difference between treatments reached a significant level (P < 0.05)

Soil microbial diversity

Relative abundance of soil colonies

As shown in Fig. 7, the relative abundance of soil bacteria in each treatment with water retention agent was different from the anthesis stage to the harvest stage of wheat. The relative abundance of Actinobacteria and Proteobacteria was higher in each treatment. The relative abundance of Acidobacteria, Chloroflexi and Gemmatimonadetes decreased successively. The relative abundance of Bacteroidetes, Cyanobacteria, Firmicutes, Rokubacteria and Patescibacteria was relatively small. The relative abundance of Actinobacteria in each treatment was lower than CK at anthesis stage, 10 days after anthesis and 30 days after anthesis, and higher than CK at 20 days after anthesis and harvest stage. The relative abundance of Proteobacteria in each treatment was significantly higher than CK from anthesis stage to 10 days after anthesis, and T4 > CK > T2 > T1 > T3 in each treatment on 20 days after anthesis. The relative abundance of Proteobacteria in T2 and T3 was higher than that in other treatments T4 at 30 days after anthesis. The relative abundance of Proteobacteria was highest in T2 during harvest period. The relative abundance of Acidobacteria in each treatment was significantly higher than CK at 10 and 20 days after anthesis stage. The relative abundance of Acidobacteria in T2 and T3 was lower than that in other treatments at anthesis stage, and T2 was the highest at harvest stage. The relative abundance of Chloroflexi in all treatments treated with water retention agent was significantly higher than that in the control group from anthesis stage to 30 days after anthesis stage, and the relative abundance of T1, T2 and T4 was lower than that in CK at harvest stage. The relative abundance of Gemmatimonadetes in each treatment treated with water retention agent was significantly higher than that in the control group at 10 and 30 days after anthesis stage.

Fig. 7
figure 7

Effects of water retention agents on relative abundance of winter wheat soil colonies in saline-alkali land. Annotation: every 5 columns from left to right is a period, anthesis stage, 10 days after anthesis, 20 days after anthesis, 30 days after anthesis, and harvest stage

Soil microbial taxa at each level

As shown in Fig. 8, there was no significant difference in the number of units at the classification level of domain and phylum between different treatments during the period from anthesis stage to harvest stage. At the level of class classification, there was no significant difference in the number of microbial units at anthesis stage and 20 days after anthesis. At 10 days after anthesis and harvest stage, the number of microbial units applied with water retention agent was significantly higher than that of the control group, among which T2 was the largest, and T1 and T3 were significantly higher than other treatments at 30 d after anthesis stage. At the level of order classification, the number of microbial units in each treatment was significantly higher than that in the control group in each stage. At the level of order classification, T3 had the largest number of microbial units, and there was no significant difference between T2, T3, and T4 at anthesis stage. At the level of order classification at 10 days after anthesis, the number of microbial units was T3 > T2 > T4 > T1 > CK. At the level of order classification, the number of T3 and T4 microbial units was the highest 20 days after anthesis, but there was no significant difference between them, and there was no significant difference between T1 and T2. At the level of order classification, T1 had the largest number of microbial units at 30 days after anthesis, while there was no significant difference between T2, T3, and T4. At harvest stage, the number of T2 microbial units was the largest at order level, followed by T3 and T4. The number of microbial units at the level of family classification in each treatment treated with water retention agent was significantly higher than that in the control group at anthesis stage, 10 days and 30 days after anthesis. At anthesis stage and 10 days after anthesis, the number of microbial units at the family taxonomic level of T2 and T3 was the largest, and T1 was the largest at 30 days after anthesis stage. There was no significant difference between T1 and CK in the number of microbial units at the level of family classification at 20 days after anthesis and at harvest stage, while T2, T3 and T4 were significantly higher than CK. The number of microbial units in each treatment was significantly higher than that in the control group at the level of genus classification. The number of microbial units at the genus level of T3 was the largest at anthesis stage, T2 was the largest at 10 and 20 days after anthesis, T1 was the largest at 30 days after anthesis stage, and T2 was the largest at harvest stage. The number of microbial units at species classification level in all treatments was significantly higher than CK in all treatments except T1 at anthesis stage, and significantly higher than control group at 10 days after anthesis. As shown in Fig. 8, there was no significant difference in the number of units at the classification level of domain and phylum between different treatments during the period from anthesis stage to harvest stage. At the level of class classification, there was no significant difference in the number of microbial units at anthesis stage and 20 days after anthesis stage. At 10 days after anthesis stage and harvest stage, the number of microbial units applied with water retention agent was significantly higher than that of the control group, among which T2 was the largest, and T1 and T3 were significantly higher than other treatments at 30 days after anthesis stage. At the level of order classification, the number of microbial units in each treatment was significantly higher than that in the control group in each period. At the level of order classification at anthesis stage, T3 had the largest number of microbial units, and there was no significant difference between T2, T3 and T4. At the level of order classification at 10 days after anthesis stage, the number of microbial units was T3 > T2 > T4 > T1 > CK. At the level of order classification, the number of T3 and T4 microbial units was the highest 20 days after anthesis stage, but there was no significant difference between them, and there was no significant difference between T1 and T2. At the level of order classification, T1 had the largest number of microbial units at 30 days after anthesis stage, while there was no significant difference between T2, T3 and T4. At harvest stage, the number of T2 microbial units was the largest at order level, followed by T3 and T4. The number of microbial units at the level of family classification in each treatment treated with water retention agent was significantly higher than that in the control group at anthesis stage, 10 days and 30 days after anthesis stage. At anthesis stage and 10 days after anthesis stage, the number of microbial units at the family taxonomic level of T2 and T3 was the largest, and T1 was the largest at 30 days after anthesis. There was no significant difference between T1 and CK in the number of microbial units at the level of family classification at 20 days after anthesis stage and at harvest stage, while T2, T3, and T4 were significantly higher than CK. The number of microbial units in each treatment was significantly higher than that in the control group at the level of genus classification. The number of microbial units at the genus level of T3 was the largest at anthesis stage, T2 was the largest at 10 and 20 days after anthesis, T1 was the largest at 30 days after anthesis, and T2 was the largest at harvest stage. The number of microbial units at species classification level in all treatments was significantly higher than CK in all treatments except T1 at anthesis stage, and significantly higher than control group at 10 days after anthesis and at harvest stage, among which T2 was the largest, and there was no significant difference in each treatment at 20 days after anthesis and 30 days after anthesis. And at harvest stage, among which T2 was the largest, and there was no significant difference in each treatment at 20 days and 30 days after anthesis.

Fig. 8
figure 8

Effects of water retention agents on the number of soil microbial taxa at each level of winter wheat in saline-alkali land. Annotation: every 5 columns from left to right is a period, anthesis stage, 10 days after anthesis, 20 days after anthesis, 30 days after anthesis, and harvest stage

Soil microbial Alpha diversity index

As shown in Table 2, various indexes of soil microbial Alpha diversity varied with different treatments from anthesis stage to harvest stage. Chao1 index and Observed Species index are used to represent the richness of each sample Species. Chao1 index and Observed Species index of the treatment with water retention agent were significantly higher than those of the control group in all periods, indicating that the application of water retention agent can significantly improve the microbial richness of winter wheat soil in saline-alkali land. The richness of T3 was the highest at anthesis stage, and that of T2 was significantly higher than that of other treatments at 10 days, 20 days after anthesis and harvest stage. The richness of T4 was the highest at 30 days after anthesis stage. Shannon index and Simpson index were used to indicate the diversity of sample species. The Shannon index of T3 was significantly lower than that of CK 30 days after anthesis stage, and there was no significant difference between T1 and CK. The Shannon index and Simpson index of the treatments applied with water retention agent were significantly higher than those of CK in the other stages, indicating that the application of water retention agent could improve the soil microbial diversity of winter wheat in saline-alkali land, and the diversity of T2 in each treatment was the best from anthesis stage to harvest stage. Pielou’s Evenness index was used to represent the evenness of each sample species. At the anthesis stage, the evenness of T3 decreased, while the evenness of other treatments remained basically the same. At the 10 days after anthesis and the harvest stage, the evenness of each treatment with water retention agent was significantly higher than that of the control group, among which T2 showed the best performance. At 20 days after anthesis, the evenness of all treatments was lower than CK, and the decrease of T2 and T4 was the least. At 30 days after anthesis, there was no significant difference in evenness between T1 and CK, while other treatments were significantly higher than CK. Faith’s PD Index represents the evolutionary diversity of sample species. The application of water retention agent can significantly improve the evolutionary diversity of soil microbial species of winter wheat in saline-alkali land, and the overall performance of T2 and T3 is better. Good’s Coverage index was used to represent the coverage of the sample library, and the values of each treatment were around 0.98 to 0.99, indicating that the sequencing results could represent the real situation of microbes in the sample.

Table 2 Soil microbial Alpha diversity index under different treatments

Soil microbial OTU quantity

According to the number of OTUs in different treatments, a Venn diagram was made. The number of common OTUs and the number of specific OTUs among different treatments are shown in Fig. 9. The total amount of OTU in each treatment showed as T2 > T4 > T1 > T3 > CK. The results showed that applying water retention agent could significantly increase OTU quantity of winter wheat soil microorganisms in saline-alkali soil. The total number of OTUs specific to each treatment was T2 > T4 > T1 > CK > T3. The results showed that proper application of water retention agent could significantly increase the number of microbial specific OTUs in winter wheat soil in saline-alkali land, but excessive application would lead to the decrease of OTUs. In general, T2 has the best comprehensive performance. Both the total number of OTUs and the number of specific OTUs in T2 are significantly higher than other treatments.

Fig. 9
figure 9

Venn diagram of OTUs quantity of soil microorganisms under different treatments

Discussion

Soil moisture

This study showed that the application of a compound water retention agent could significantly increase the soil water content of saline winter wheat in saline-alkali land, which increased with the amount of compound water retention agent within a certain range. Other studies found that the application of water retention agent could increase photosynthetic rate and yield of spring millet by increasing soil water content [22]. Water retention agents, due to their strong water absorption capacity and volume change during the wet and dry cycle, can improve the basic physical properties of soil after mixing with soil, such as increase water absorption and desorption capacity, reduce bulk weight, increase total porosity, significantly improve permeability and air permeability, inhibit soil water evaporation and prevent soil leakage, thus increasing the water content of soil [21].

Soil nutrients

The stage of anthesis to harvest is an important time for wheat growth and development. Studies have demonstrated that water retention agents can retain soil nutrients and promote nutrient uptake by plants [23, 24]. In this experiment, the contents of soil alkali-hydrolyzed nitrogen, available phosphorus and available potassium of each treatment with water retention agent were significantly higher than those of the control at the anthesis stage of wheat, indicating that the application of water retention agent can preserve soil nutrients and reduce nutrient loss before the anthesis stage of wheat [25]. The compound water retention agent applied in this study contains bentonite, biochar, rare earths and albite. Bentonite is a natural layered silica-aluminate mineral clay with properties of water molecule adsorption, ion exchange and good adhesion, which can enhance the salt resistance of water retention agent [26]. Biochar has favorable physicochemical properties and nutrient regulating effects, which can improve soil bulk structure, enhance soil nutrient adsorption and retention, and meet the water demand of plant growth [27]. The water retention agent adsorbs nutrients from the soil while retaining water, reducing nutrient loss in the early stages of wheat growth, improving the microenvironment of the soil, reducing the stressing effect of salinity on wheat, and ensuring the nutrient uptake capacity of wheat and its nutrient requirements in the later stages of growth.

The soil organic matter content in different treatments was lower than that of the control from anthesis to harvest stage, and the decrease rate was higher than that of the control, which might be because the application of water retention agent increased soil water content and promoted the decomposition of organic matter into inorganic nutrients [28].

Soil microbial diversity

Soil microorganisms play an important role in the transformation and supply of soil nutrients, which can regulate organic and inorganic nutrients, decompose organic matter, and affect the availability of nutrients, thus affecting crop yield [29]. The dominant phyla in this study were Actinobacteria, Proteobacteria, Acidobacteria, Chloroflexi, and Gemmatimonadetes. Actinobacteria are active in dry environments [30], which may be the reason why the abundance of Actinobacteria in this study has decreased in most periods. Proteobacteria are related to the absorption of nitrogen and phosphorus by plants and the transformation of organic matter [31]. In this study, the treatment with water retention agent consumes more available nutrients and decomposition of organic matter. Therefore, this may be the reason why the abundance of Proteobacteria in the treatment with water retention agent in this study is significantly higher than that in other treatments. Acidobacteria is a kind of oligotrophic taxon, which can maintain metabolic activity under low nutrient conditions [32]. This suggests that the higher relative abundance of Acidobacteria in the treatment with water retention agent in this study may be due to the better utilization of available nutrients.

The species richness, diversity and evenness of soil microorganism were increased by applying water retention agent from anthesis to harvest stage. Studies have shown that soil microbes have a strong dependence on soil water, and bacteria's acquisition of nutrients mainly depends on the flow of water film in soil. Within a certain range, soil microbial richness and diversity are positively correlated with soil water content [33]. Enhanced soil nutrient cycling driven by bacterial communities is usually associated with higher microbial diversity [34, 35]. The results of this experiment are similar to those of previous studies. In this experiment, soil microbial diversity may be improved by increasing soil water content and improving soil physical and chemical properties by applying water retention agent.

Conclusions

In this study, a compound water retention agent was manufactured from acrylic acid, acrylamide, bentonite, biochar, attapulgite, rare earth, N-N methylene bisacrylamide, and potassium persulfate. (1) The application of water retention agent was beneficial in improving soil water content, soil nutrient status and soil microbial diversity compared to the treatment without water retention agent. (2) The application of the same amount of the compound water retention agent (T2) was more effective compared to the treatment with the attapulgite water retention agent (T4). In this experiment, a variety of natural and environmentally friendly materials were used as active ingredients of water retention agents, which help to reduce the stress of wheat in the harsh soil environment and avoid their own toxicity. However, since the use of chemical materials such as acrylic acid and acrylamide is still unavoidable, the current problem is to select natural and biodegradable materials as their alternatives and to maintain the reproducibility and consistency of water retention agent performance in complex field environments for mass production and agricultural applications.

Availability of data and materials

The datasets used or analyzed during the current study are available from the corresponding author on reasonable request.

References

  1. Rivera-Amado C, Trujillo-Negrellos E, Molero G, Reynolds MP, Sylvester-Bradley R, Foulkes MJ. Optimizing dry-matter partitioning for increased spike growth, grain number and harvest index in spring wheat. Field Crop Res. 2019;240:154–67. https://doi.org/10.1016/j.fcr.2019.04.016.

    Article  Google Scholar 

  2. Wang J, Liu W, Dang T. Responses of soil water balance and precipitation storage efficiency to increased fertilizer application in winter wheat. Plant Soil. 2011;347:41–51. https://doi.org/10.1007/s11104-011-0764-4.

    Article  CAS  Google Scholar 

  3. Lv X, Zhang Y, Li H, Fan S, Feng B, Kong L. Wheat belt-planting in China: an innovative strategy to improve production. Plant Prod Sci. 2020;23:12–8. https://doi.org/10.1080/1343943X.2019.1698972.

    Article  CAS  Google Scholar 

  4. Saleem Kubar M, Feng M, Sayed S, Hussain Shar A, Ali Rind N, Ullah H, Ali Kalhoro S, Xie Y, Yang C, Yang W, Ali Kalhoro F, Gasparovic K, Barboricova M, Brestic M, El Askary A, El-Sharnouby M. Agronomical traits associated with yield and yield components of winter wheat as affected by nitrogen managements. Saudi J Biol Sci. 2021;28:4852–8. https://doi.org/10.1016/j.sjbs.2021.07.027.

    Article  CAS  Google Scholar 

  5. Kong L. Maize residues, soil quality, and wheat growth in China a review. Agron Sustain Dev. 2014;34:405–16. https://doi.org/10.1007/s13593-013-0182-5.

    Article  CAS  Google Scholar 

  6. Xu J, Han H, Ning T, Li Z, Lal R. Long-term effects of tillage and straw management on soil organic carbon, crop yield, and yield stability in a wheat-maize system. Field Crop Res. 2019;233:33–40. https://doi.org/10.1016/j.fcr.2018.12.016.

    Article  Google Scholar 

  7. Liang J, Li Y, Si B, Wang Y, Chen X, Wang X, Chen H, Wang H, Zhang F, Bai Y, Biswas A. Optimizing biochar application to improve soil physical and hydraulic properties in saline-alkali soils. Sci Total Environ. 2021;771:144802. https://doi.org/10.1016/j.scitotenv.2020.144802.

    Article  CAS  Google Scholar 

  8. Cui Q, Xia J, Yang H, Liu J, Shao P. Biochar and effective microorganisms promote sesbania cannabina growth and soil quality in the coastal saline-alkali soil of the yellow river delta China. Sci Total Environ. 2021;756:143801. https://doi.org/10.1016/j.scitotenv.2020.143801.

    Article  CAS  Google Scholar 

  9. Chen X, Yaa O-K, Wu J. Effects of different organic materials application on soil physicochemical properties in a primary saline-alkali soil. Eurasian Soil Sci. 2020;53:798–808. https://doi.org/10.1134/S1064229320060034.

    Article  Google Scholar 

  10. Bandak S, Naeini SARM, Zeinali E, Bandak I. Effects of superabsorbent polymer A200 on soil characteristics and rainfed winter wheat growth (Triticum aestivum L.). Arab J Geosci. 2021;14:712. https://doi.org/10.1007/s12517-021-06824-x.

    Article  Google Scholar 

  11. Li X, He J-Z, Hughes JM, Liu Y-R, Zheng Y-M. Effects of super-absorbent polymers on a soil–wheat (Triticum aestivum L.) system in the field. Appl Soil Ecol. 2014;73:58–63. https://doi.org/10.1016/j.apsoil.2013.08.005.

    Article  Google Scholar 

  12. Ai F, Yin X, Hu R, Ma H, Liu W. Research into the super-absorbent polymers on agricultural water. Agric Water Manag. 2021;245:106513. https://doi.org/10.1016/j.agwat.2020.106513.

    Article  Google Scholar 

  13. Ashkiani A, Ghooshchii F, Tohidi-Moghadam HR. Effect of super absorbent polymer on growth, yield components and seed yield of wheat grown under irrigation withholding at different growth stages. Res Crops. 2013;14:48–53.

    Google Scholar 

  14. Guo L, Ning T, Nie L, Li Z, Lal R. Interaction of deep placed controlled-release urea and water retention agent on nitrogen and water use and maize yield. Eur J Agron. 2016;75:118–29. https://doi.org/10.1016/j.eja.2016.01.010.

    Article  CAS  Google Scholar 

  15. Ma X, Wen G. Development history and synthesis of super-absorbent polymers: a review. J Polym Res. 2020;27:136. https://doi.org/10.1007/s10965-020-02097-2.

    Article  CAS  Google Scholar 

  16. Jiang N, Cai D, He L, Zhong N, Wen H, Zhang X, Wu Z. A facile approach to remediate the microenvironment of saline-alkali soil. ACS Sustain Chem Eng. 2015;3:374–80. https://doi.org/10.1021/sc500785e.

    Article  CAS  Google Scholar 

  17. Tabassum MA, Zhu GL, Zhou GS, Song L, Bashir MA, Hashem M, Alamri S, El-Zohri MA. Super absorbent polymer application improves plant growth in saline soils overview and challenges. Fresenius Environ Bulletin. 2021;30:12241–9.

    CAS  Google Scholar 

  18. Zhao W, Zhou Q, Tian ZZ, Cui YT, Liang Y, Wang HY. Apply biochar to ameliorate soda saline-alkali land, improve soil function and increase corn nutrient availability in the Songnen Plain. Sci Total Environ. 2020. https://doi.org/10.1016/j.scitotenv.2020.137428.

    Article  Google Scholar 

  19. Dong CW, Zhang YZ and Shi Y (2021) Effects of new compound water-retaining agent on growth and physiological characteristics of wheat seedlings under drought stress. Soil and Fertilizer Sciences in China: 255-261

  20. Liu MM, Sun JN, Zhai SS, Xu YS, Jun LI, Wang YF, Zhang YZ, Shi Y. Effect of attapulgite water retaining agent on wheat quality and yield in dryland. Tillage Cultiv. 2018. https://doi.org/10.1360/j.cnki.52-1065/s.2018.04.002.

    Article  Google Scholar 

  21. Han Y, Yu X, Yang P, Li B, Xu L, Wang C. Dynamic study on water diffusivity of soil with super-absorbent polymer application. Environ Earth Sci. 2013;69:289–96. https://doi.org/10.1007/s12665-012-1956-9.

    Article  Google Scholar 

  22. Wen XX, Zhang DQ, Liao YC, Jia ZK, Ji SQ. Effects of water-collecting and -retaining techniques on photosynthetic rates, yield, and water use efficiency of millet grown in a semiarid region. J Integr Agric. 2012;11:1119–28. https://doi.org/10.1016/s2095-3119(12)60105-1.

    Article  Google Scholar 

  23. Baak H. The effects of super absorbent polymer application on the physiological and biochemical properties of tomato (Solanum lycopersicum L.) plants grown by soilless agriculture technique. Appl Ecol Environ Res. 2020;18:5907–21.

    Article  Google Scholar 

  24. Liu F, Ma H, Xing S, Du Z, Ma B, Jing D. Effects of super-absorbent polymer on dry matter accumulation and nutrient uptake of pinus pinaster container seedlings. J For Res. 2013;18:220–7. https://doi.org/10.1007/s10310-012-0340-7.

    Article  Google Scholar 

  25. Tian XM, Wang KY, Fan H, Wang JQ, Wang LN. Effects of polymer materials on the transformation and utilization of soil nitrogen and yield of wheat under drip irrigation. Soil Use Manag. 2021;37:712–22. https://doi.org/10.1111/sum.12651.

    Article  Google Scholar 

  26. Wang HB, Wang ZY, Wang WX and Cao WF (2016) Study on Bentonite/Poly(Sodium acrylate-acrylamide)Superabsorbent Composite. Mod Agric Sci Technol 2016;3:233–241.

  27. Cheng H, Shen Y, Meng H, Zhan S. Effects of biochar-based super absorbent on soil moisture and rape growth. J Agric Sci Technol. 2017;19(2):86.

    CAS  Google Scholar 

  28. Sierra CA, Trumbore SE, Davidson EA, Vicca S, Janssens I. Sensitivity of decomposition rates of soil organic matter with respect to simultaneous changes in temperature and moisture. J Adv Model Earth Syst. 2015;7:335–56. https://doi.org/10.1002/2014MS000358.

    Article  Google Scholar 

  29. Li G, Niu W, Sun J, Zhang W, Zhang E, Wang J. Soil moisture and nitrogen content influence wheat yield through their effects on the root system and soil bacterial diversity under drip irrigation. Land Degrad Dev. 2021;32:3062–76. https://doi.org/10.1002/ldr.3967.

    Article  Google Scholar 

  30. Stevenson A, Hallsworth JE. Water and temperature relations of soil actinobacteria. Environ Microbiol Rep. 2014;6:744–55. https://doi.org/10.1111/1758-2229.12199.

    Article  CAS  Google Scholar 

  31. Fu Z-d, Zhou L, Chen P, Du Q, Pang T, Song C, Wang X-c, Liu W-g, W-y Y, Yong T-w. Effects of maize-soybean relay intercropping on crop nutrient uptake and soil bacterial community. J Integr Agric. 2019;18:2006–18. https://doi.org/10.1016/S2095-3119(18)62114-8.

    Article  CAS  Google Scholar 

  32. Fierer N, Lauber CL, Ramirez KS, Zaneveld J, Bradford MA, Knight R. Comparative metagenomic, phylogenetic and physiological analyses of soil microbial communities across nitrogen gradients. ISME J. 2012;6:1007–17. https://doi.org/10.1038/ismej.2011.159.

    Article  CAS  Google Scholar 

  33. Evans SE, Wallenstein MD. Soil microbial community response to drying and rewetting stress: does historical precipitation regime matter? Biogeochemistry. 2012;109:101–16. https://doi.org/10.1007/s10533-011-9638-3.

    Article  Google Scholar 

  34. Campos AC, Etchevers JB, Oleschko KL, Hidalgo CM. Soil microbial biomass and nitrogen mineralization rates along an altitudinal gradient on the cofre de perote volcano (mexico): the importance of landscape position and land use. Land Degrad Dev. 2014;25:581–93. https://doi.org/10.1002/ldr.2185.

    Article  Google Scholar 

  35. Chen DD, Zhang SH, Dong SK, Wang XT, Du GZ. Effect of land-use on soil nutrients and microbial biomass of an alpine region on the northeastern Tibetan plateau, China. Land Degrad Dev. 2010;21:446–52. https://doi.org/10.1002/ldr.990.

    Article  Google Scholar 

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Acknowledgements

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Funding

Supported by Shandong Modern Agricultural Technology & Industry System—cultivation and soil fertilizer (SDAIT0107) and Agricultural Major Technology Collaborative Promotion Plan Project in Shandong Province (SDNYXTTG-2022-18).

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YS and YX designed the experiment. YX, YG, WL, SC, and YL completed the experiment. YX and YG carried out data analysis and graphic production. YX participated in the writing of the manuscript. YS performed the final editing of the manuscript. All authors read and approved the final manuscript.

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Correspondence to Yan Shi.

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Xu, Y., Gao, Y., Li, W. et al. Effects of compound water retention agent on soil nutrients and soil microbial diversity of winter wheat in saline-alkali land. Chem. Biol. Technol. Agric. 10, 2 (2023). https://doi.org/10.1186/s40538-022-00375-3

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