The effects of drip irrigation (DI) with fresh water (FW) and brackish water (BW) on saline-alkali soil improvement were compared
under treatments of five amendment combinations. The experiment was designed using the orthogonal test method and performed
using an indoor DI system. Soil electrical conductivity (EC), pH, sodium adsorption ratio and soil nutrients were analyzed after DI
both before evaporation and after one month of evaporation. The results showed that after one month of evaporation, soil EC increased
by an average of 97.26% and 27.76% for the FW and BW treatments, respectively. Furthermore, it was shown that soil nutrients
increased greatly under the BW treatment and that cow dung proved to be a leading agent influencing soil nutrients except available
soil potassium (
p
<0.05). Consequently, the optimum combination of soil amendments was determined as 0.03 m
3
/m
2
of straw, 3 kg/m
2
of phosphogypsum, 0.04 m
3
/m
2
of cow dung, 0.6 kg/m
2
of humic acid and 0.18 kg/m
2
of microbial fertilizer under the BW treatment.
Additional key words:saline-alkali soil;orthogonal test;fresh water;brackish water;soil improvement.Abbreviations used:BW (brackish water);DI (drip irrigation);EC (electrical conductivity);FW (fresh water);OM (organic matter);SAR (sodium adsorption ratio);ANOVA (analysis of variance).Earmarks of Bohai Granary Demonstrative Project of Science and Technology for Hebei Province, China; Science and
Technology Support Program of Hebei Province (152776122D); Natural Science Foundation of Hebei Province (D2016208100); the
Natural Science Foundation of China (41401307); Research Foundation of Education Department of Hebei Province (QN2015096);
Five Platform Open Fund Project of Hebei University of Science and Technology (2016PT69); High-Level Leading Talent Introduction
Program of GDAS (2016GDASRC-0103).
Author's contributions:
Conceived, designed and performed the experiments: XW, YL, and JS. Analyzed the data: SZ and YL.
Wrote the paper: SZ, YL and ZY. All authors read and approved the final manuscript.
Citation
Liu, Y.; Zhou, S.; Sun, J. P.; Wang, X. P.; Yuan, Z. J. (2018). An optimum soil amendment combination under drip
irrigation with different water sources in the coastal areas, East China. Spanish Journal of Agricultural Research, Volume 16, Issue 3,
e1102.
https://doi.org/10.5424/sjar/2018163-13165
Competing interests:
The authors have declared that no competing interests exist.
Introduction
Saline soils are important land resources that are widely distributed throughout China. As an important subclass of saline soils, the coastal saline soil area is approximately 7% of the total area of saline soils, and mainly distributed in East China. The reclamation of these saline soils is essential for the sustainable development of agriculture and is important to underpin crop production in coastal regions (
Rengasamy, 2006
;
Weng
et al.
, 2010
;
Mao
et al.
, 2016
).
Various techniques have been applied to reclaim coastal saline soils and enhance soil fertility and crop yield, including improvement measures in engineering, chemistry, biology and physics (
Qadir
et al.
, 1996
;
Xiong
et al.
, 2012
;
Luo
et al.
, 2015
;
Gupta
et al.
, 2016
;
Mao
et al.
, 2016
). Amelioration of saline soils with amendments is an established technology. Over time, gypsum, cow dung, humic acids, crop straw and microbial fertilizer have been used for soil reclamation. Gypsum adds Ca
2+
to saline soils and decreases exchangeable sodium (
Kelly & Brown, 1934
) and can also improve other properties such as soil aggregate structure, soil bulk density, soil permeability and alkalization (
Clark & Baligar, 2003
). Applying cow dung can effectively improve soil fertility, enhance the activity of soil microorganisms, and promote crop growth (
Liu L
et al.
, 2015
;
Liu Y
et al.
, 2015
). Humic acids contain large amounts of active groups and great cation exchange capacity: they reduce soil pH and alkalinity by neutralization reaction and ion exchange interactions (
Tong
et al.
, 2014
). With crop straw returned to soil, soil structure and properties including water content, fertilizer, gas and heat condition of soils are improved (
Lu
et al.
, 2016
). Microbial fertilizer contains large amounts of beneficial microorganisms and organic matter (OM), which produce large amounts of organic acids during the decomposition process. Microbial fertilizer can effectively improve the physical and chemical properties of saline soils, increase microbial activity and therefore enhance soil fertility (
Gu, 2013
). These amendments can effectively improve the physical and chemical qualities of saline soils. However, soil reclamation with amendments would require more time without additional measures such as leaching (
Liu L
et al.
, 2015
).
The leaching method is one of the most important techniques and has been widely used to reclaim saline soils (
Shainberg
et al.
, 1991
;
Chaganti
et al.
, 2015
). However, the traditional leaching (continuous or partial ponding) method is limited in coastal regions due to shortages of high quality water. Drip irrigation (DI) is an effective irrigation technique for improving water use efficiency and has been successfully applied in reclamation of saline soils. In addition, DI is regarded as the most promising irrigation system for use with saline (brackish) water, which is readily acquired in coastal regions and can be used as an alternative to freshwater (
Li X
et al.
, 2015
). Drip irrigation applies water precisely and uniformly at high frequencies and maintains high soil matric potential in the root zone; thus, DI compensates for the decreased osmotic potential caused by irrigation with saline water and enables the maintenance of constant high total water potential for crop growth (
Li X
et al.
, 2015
).
As an important land reserve, coastal saline areas of East China play a key role in releasing the tense situation of limited farmland resources, which has imposed a great pressure on sustainable food production for China's booming population. Extensive research has been conducted over decades with respect to using either soil amendments or the DI method to reclaim saline-sodic soils; however, combining effects of soil amendments with DI are questionable and warrant further study.
In the present study, the effects of coapplication of straw, phosphogypsum, cow dung, humic acid, and microbial fertilizer on coastal saline soil improvements were investigated under DI with two kinds of water sources including fresh water (FW) and brackish water (BW). The study aimed to determine 1) the best water source for DI, and 2) the optimum combination of soil amendments to improve coastal saline soils. The results could elucidate the approach to improving saline-alkali soils where subsurface pipes are laid to discharge salt in the coastal field.
Material and methodsSoil sample collection and soil properties
Soils were taken from uncultivated saline-alkali land (117.°38'26"E, 38.°27'40"N) near the coast of Bohai District in Cangzhou City, Hebei Province, China (Fig. 1). The area experiences a warm temperate semi humid monsoon climate. The annual mean precipitation is approximately 600 mm, 70-80% of which occurs from July to August. Experimental soils were clayey coastal saline soils, collected from the depth range of 0-100 cm, mixed, air dried and sieved (2-mm mesh). The contents of Na
+
and Cl
-
in the test soils accounted for 32.3% and 45.3% of the total ion content, respectively. Therefore, the soil salinity mainly consisted of NaCl. The experimental soils exhibited an electrical conductivity EC= 8.02 dS/m, pH= 8.69 and sodium adsorption ratio SAR= 40.6 (mmol/L)
0.5
. Soil OM, available nitrogen (N), available phosphorus (P) and available potassium (K) were 25.3 g/kg, 36.7 mg/kg, 11.7 mg/kg and 691.0 mg/kg, respectively. Soil bulk density was 1.75 g/cm
3
, and soil aggregates with diameters less than 0.5 mm accounted for 97.22% of the total soil mass. The soil chemical properties are shown in Table 1.
Location of sample area in Cangzhou city,
Hebei Province. Experimental soils and brackish water
were both taken from this area.
Soil chemical properties in the experiment.
Experimental materials
The experiments were conducted at the Institute of Coastal Agriculture, Hebei Academy of Agriculture and Forestry Sciences in Tangshan City, Hebei Province, China. Soil amendments included straw (A), phosphogypsum (B), cow dung (C), humic acid (D) and microbial fertilizer (E). The contents and sources for soil amendments are shown in Table 2.
Properties and sources of soil amendments in the experiment.
Experimental design
Orthogonal testing design is an optimization method for studying experiments with multiple factors and multiple levels. Certain representative points are selected for testing based on orthogonal tests instead of conducting every test (
Wang & Wang, 2012
). This method is an efficient, fast and economical experimental design method, and has been widely used in many fields. In this study, orthogonal testing was performed in order to obtain the best combination of the soil amendments. Table 3 shows the orthogonal design [L16 (4
5
) for five soil amendments (labeled from A to E) at four levels (labeled from 1 to 4, followed by the corresponding doses )] in this study: straw (0.01, 0.02, 0.03 and 0.04 m
3
/m
2
for A1, A2, A3 and A4, respectively), phosphogypsum (1.5, 3, 4.5 and 6 kg/m
2
for B1, B2, B3 and B4, respectively), cow dung (0.01, 0.02, 0.03 and 0.04 m
3
/m
2
for C1, C2, C3 and C4, respectively), humic acid (0.3, 0.6, 0.9 and 1.2 kg/m
2
for D1, D2, D3 and D4, respectively), and microbial fertilizer (0.045, 0.09, 0.135 and 0.18 kg/m
2
for E1, E2, E3 and E4, respectively) which were optimized according to the practice of a previous demonstration project for improvement of saline-alkali soils in the study area (
Liu Y
et al.
, 2015
). The experiment was set up with three replicates. The simple average values of the three replicates of each treatment were deemed the experimental index values.
Levels and the corresponding doses (inside the brackets) for orthogonal experimental design for soil
amendments.
In this study, two varieties of irrigation water sources were used, viz. fresh water (tap water) with salinity of 1.4 g/L from the local 200 m-deep well and brackish water with salinity of 3.5 g/L from a 500 m-deep well in the sample area of Xinhai Biotechnol. Co. Ltd. at Nanpai River Town in Cangzhou City, Hebei Province (Fig. 1). The properties of water sources used are shown in Table 4. The ID water supply system was performed with a Markov bottle (Fig. 2). The Markov bottle is a constant flow water supply device and has been extensively used in infiltration evaporators and experimental water supply systems. It controls the constant water supply flow by adjusting the height difference between the Markov bottle inlet and the water supply pipe outlet. In this study, a Markov bottle with an internal diameter of 14 cm and a height of 80 cm was employed. During the process of DI, the water level in the soil column moves downwards, causing the pressure difference between the Markov bottle and the soil column, which forces the Markov bottle to fill the soil column through the water hose. Therefore, the height of the water surface in the Markov bottle decreases, and the amount of DI is measured by the decrease in the height of the Markov water surface. Test soils, which were well-mixed with amendments at required doses according to the experimental design, were filled in an organic glass column with different heights due to implementation of soil amendments. The glass column was 0.1 cm thick, 100 cm tall and 15 cm in diameter (
Liu Y
et al.
, 2015
). Gravels with a median diameter of approximately 4 cm were laid in the bottom of the soil column as a leaching layer with thickness of 5 cm. Using a DI system with a flow rate of 1.38 L/h under a 10 m DI tape, 5 L of water was used for DI for each soil column with a drop rate of 0.5 L/h, according to the former study results of our group as well as the situation of the testing area (
Liu Y
et al.
, 2015
). The DI process lasted for approximately 3 days. Soil columns were evaporated for 30 days under a shelter outdoors after irrigation to test soil salinization.
Properties of different water sources in the experiment.
Experimental drip irrigation frame. Stand 1 and Stand 2 represent 8 treatments of either
kind of water resource (fresh water (FW) or brackish water (BW)) respectively for one set of drip
irrigation experiment. Stand 3 represents the water supply system using a Markov bottle device.
Analytical methods
The topsoil (0-20 cm) is deemed the most important portion for agricultural production and is directly related to a stable and high yield of food production (
Bai
et al.
, 2011
). Therefore, experimental soils were obtained from the top 0-20 cm of the sample field after DI and evaporation. Soil pH was measured with a pH meter (soil/deionized water ratio: 1:5), and soil EC was tested using a DDS-11A electrical conductivity meter (soil/deionized water ratio: 1:5). SAR, which is an important indicator in characterizing soil salinization, is defined as the ratio of the concentration of Na
+
to the square root of the concentration of Ca
2+
and Mg
2+
in the solution (
Sposito & Mattigod, 1977
). The contents of Na
+
, Ca
2+
and Mg
2+
were measured by an atomic absorption spectrophotometer (Beijing TAS99F). Soil available N, P and K were extracted according to
Bao (2008)
: N using the alkaline hydrolysis diffusion method, P using sodium bicarbonate method, and K using the ammonium acetate extraction method. Soil OM was measured by the potassium dichromate heating method.
The analysis of variance (ANOVA) was used to explore soil improvement differences by different soil amendments using SPSS 19.0 software with a significance level of
p
<0.05. The fitting procedures were carried out using Microsoft Office Excel 2007 and Grapher 8.0 software (
http://www.goldensoftware.com
).
Results
In this study, the effects of soil improvement were reflected in two aspects including improvement to soil properties and enhancement of soil nutrients. Improvement to soil properties was analyzed in terms of soil EC, pH and SAR values, which are key factors for plants survival. Soil nutrients comprised soil available N, P, K and OM, which are essential for plant growth.
Soil property improvement after DI
Table 5 shows that the soil EC decreased distinctively after DI under either the FW or BW treatment compared with the original soils (EC=8.02 dS/m). Under the FW treatment, the soil EC values of 16 treatments declined by 6.8-7.6 dS/m with an average decline of 91.7%; treatment T6 resulted in the lowest soil EC value (0.38 dS/m). Under the BW treatment, the soil EC values decreased by 6.2-7.3 dS/m with an average decline of 85.5%; treatment T5 resulted in the lowest soil EC value (0.76 dS/m). Both FW and BW reduced soil pH (Table 5). Under the FW treatment, compared with the original soils (pH=8.69), the soil pH values of 16 treatments were reduced by 0.23-0.89, with an average decrease of 6.1%. Under the BW treatment, the soil pH values declined by 0.44-1.02 with an average decrease of 8.0%.
Effects of combination of different water sources (FW, BW) and soil amendments on soil chemical
properties after drip irrigation (p<0.05).
The soil SAR value was highest in the CK among all treatments under either water source after DI (Table 5). Soil SAR decreased distinctively under either the FW or BW treatment compared with the original soils (SAR=40.6 (mmol/L)
0.5
). Under the FW treatment, the soil SAR values of 16 treatments decreased by 32.7-37.6 (mmol/L)
0.5
on average, with an average decline of 89.4%. Treatment T12 produced the lowest soil SAR value (1.9 (mmol/L)
0.5
). For the BW treatment, the soil SAR values decreased by 29.1-34.8 (mmol/L)
0.5
with an average decline of 77.9%. Treatment T3 resulted in the lowest soil SAR value (5.8 (mmol/L)
0.5
).
Soil properties improvement after evaporation
After DI under the FW and BW treatments, soil columns were laid outdoors under a shelter for one month. Then, the soil EC, pH and SAR values were measured through sampling topsoils (0-20 cm).
Soil salinization occurred under both the FW and BW treatments (Table 6), compared with the soil columns before evaporation (Table 5). Under the FW treatment, the soil EC values decreased by 6.2-7.2 dS/m, with an average decline of 84.8%, in contrast to the original soils. However, the soil EC values of the 16 treatments increased by 97.3% on average; only CK exhibited no change compared with those before evaporation. The best treatment was CK. Under the BW treatment, soil EC values decreased by 4.1-7.2 dS/m with an average decline of 81.2% compared with the original soils. However, soil EC values of the 16 treatments increased by 27.8% on average compared with those before evaporation, and the best treatment was T5.
Effects of combination of different water sources (FW, BW) and soil amendments on soil
chemical indexes after one-month evaporation (p<0.05).
In terms of soil pH, the changes showed a different trend between the FW and BW treatments after evaporation (Table 6). Under the FW treatment, the soil pH values decreased by 0.20-0.75 (5.7% on average) in contrast to the original soils. Moreover, the soil pH values were increased by an average of 0.40% in comparison with those before evaporation (Table 5). The best treatment was T12. For the BW treatment, the soil pH values were decreased by 0.36-1.12 with an average of 9.8%, in contrast to the original soils. It should be noted that the soil pH values of the 16 treatments were decreased by 1.1% on average compared with those before evaporation (Table 5). The optimum treatment was T16.
Table 6 suggests that the soil SAR value of CK was the highest among all 16 treatments under either water source after evaporation, which is similar to those results after DI. For the FW treatment, the soil SAR values were decreased by 31.1-37.8 (mmol/L)
0.5
(86.3% on average) in contrast to the original soils. Compared with those before evaporation (Table 5), the soil SAR values of all the treatments were increased by 3.1% on average, except T2. For the BW treatment, the soil SAR values were decreased by 29.0-34.4 (mmol/L)
0.5
(78.8% on average) in contrast to the original soils, and decreased by 0.9% on average compared with those before evaporation.
Soil nutrients after evaporation
The experimental data showed that the accumulation of soil nutrients, including soil available N, P, K and soil OM, was significantly enhanced (
p
<0.05).
Fig. 3a indicates that under the FW treatment, the soil available N in the topsoils of the 16 treatments increased to 48.7-106.4 mg/kg compared with the original soils (36.7 mg/kg), the soil available N of the 16 treatments increased by 32.6-190.0% while that of CK decreased by 8.2%, and T10 attained the highest soil available N content of 106.4 mg/kg. For the BW treatment, the content of soil available N ranged from 47.6 to 141.6 mg/kg, increasing by 29.6-285.7% compared with the original soils, and T13 achieved the highest soil available N content (141.6 mg/kg). Comparing the soil available nitrogen between FW and BW treatments (Fig. 3a), 12 of the 16 treatments exhibited a significant difference, which indicated that different water sources greatly affected soil available N content.
Effect of different treatments on soil nutrients including soil available N (nitrogen), P
(phosphorus), K (potassium) and soil OM (organic matter) under FW (fresh water) and BW (brackish
water) treatments after one-month evaporation. The black horizonal lines indicate the soil nutrient levels
of original soils.
Under the FW treatment in Fig. 3b, the soil available P of the 16 treatments greatly increased to 235.6-692.0 mg/kg compared with the original soils (18.7 mg/kg). T10 reached the highest soil available P of 710.7 mg/kg. In the BW treatment, the content of soil available P ranged from 111.4 to 341.7 mg/kg, which is 5.0-17.3 times higher than that in the original soils, and T10 enabled the highest soil available P (341.7 mg/kg). There was significant difference between all the columns between FW and BW treatments except CK and T6.
Under the FW treatment in Fig. 3c, soil available K ranged from 512.0 to 785.0 mg/kg. Compared with original soils (691 mg/kg), the contents of soil available K of some treatments increased while others decreased. T13 resulted in the highest soil available K of 785.0 mg/kg. Under the BW treatment, the content of soil available K ranged from 404.9 to 832.2 mg/kg. Similar to the FW treatment, T13 also reached the highest content of soil available K (832.2 mg/kg). Most of the soil columns showed a significant difference between the FW and BW treatments (Fig. 3c).
The accumulation of soil OM is shown in Fig 3d, ranging from 13.4 to 27.1 g/kg under the FW treatment. In contrast to the original soils (25.3 g/kg), the soil OM of some treatments increased while others decreased; however, the soil OM of the 16 treatments were higher than that in CK (7.3 g/kg). T10 reached the highest soil OM of 27.1 g/kg. For the BW treatment, the content of soil OM reached 17.1-39.7 g/kg, corresponding to 0.8-3.3 times higher compared with that in CK (9.4 g/kg), and T13 reached the highest content of soil OM (39.7 g/kg). Fig. 3d shows that most of the columns had a significant difference in soil OM between the FW and BW treatments, and that the soil OM contents of all soil columns under the BW treatment were higher than those under the FW treatment.
Determination of superior water source
The above analyses showed that the FW treatment performed better than the BW treatment in decreasing the soil EC, while the latter performed better than the former in decreasing the soil pH after DI (Table 5). After evaporation, however, soil salt and alkalinity under the FW treatment increased in most of the treatments (Table 6),
i.e.
, soil EC, pH and SAR values under the FW treatment showed greater increases than those under the BW treatment. Soil pH and SAR under the BW treatment even decreased after evaporation (Table 6). In terms of soil nutrients, soil available N and P were enhanced while soil available K either decreased or increased under both water treatments. However, the studied saline-alkali soils were rich in soil available K (
Zhang
et al.
, 2012
). In addition, the soil OM of the BW treatment was higher than that of the FW treatment (Fig. 3d): the additional fact that brackish water was easily acquired and thus would decrease soil reclamation costs in coastal areas proved the great potential of BW in improving saline-alkali soils (
Yao
et al.
, 2014
).
Determination of optimum combination of amendments under BW treatment
According to the above results, orthogonal analysis was performed on all the indices after evaporation in order to obtain the best combination of the amendments under the BW treatment.
Effect of different amendments on soil chemical properties
The ANOVA analysis showed that only phosphogypsum had a significant effect on soil EC among the different amendments and that soil EC was influenced in the order of B>A>E>D>C, which showed that phosphogypsum was the most important factor affecting soil EC (straw was the second). Fig. 4a indicates that the soil EC decreased first and then increased linearly with the increase in phosphogypsum and straw application and that the optimal levels were B2 and A2. Other indices changed slightly, which indicated that they had little effect on soil EC. Therefore, A2B2C4D1E4 was the optimal combination for soil EC.
Effect of different amendments on soil chemical properties (soil electrical conductivity (EC), pH and sodium
adsorption ratio (SAR) under BW treatment after one-month evaporation. The black solid triangles represent the optimal
levels of each soil amendment for soil chemical properties.
According to the variance analyses (
p
<0.05), phosphogypsum had a significant effect on soil pH, which was influenced in the order of B>C>A>D>E. It can be seen that phosphogypsum was still the most important factor affecting soil pH. The result showed that phosphogypsum played an important role in regulating soil pH value. Based on comprehensive consideration (Fig. 4b), A4B4C4D3E3 was the best combination for decreasing soil pH.
The ANOVA analysis indicated that all amendments had no significant effect on soil SAR, which was influenced in the order of A>B>D>E>C. Fig. 4c indicates that straw was the major factor for soil SAR, and phosphogypsum was the second. With the increase in straw application, soil SAR value increased possibly because the straw could absorb brackish water. With the increase in phosphogypsum application, SAR decreased gradually due to the increase in Ca
2+
concentration. Finally, A1B4C2D1E3 was chosen as the optimal combination for reducing soil SAR.
Effect of different amendments on soil nutrients
Cow dung had a significant effect on soil available N (
p
<0.05), which was influenced in the order of C>E>D>A>B. Fig. 5a shows that cow dung is the greatest influencing factor on increasing soil available N,
i.e.
, the more cow dung applied, the higher soil available N content. Hence, C4 was chosen as the optimal level, and A4B4C4D2E4 was the best treatment for soil available N.
Effect of different amendments on soil nutrients (soil available N (nitrogen),
P (phosphorus), K (potassium) and soil organic matter (OM)) under BW (brackish water)
treatment after one-month evaporation. The black solid triangles represent the optimal levels
of each soil amendment for soil nutrients.
The results of the ANOVA analysis indicated that straw and cow dung were significant for soil available P, which was influenced in the order of C>A>E>D>B. Fig. 5b suggests that soil available P gradually increased as cow dung application increased; the value increased first and decreased afterwards with application of straw. Therefore, A3B4C4D2E3 was the best treatment for soil available P.
All amendments had no significant effect on soil available K, which was influenced in the order of B>A>C>D>E, indicating that phosphogypsum exerted the greatest effect on soil available K: with the increase in phosphogypsum application, the content of soil available K decreased (Fig. 5c). A4B1C4D2E1 was then the best treatment for soil available K.
Variance analysis suggested that cow dung had a significant effect on soil OM, which was influenced in the order of C>D>B>E>A. Similar to soil available N (Fig. 5a), Fig. 5d shows that cow dung was also the greatest influence factor on increasing soil OM. The best combination was A4B1C4D2E3 for soil OM.
Determination of optimal combination
It is necessary to take into account all the indicators in order to achieve the purpose of improving saline-alkali land. Therefore, the optimum combinations were also determined on the basis of the degree sequence and a comprehensive consideration including cost and practicality.
Straw (A) significantly affected only soil available P (
p
<0.05), and A3 was the best level because it had no significant influence on other soil indicators. Therefore, the A3 level was chosen. Phosphogypsum (B) had a significant effect on soil EC and pH (
p
<0.05), and it was the first influencing factor for soil EC and pH, B2 was the best level for soil EC, while B4 was best for soil pH value. As B2 increased soil pH value by 3.9% more than B4, while the latter increased soil EC by 105.9% more than the former, B2 was chosen. Cow dung (C) had significant influence on soil available N, P and OM (
p
<0.05). It was the first influencing factor for those three indicators, and C4 performed at the best level. Therefore, the C4 level was chosen. Humic acid (D) had no significant influence on any indicators (
p
<0.05), but it was the second effective factor on soil pH value and soil OM: D2 was the best level for soil nutrients with D3 for soil pH value. Since D2 increased soil pH value by 1.0% more than D3, while the latter decreased soil OM by 10.4%, the D2 level was chosen. Microbial fertilizer (E), similar to humic acid, had no significant effect on any indice (
p
<0.05). As microbial fertilizer was the second effect factor on soil available N, and E4 was the best level, the E4 level was chosen by comprehensive consideration. Therefore the optimum formula was A3B2C4D2E4 under BW treatment.
Discussion
As they are vital agricultural land reserves, the studies of highly saline-alkali soils have received much attention in the world (
Agassi
et al.
, 1986
;
Qadir
et al.
, 1996
;
Gupta
et al.
, 2016
;
Rameshwaran
et al.
, 2016
). Applying soil amendments as a common method with low cost and potentially significant effectiveness could solve the problems of soil salinity. Due to the scarcity of fresh water in coastal areas, low quality water (such as saline groundwater) has been widely utilized (
Beltrán, 1999
;
Verma
et al.
, 2012
;
Wang
et al.
, 2016
). The results of this experiment showed that DI with both FW and BW could improve soil salinity and alkalinity and enhance soil nutrient contents through a proven combination of soil amendments. Furthermore, the results showed that compared with the FW treatment, soil SAR and pH values were further decreased while soil OM content was enhanced after evaporation under the BW treatment, which was beneficial to the improvement of saline alkali soils.
Effects of soil amendments
Straw and cow dung can be decomposed to improve soil fertility by increasing soil nutrient content (
Rao & Pathak, 1996
). Specifically, in this work, straw had a significant effect on the improvement of soil available P (for 1-3 levels), while cow dung had a significant effect on soil available N, P and soil OM (
p
<0.05).
As a byproduct of the ammonium phosphate industry, phosphogypsum has been widely used due to its low cost and potential to improve soil salinity (
Al-Karaki & Al-Omoush, 2002
).
Agassi
et al.
(1986)
found that application of phosphogypsum can prevent soil hardening and reduce sodium ion concentration in the soil. The study of
Wu
et al.
(2012)
indicated that phosphogypsum could increase soil nutrients and improve soil salinity conditions,
i.e.
, Ca
2+
, suitable for crops, replaced the unsuitable Na
+
, and Na
+
was eventually washed away by water. Moreover, CO
32-
and HCO
3-
decreased gradually while SO
42-
(harmless to crops) increased, and soil pH was effectively improved. Similar results appeared in our experiments (see Table 1), in which phosphogypsum demonstrated a significant influence on soil EC and pH (
p
<0.05).
In terms of humic acid,
Sun
et al.
(2013)
reported that humic acid could decrease soil pH by releasing H
+
and OH
-
ions to generate H
2
O as well as improve soil structure and heighten soil permeability, which promoted the dissolution of Na
+
, and therefore reduced soil EC value. However, in the present work, the effect of humic acid was not significant for soil EC, pH and SAR under BW treatment. This may be related to the different water sources and antagonistic effects of different soil amendments.
Microbial fertilizer increases soil OM and organic acid via decomposition, which could provide nutrition for microorganism and improve physical and chemical properties of saline-alkali soils (
Sun, 2010
;
Wu
et al.
, 2011
). Our experimental results showed that microbial fertilizer had no significant effect on either soil properties (pH, EC and SAR) or soil nutrients (soil available N, P, K and soil OM) under the BW treatment (
p
<0.05). Possible reasons for this result were that the effect of microbial fertilizer largely depends on the living environment of the microorganism,
e.g.
, soil temperature, soil water content, soil salinity and OM, soil pH and illumination (
Liu, 2008
). In fact, microbial fertilizer is not actual fertilizer; it provides nutrients indirectly through the living activities of microorganism, which enhance soil nutrient level. Considering that five soil amendments were mixed together to improve experimental soils, the effectiveness of microbial fertilizer could be discounted.
Limitations and prospects
In our study, a combination of five soil amendments with fresh and brackish water under DI treatment was applied for saline-alkali soil improvement. Considering the cost and convenience of soil reclamation materials, the optimal soil amendment combination under brackish water was determined by orthogonal analysis in terms of soil EC, pH, SAR and soil nutrients. Those indicators are considered the most important factors affecting plant survival and growth. Therefore, soil physical properties such as soil bulk density have not been discussed in this study, which might have some effects on the study conclusion. For saline water irrigation, it was reported in previous studies that irrigating with saline water presents risks such as salinity hazards or salt toxicity for plants (
Sairam & Tyagi, 2004
) while other scientists reached the opposite conclusion (
Li C.
et al.
, 2015
).
Since the topsoil (0-20 cm) is the soil region for plants, this study focused on the improvement of topsoil: the salt permeated downwards, moving to the deeper soil layer and causing salt accumulation. To solve this problem in the field, underground pipes are usually laid to drain away the applied salty water, which finally flowes into small wells, which is excavated as a component of a subsurface drainage system.
In conclusion, brackish water, with a lower cost, showed great potential to improve saline-alkali soils, especially regarding decreases in soil alkalinity and SAR, compared with fresh water. The optimum combination of soil amendments was A3B2C4D2E4 (0.03 m
3
/m
2
of straw, 3 kg/m
2
of phosphogypsum, 0.04 m
3
/m
2
of cow dung, 0.6 kg/m
2
of humic acid and 0.18 kg/m
2
of microbial fertilizer) under the brackish water treatment. As soil quality improvement is complicated and time-varying process, further work should be conducted to examine soil quality alteration in the longer period, in terms of soil property improvement, soil nutrient enhancement, and conditions in the field. The conclusions could provide references for improving saline-alkali soils especially for brackish water use, and promote the sustainable development of ecology, agriculture and economy in the coastal saline areas of East China.
Acknowledgements
The authors wish to express cordial thanks to anonymous reviewers and editors for kindly providing valuable suggestions and helpful improvements to the paper.
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