Upscaling Soil Salinization in Keriya Oasis Using Bayesian Belief Networks

Abstract

Soil salinization in oasis areas of arid regions is recognized as a dynamic and multifaceted environmental threat influenced by both natural processes and human activities. In this study, 13 spatiotemporal predictors derived from field surveys and remote sensing are utilized to construct a spatial probabilistic model of salinization. A Bayesian Belief Network is integrated with spline interpolation in ArcGIS to map the likelihood of salinization, while Partial Least Squares Structural Equation Modeling (PLS-SEM) is applied to analyze the interactions among multiple drivers. The test results of this model indicate that its average sensitivity exceeds 80%, confirming its robustness. Salinization risk is categorized into degradation (35–79% probability), stability (0–58%), and improvement (0–48%) classes. Notably, 58.27% of the 1836.28 km² Keriya Oasis is found to have a 50–79% chance of degradation, whereas only 1.41% (25.91 km²) exceeds a 50% probability of remaining stable, and improvement probabilities are never observed to surpass 50%. Slope gradient and soil organic matter are identified by PLS-SEM as the strongest positive drivers of degradation, while higher population density and coarser soil textures are found to counteract this process. Spatially explicit probability maps are generated to provide critical spatiotemporal insights for sustainable oasis management, revealing the complex controls and limited recovery potential of soil salinization.

1. Introduction

Land degradation is a global environmental problem that has an important impact on production, life, and the ecological environment [1,2]. Currently, saline land is widely distributed in more than 100 countries around the world, and it is estimated that about 7% of the Earth’s land is at risk of salinity, while 20% of irrigated areas are threatened by secondary salinity of soil [3,4]. Soil salinization is more widely distributed in arid and semi-arid regions [5]. China’s saline-alkali land area is about 3.6 × 10⁷ hm², mainly distributed in six provinces in northwest China [6]. In addition, drought, low rainfall, and high evaporation greatly hinder the sustainable development of agriculture in these areas [7,8]. Therefore, the prevention and control of salinization by prediction has become one of the important ways to solve global environmental and food security problems [9,10].

Soil salinization is a prominent contributor to land degradation. According to the cause, it can be divided into primary and secondary salinization. It occurs primarily through the upward migration of soluble salts from deeper soil layers or groundwater to the surface via capillary action, culminating in salt accumulation in the topsoil as water evaporates [11,12]. This phenomenon significantly diminishes agricultural productivity and environmental quality by reducing crop yields, soil fertility, vegetation coverage, and biodiversity [13,14]. Anthropogenic activities and geomorphological conditions play crucial roles in driving soil salinization in oasis regions [14,15], which exhibits notable dynamics and uncertainty across both horizontal and vertical spatial scales [16,17,18]. With the intensification of global warming and the continued expansion of irrigated land, soil salinization has become an increasingly complex ecological challenge, particularly affecting the sustainable development of arid oases [19]. Research has identified multiple sources of secondary salinization. These include the following: (1) parent geological material and inherent soil characteristics, (2) shallow, salt-rich groundwater, and (3) irrigation with saline water [20]. In studying spatial and temporal variations of salinity, 11 key influencing factors have been highlighted—most notably groundwater depth, surface water evaporation, irrigation practices, groundwater mineralization, and rainfall [21]. Notably, shallow groundwater depth, groundwater salinity, and agricultural practices such as over-irrigation and insufficient drainage are primary drivers of salinity expansion. The spatial pattern of soil salinity typically increases from oasis cores outward [22,23,24]. In summary, soil salinization is the result of the joint action of human activities and natural factors.

Several spatial modeling approaches have been employed to investigate salinization patterns. In the Manas River Irrigation Area, for instance, researchers found higher salt concentrations in both upstream and downstream regions and a decrease in variability with increasing soil depth [21]. In Egypt’s Siwa Oasis, a deep learning-enhanced U-Net algorithm revealed widespread salinity increases in all directions [25]. Given that salinization evolves at macro-environmental scales, a comprehensive and dynamic modeling approach is essential for supporting sustainable land management strategies [17]. Moreover, the increasing complexity of natural systems contributes to greater uncertainty in salinization risk distribution [26]. However, geostatistical techniques like probability kriging and ordinary cokriging have been applied to produce salinity probability maps [27,28]. But they often fall short in addressing the multidimensional interactions of contributing factors. Bayesian networks (BNs), when integrated with geospatial tools such as ArcGIS, have emerged as effective tools for modeling and predicting complex environmental systems [29,30,31]. The strength of BNs modeling lies in its ability to incorporate diverse quantitative and qualitative datasets, enabling the analysis of probabilistic causal relationships across scales [32]. BNs have been successfully applied to enhance the understanding and modeling of diverse environmental issue [33,34,35]. And BNs are becoming more and more mature as a tool for predicting soil salinization, for instance, scholars employed a combined approach of BNs and random forest regression to predict the electrical conductivity (EC) of saturated soil extracts in the coastal region of South Sindh Province, Pakistan (9707 km²) during the period from 2014–2015 to 2020–2021 [36]. BNs have been used by scholars to quantify the uncertainty in salinity associated with reducing the EC in peri-urban circulating water [37]. And a study using BNs to assess the use of water cycling to control soil salinity has also come to fruition [38]. Some studies have used BN models to predict the overall regional salinization status of the Keriya Oasis [39]. Despite the potential of such approaches, few studies have applied BNs in combination with field-based monitoring and remote sensing data to analyze soil salinization in oasis environments. This presents both a methodological gap and an opportunity to enhance our understanding of salinization dynamics in highly vulnerable regions [40]. And most of the existing studies focus on the region as a whole, but ignore the internal differences of oases.

The Keriya Oasis is located at the southern edge of the Taklimakan Desert in Xinjiang. It has an extremely arid temperate continental climate, with scarce precipitation and intense evaporation. The annual average precipitation is less than 50 mm [41,42]. Moreover, shallow groundwater drives salt accumulation; improper irrigation methods aggravate salt redistribution; and extreme arid climate amplifies ecological risks and makes it a salinization disaster area [43]. Therefore, the main objectives of the current study were to achieve the following: (1) Develop a GIS-integrated BNs model to analyze the spatial patterns and trends of soil salinization in the Keriya Oasis. (2) Estimate the likelihood of soil salinization trends—categorized as Improvement (Reduction in Salinity), stability, or degradation—and examine their relationships with eco-environmental driving factors. (3) Explore small-scale regional differences from the inside of the oasis, which provides some theoretical basis for soil salinization control the Keriya Oasis.

2. Materials and Methods

2.1. Study Area

The Keriya Oasis (81°09′–82°00′ E, 36°44′–37°12′ N) is located in the southern region of the Xinjiang Uygur Autonomous Region (XUAR), China (Figure 1) [39]. This oasis is primarily distributed across the alluvial plain of the Keriya River, covering an area of approximately 2000 km². The river serves as its primary water source, forming the fundamental hydrological basis of the oasis [44,45]. The region is characterized by an arid continental climate, with an average annual precipitation of only 44.7 mm, a mean annual temperature of 11.6 °C, and a potential evaporation rate reaching 2498 mm. The soil structure is loose, the soil texture is sand, and the fertility is relatively low, while shallow groundwater is highly mineralized. The topography is relatively flat, further influencing hydrological and soil conditions [46]. The permanent population of the Keriya Oasis is approximately 283,000, concentrated in the southern part of the oasis, and it has a history of irrigation agriculture of about 3500 years [44]. The region faces substantial environmental pressures due to high population density and increasing anthropogenic activities. Rapid population growth and economic expansion have significantly heightened water demand, leading to unsustainable irrigation practices and insufficient drainage infrastructure [42]. These factors have exacerbated soil salinization, contributing to its expansion toward the periphery of the oasis and posing critical challenges for sustainable land use and ecological stability.

2.2. Data Sources

Modeling data for 13 indicators were extracted from three types of sources. The first includes remote sensing data sources such as the Earth Resources Data Cloud, National Tibetan Plateau Data Center, Land Scan dataset provided by the Oak Ridge National Laboratory under the U.S. Department of Energy, European Space Agency, OpenStreetMap, and Geospatial Data Cloud. The second source consists of published papers. The third source is from five field monitoring campaigns. Detailed information is provided here (

Table 1. Data sources for modeling of Keriya Oasis salinization probability.

Data Types	Indicator	Time Scale	Resolution	Data Quantity	Source
Meteorological	Temperature (°C)	2000–2023	1 km	24	http://www.gis5g.com/data/dzsjj (accessed on 21 April 2024)
	Evaporation (mm)	2000–2023	1 km	24	http://www.gis5g.com/data/dzsjj (accessed on 21 April 2024)
	Precipitation(mm)	2000–2023	1 km	24	https://data.tpdc.ac.cn/home (accessed on 1 April 2024)
Socioeconomic	Density of population (person/km2)	2000–2023	1 km	24	https://landscan.ornl.gov/ (accessed on 15 April 2024)
LUCC	Vegetation type trend	2000–2023	300 m	24	European Space Agency
Biophysical	Soil moisture content (g/kg)	2000–2022	100 m	23	https://data.tpdc.ac.cn/home (accessed on 1 April 2024)
	Natural drainage distance (km)	2020	1 km	1	https://www.openstreetmap.org/ (accessed on 20 April 2024)
	Slope (°)	2020	12.5 m	1	https://www.gscloud.cn/search (accessed on 23 April 2024)
	Field distance (km)	2020	300 m	1	European Space Agency
	NDVI (Normalized Difference Vegetation Index)	2000–2023	30 m	24	http://www.gis5g.com/data/dzsjj (accessed on 21 April 2024)
	Soil texture	2019	250 m	1	http://www.gis5g.com/data/dzsjj (accessed on 21 April 2024)
	Soil organic matter (SOM) (mg/kg)	2019	1 km	1	https://data.tpdc.ac.cn/home (accessed on 1 April 2024)
salinization	EC (mS/cm)	2000, 2005, 2010; 2012, 2013, 2014, 2015, 2021, 2001, 2006, 2011, 2016, 2021	-	13	[47,48], This study field survey experimental data

). The precision of different data in the article has been resampled to 1 × 1 km, and the data of precipitation, evapotranspiration, average temperature, and soil moisture content are all averaged annually, but the NDVI data uses the maximum value for each month.

In this study, we extracted 6192 data points from Remote Sensing data sources and 288 data points from published papers using the extraction tool of ArcGIS 10.8, covering the years 2000 to 2023 (Figure 2) according to the 36 soil sampling points presented in Figure 1. There is a high regional consistency between the published data and the measured data. We then integrated this with 148 field monitoring data points spanning the years 2012 to 2021, and utilized the BNs software package NeticaTM (Version 5.24, http://www.norsys.com/.Netica (accessed on 15 May 2024)) to model the EC trend of each sampling point. And the spatial analyst tool ArcGIS 10.8 was used for spatial interpolation analysis. The likelihood of soil salinization trends and their relationships with eco-environmental driving factors was analyzed by Partial Least Squares Structural Equation Modeling (PLS-SEM) in R software (R version 4.2.0).

2.3. Field Soil Sampling and Laboratory Analysis

In this study, we conducted five field sampling activities using the Global Positioning System (GPS) to investigate the characteristics of the ecological transition zone in arid areas. The sampling design followed the principle of spatial stratified random sampling, stratifying into the core area of the oasis, the oasis–desert ecotone, and the desert area. Eight to ten random coordinate points were generated for each stratum to set up sample plots [49,50]. The soil profile was sampled using the three-point method. Specific sampling details are as follows: in July 2012, 24 soil profile samples were collected; In May 2013, 24 soil profile samples were collected. In May 2014, 36 soil profile samples were collected. In May 2015, 36 soil profile samples were collected. In July 2021, 26 soil profile samples were collected. There are a total of 148 samples. To ensure the consistency of the data as much as possible, no more diversity points were added. In this study, the surface soil was taken as the research object, and only 148 samples from the surface layer (0–20 cm) with the same spatial location in all sampling periods were selected. A series of laboratory procedures was carried out on the collected soil samples. Soil surface samples were sorted, air dried, ground, crushed, and screened with a 200-mesh sieve. 20 g of the screened sample was mixed with distilled water (conductivity < 20 mS/cm) in a 1:5 ratio, sealed, shaken over 200 times, and left to stand for 6 h. The supernatant was then filtered, and the filtrate was stored in a new container. Finally, the conductivity of the filtrate was measured using a conductivity meter (Leici DZS-706F-A) to obtain the actual conductivity data (

Table 2. Descriptive statistics for soil EC by different years as measured over 0–20 cm soil surface profile.

Indicator	Time	Maximum	Minimum	Mean	Medium	SD	Skewness	Number
EC (mS/cm)	2012	6.36	0.09	0.80	0.55	1.25	4.18	24
	2013	134.3	0.16	18.63	3.71	35.74	2.47	24
	2014	31.5	0	8.17	3.88	8.90	1.16	36
	2015	26.4	0	8.65	5.24	8.86	0.67	36
	2021	35.7	0.17	6.48	3.23	9.10	2.09	26

).

2.4. Modeling Approach

The methodological framework of this research work comprises four parts (Figure 3). The first involves the collection and processing of remote sensing-based meteorological, socioeconomic, LUCC, and biophysical data, along with openly published paper-based data and some field soil sample data. The second part focuses on model development through the interconnected use of DPSIR, BNs, and GIS to examine the salinization trend at sampling points. The third part entails an interpolation analysis of the spatial distribution probability of salinization. The fourth part investigates the factors influencing the salinization trend using the PLS-MES model.

2.4.1. Indicator Selection

The study employs a research model that integrates the Driving–Pressure–State (DPS) components of the Driving–Pressure–State–Impact–Response (DPSIR) sustainability framework. For example, temperature and precipitation are the main factors that directly affect surface evaporation; while human activities, through altering vegetation coverage, soil moisture content, and surface runoff, etc., indirectly influence surface evaporation, and all these ultimately act on the process of soil salinization [51,52]. To populate each Driver, Pressure, and State variable, we analyzed previously published research findings on soil salinization, which provided indicator sources for the probability model [24,53,54,55]. Based on representativeness and data availability, relevant spatiotemporal indicators were identified (Figure 2), and three states for each indicator were established using equal interval classification methods to determine threshold values (

Table 3. Indicators category and its threshold information.

Category	Indicator	Indicator States and Determination of Threshold
Drive	Temperature	$\mathrm{Decrease}: \mathrm{P}\_\mathrm{y}\mathrm{e}\mathrm{a}\mathrm{r}\mathrm{s}<\mathrm{P}\_(years-1)$$; \mathrm{increase}: \mathrm{P}\_\mathrm{y}\mathrm{e}\mathrm{a}\mathrm{r}\mathrm{s}>\mathrm{P}\_(years-1)$
	Soil organic matter	Low: <0.83 g/kg; medium: 0.83–1.66 g/kg; high: >1.66 g/kg
	Precipitation	Low: >42.3 mm; medium: 42.3–68.1 mm; high: >68.1 mm
	Density of population	$\mathrm{decrease}: \mathrm{P}\_\mathrm{y}\mathrm{e}\mathrm{a}\mathrm{r}\mathrm{s}<\mathrm{P}\_(years-1)$$\mathrm{stable} \mathrm{state}: \mathrm{P}\_\mathrm{y}\mathrm{e}\mathrm{a}\mathrm{r}\mathrm{s}\approx \mathrm{P}\_(years-1)$$; \mathrm{increase}: \mathrm{P}\_\mathrm{y}\mathrm{e}\mathrm{a}\mathrm{r}\mathrm{s}>\mathrm{P}\_(years-1)$
	Slope	small: <4.73°; middle: 4.73–6.20°; big: >6.20°
	Natural drainage distance	nearly: <5.76 km; middle: 5.76–11.29 km; far: >11.29 km
	Soil texture	clay: <0.2 mm; sand: 0.05–2 mm; silt: >2 mm
Pressure	Evaporation	low: >1255 mm; medium: 1255–1352 mm; high: >1352 mm
	Soil moisture content	low: <0.080 m3; medium: 0.080–0.13 m3; high: >0.13 m3
	Vegetation type trend	harmed: bare land; unchanged: cultivated land; improvement: grassland
	Field distance	nearly: <0.95 km; middle: 0.95–1.18 km; Far: >1.18 km
	NDVI	low: <30%; medium low: 30–40%; medium: 40–60%; high: >60%
State	EC	$\mathrm{degradation}: \mathrm{P}\_\mathrm{y}\mathrm{e}\mathrm{a}\mathrm{r}\mathrm{s}<\mathrm{P}\_(years-1)$$; \mathrm{Stable} \mathrm{state}: \mathrm{P}\_\mathrm{y}\mathrm{e}\mathrm{a}\mathrm{r}\mathrm{s}\approx \mathrm{P}\_(years-1)$$; \mathrm{improvement}: \mathrm{P}\_\mathrm{y}\mathrm{e}\mathrm{a}\mathrm{r}\mathrm{s}>\mathrm{P}\_(years-1)$

).

2.4.2. Bayesian Network

A BN elucidates the dependencies among variables and enables predictions based on prior probabilities [56]. Also referred to as a belief network model, a BN links each node to a conditional probability distribution (CPD), which quantifies the influence of parent nodes on child nodes [30]. The parent node refers to the node that has a direct influence on other variables in the network structure, and the child node responds to the changes of the parent node; a complete set of parent-child nodes is called an evidence chain [57,58]. In practical inference, BNs typically depend on the CPD of variables and the BN theorem for calculations (Figure 4). The fundamental expression of the BN theorem is as follows:

$$P(\alpha │\beta )=\left(P\right(\alpha │\beta \left)P\right(\alpha \left)\right)/P\left(\beta \right)$$

(1)

where $P\left(\alpha \right)$ and $P\left(\beta \right)$ denote the probabilities of independently observing $\alpha$ and $\beta$, without accounting for their mutual influence; $P(\alpha │\beta )$ signifies the conditional probability of $\alpha$ given $\beta$; and $P(\alpha │\beta )/P\left(\beta \right)$ represents the Bayesian factor or likelihood ratio.

2.4.3. Model Validation

BN node hypothesis testing was employed for model performance evaluation. This method assesses whether significant synchronous relationships exist between variables by introducing prior distributions and observed data to compute posterior distributions. It is particularly well-suited for large datasets where clear parent-child node relationships have been established based on existing knowledge [59,60]. We conducted BN hypothesis testing at 36 sampling points. Each test was performed node-by-node using observational data from 2000 to 2023, comparing prior and posterior probability distributions 300 times for each point (totaling 10,800 times) to analyze variable synchronization characteristics. Its equation is as follows:

$$B{F}_{10}=\left(P\right(D│H_1\left)\right)/\left(P\right(D│H_0\left)\right)$$

(2)

where, $B{F}_{10}$ represents the BN Factor, $H_0$ denotes the null hypothesis, and $H_1$ denotes the alternative hypothesis. $P(H│D)$ is the marginal likelihood of observing the data D under hypothesis H, which integrates over all possible parameter values.

2.4.4. Tension Spline Function

Spline interpolation is a deterministic interpolation method that can construct the model’s predicted results as a smooth surface passing through all the known points. There are two types of spline interpolation: regularization and tension. In this study, the tension spline interpolation method was adopted. Based on correlation and error analysis, it was found that the performance of the tension spline method was superior to that of the regularized spline method [61,62]. The tension spline function approximates a complex function or dataset using a series of polynomial segments. These segments are connected at specific nodes, forming a continuous curve [63]. The mathematical expression is as follows:

$$z\left(x,y\right)={\sum }_{i=1}^n{\lambda }_{i}R\left(r_i\right.,\left.\varphi \right)+T\left(x\right.,\left.y\right)$$

(3)

where $z(x,y)$ represents the interpolated value at spatial location $(x,y)$; ${\lambda }_i$ is the weight coefficient; $R\left(r_i\right.,\left.\varphi \right)$ is the radial basis function; $r_i$ is the Euclidean distance between the ith known point and $(x,y)$; $\varphi$ is a parameter that controls the shape of the function; and $T\left(x\right.,\left.y\right)$ is the trend function, which describes the global trend of the data.

2.4.5. PLS-SEM Model

Partial least squares structural equation modeling (PLS-SEM) is one of the most widely used methods of multivariate data analysis [64]. The PLS-SEM model analyzes the causal relationships between multiple variables with the covariance matrix as the core, including measurement models and structural models as two basic models [65]. The measurement model describes the relationships between the latent variables and their corresponding observed variables with the following equations:

$$\mathsf{{\rm Y}}={\mathsf{\Lambda }}_y\eta +\epsilon$$

(4)

$$X={\mathsf{\Lambda }}_x\xi +\delta$$

(5)

Equations (4) and (5) are the endogenous and exogenous variables, respectively. ${\mathsf{\Lambda }}_x$ is the factor loading matrix of the exogenous measurable variable on the exogenous latent variable $\xi$; ${\mathsf{\Lambda }}_y$ is the factor loading matrix of the endogenous measurable variable on the endogenous latent variable $\eta$; $\delta$ and $\epsilon$ are the measurement model error terms.

The structural model reflects the causal relationship between endogenous latent variables and exogenous latent variables with the following expressions:

$$\eta =B_{\eta }+\mathsf{\Gamma }\xi +\zeta$$

(6)

where $\eta$ is the endogenous latent variable, $\xi$ is the exogenous latent variable, and $B$ denotes the effect of the exogenous latent variable on the endogenous latent variable. $\mathsf{\Gamma }$ is the path coefficient, which measures the effect of the exogenous latent variable on the endogenous latent variable, and $\zeta$ is the structural model residual term [66].

3. Results

3.1. Model Sensitivity Analysis

The model sensitivity analysis was performed for fifteen chains of nodes using BNs node hypothesis testing (Equation (2)). The chains a, b, c, f, g, h, j, l, and n indicated relatively higher accuracy with an error rate of <20%; the chains i, k, m, and o showed accuracy with an error rate of <25%; and the chains d and e had an error rate between 25% and 35%. The highest sensitivity was found in chain a, while the lowest sensitivity was found in chain e, which requires additional investigation (

Table 4. Results of the model validation exercise.

No.	Chain of BN Nodes	Accuracy (%)	Number of Tests
a	Soil texture—NDVI	90	720
b	Soil organic matter—NDVI	84
c	Soil organic matter—LUCC	87
d	Precipitation—LUCC	73
e	Precipitation—Soil moisture content	66
f	Density of population—LUCC	83
g	Density of population—Field distance	81
h	Field distance—Soil moisture content	83
i	Soil moisture content—Evaporation	75
j	NDVI—Evaporation	80
k	LUCC—Evaporation	78
l	Temperature—Evaporation	87
m	Evaporation—EC	77
n	Slope—EC	83
o	Natural drainage channels—EC	76
	Average	80.2	Total 10,800

).

3.2. Spatio-Temporal Changes of Soil Salinization

3.2.1. Temporal Changes of Soil Salinization

The changes in EC by 36 points in the Yutian oasis in 2012 were compared with the measured data in 2021. Among them, the EC of Y01, Y13, Y18, and Y21 sampling points decreased by 0.02, 0.26, 0.38, and 0.38, respectively, in the two-year data comparison. The EC at sampling points Y08, Y11, Y20, and Y35 increased by 14.68, 21.44, 8.83, and 8.44, respectively, which requires additional investigation (

Table 5. Comparison Results of Sampling Points’ EC between 2012 and 2021.

Sample ID	Y01	Y02	Y03	Y04	Y05	Y06	Y07	Y08	Y09	Y10	Y11	Y12
EC change from 2012 to 2021 (mS/cm)	−0.02	0.35	0.15	14.68	0.16	5.21	1.19	16.65	1.34	0.05	21.44	2.28
Sample ID	Y13	Y14	Y15	Y16	Y17	Y18	Y19	Y20	Y21	Y22	Y23	Y24
EC change from 2012 to 2021 (mS/cm)	−0.26	2.68	5.48	1.91	0.33	−0.38	6.24	8.83	−0.38	3.52	2.47	4.84
Sample ID	Y25	Y26	Y27	Y28	Y29	Y30	Y31	Y32	Y33	Y34	Y35	Y36
EC change from 2012 to 2021 (mS/cm)	5.28	4.89	−0.32	5.58	2.54	2.47	1.54	6.04	1.02	0.96	8.44	4.61

).

3.2.2. Spatial Characteristics of Salinization Probability Trend

Based on probabilistic theory (Equation (1)), we produced BNs to study the impact of twelve factors on salinization trends at 36 sampling points in the Keriya Oasis (Figure 1 and Figure 4). The software generated a total of 1049 conditional probabilities among 15 node chains for these points (Table 4). The salinization probability for each sampling point was calculated across three types of trends: degradation, stable state, and improvement. Subsequently, using the tension spline function of ArcGIS 10.8, we produced spatial distribution maps of salinization probability in the Keriya Oasis.

Results indicate that (Figure 5) the salinization probability in the Keriya Oasis exhibits clear spatial characteristics, with larger degradation areas located along the southern margin of the oasis in both the eastern and western parts, where intense anthropogenic activities occur in flat terrain with poor drainage. Stable state areas are predominantly found in the northwest and some northern regions of the oasis, characterized by sparsely populated natural vegetation and a dominant ecotone ecosystem. The improvement areas are located near degradation zones to the north, likely due to specific rational desalinization practices. The likelihood of degradation varies from 35% to 79%, stability from 0% to 58%, and improvement from 0% to 48%. In terms of degradation, stable state, and improvement, the minimum and maximum probability order is 79% > 58% > 48%, and 31% > 0% = 0%, respectively. This indicates that the probability of salinization degradation is higher than that of the stable state, which in turn is higher than the probability of improvement. Notably, the maximum probability of improvement in the oasis is less than 50%, indicating almost no chance of salinization enhancement under the current situation.

3.3. Area Analysis of Salinization Probability Trend

If the probability of the event P (Y = 1) is ≥50%, it is predicted to occur. This study divided the salinization probability into four groups based on the median value of 50%. The spatial distribution of salinization probability indicates that, as shown in (Figure 6), the predominant state of salinization trend is expected degradation and stable state events, with improvement being unlikely.

Among these, the degradation probability of 60–80% accounts for 15.47% of the total area, covering 284.02 km²; 50–60% accounts for 42.80% of the total area, covering 785.93 km²; and 40–50% accounts for 39.24% of the total area, covering 720.64 km². The stable state probability of 50–60% accounts for 1.41% of the total area, covering 25.91 km², while 40–50% accounts for 9.28% of the total area, covering 170.38 km². The improvement probability of 40–50% accounts for 3.43% of the total area, covering 62.95 km².

3.4. Analysis of Spatial Superposition with Different Probabilities

The geospatial overlay analysis identified distinct zones with varying probabilities of salinization states, allowing for the development of predictive models. The integrated probability distribution maps of three salinization trends delineate zones that can be interpreted in terms of salinization state probabilities (Figure 7). Figure 7 illustrates spatial domains where the probability of salinization exacerbation ranges from 50% to 77.8%. At the 77.8% probability threshold for exacerbation, the combined probability of the remaining two states converges to 22.2%, indicating a near-dominance of degradation dynamics in these zones.

4. Discussion

4.1. Mechanism of Drivers Coupling the Salinization Spatiotemporal Probability

To analyze the effects of multiple factors on the trend of salinization probability through various mechanisms, we studied the complex correlations between the dynamic probability of salinization and its key spatiotemporal drivers (13 spatial variables, ranging from 2000 to 2023) using PLS-SEM. This approach is valuable for compensating for the inadequate analysis of factor interactions in studies of complex salinization problems [67].

The arid oasis is a landscape unit with higher vegetation coverage and population density, particularly in the core area of the oasis, which experiences high population density and nearly all agricultural activities. However, in this part of the region, in order to ensure a suitable living environment, a large number of human and material resources are invested to ensure that the soil salinization is under control. Relevant research results show a clear correlation between vegetation density and population [68]. People tend to settle in areas with higher vegetation coverage, suitable topography and texture for drainage, and convenient hydrological conditions for cultivating crops. As the distance from farmland increases, population density decreases [69]. Agricultural activities within the oasis influence water allocation strategies, with farmland receiving more water than the ecotone, which increases soil moisture content in the farmland [70,71,72]. Subsequently, strong evaporation occurs in farmland compared to the ecotone, but salinization is less pronounced in the farmland. Frequent irrigation helps leach salts deeper into the soil layers, while the ecotone, due to sparse precipitation, has almost no water input to leach salts from the surface into deeper layers.

The Taklimakan adjacent to Keriya Oasis is dominated by desert soil with coarse particles, large pores, and rapid water infiltration. Following irrigation or precipitation, salts tend to migrate downward with the water, leading to low soil moisture content and, to some extent, reducing the risk of salinization [73]. In contrast, clay soils, composed of fine particles with a dense pore structure and low permeability, cause water to accumulate at the surface, and subsequent evaporation intensifies the accumulation of salts in the topsoil [74]. Therefore, frequent irrigation elevates the groundwater table in the ecotone, especially in flat, low terrain and low-lying areas where slopes descend sharply. A common landscape feature is a strongly salinized barren area surrounded by high grass at higher topographical positions [75].

Long-term irrigation with low-quality water sources leads to increased soil pH, electrical conductivity, and total inorganic carbon content, while reducing microbial activity, total organic carbon, and labile carbon pools, thereby resulting in the degradation of soil quality [76]. It is evident that a higher salinization hazard is closely related to a shallow groundwater table, flat terraces, poor drainage conditions, and salt-tolerant vegetation in marginal ecotone areas [24,77].

Furthermore, previous studies indicate that an increase in cultivation duration raises soil organic matter content, while other research suggests that salt-tolerant plants in ecotone areas also contribute to increased organic matter content in salinized soils. This highlights the role of organic matter in enhancing soil fertility and self-purification ability, thereby reducing salinization risk [78,79]. However, while organic matter content is higher in ecotone areas than in desert soils, the salinization risk is also higher in these areas [80,81].

The oasis marginal ecotone has a fragile ecosystem and lower environmental capacity than the inner cultivated oasis. However, the ecotone may exhibit some improvement in salinization due to natural drainage, higher topographical positions, and a beneficial surface water system [21,82]. It is clear that different management strategies are recommended for different landscape types based on the varying mechanisms of influencing factors. Figure 8 illustrates the impact mechanism of 10 significant spatiotemporal variables on soil degradation trends in the southern margin of the oasis, covering both the eastern and western parts.

There is a significant and direct negative correlation between salinization deterioration and the combined factors of increasing population density, elevated evaporation, and soil texture transitions, with population density exerting the strongest influence. Soil organic matter is directly and positively correlated with both salinization deterioration and population density, with population density again playing the dominant role.

Slope shows a direct positive correlation with both population density and salinization deterioration, while exhibiting a direct negative correlation with NDVI. Among these, the positive correlation with salinization deterioration is the most prominent. Distance from farmland is significantly and negatively correlated with both population density and soil moisture, while being positively correlated with NDVI. Consequently, it is indirectly and positively associated with salinization deterioration. Vegetation type is significantly and directly negatively correlated with NDVI, and subsequently, it is indirectly and positively associated with salinization deterioration (Figure 8).

The improvement areas are located near degradation zones to the north, likely due to specific rational desalinization practices, and are correlated with nine significant impact factors (Figure 9). Stable state areas are predominantly located in the northwest and some northern regions of the oasis, which are also correlated with nine significant impact factors (Figure 10). A significant negative correlation exists between population density and salinization improvement, while a significant positive correlation is observed between population density and salinization stability. Evaporation and soil texture show no significant relationship with salinization improvement, but they are significantly and positively correlated with the stable salinization state. Soil organic matter is directly and negatively correlated with the stable state; however, when mediated by population density, it exhibits a significant positive correlation with the stable state. Additionally, it is directly and positively correlated with salinization improvement. Distance from farmland is positively correlated with salinization improvement through the influence of population density, but negatively correlated with soil moisture. It is directly and negatively associated with the stable state, indirectly negatively correlated via population density, and positively correlated with the stable state through moisture conditions.

In summary, effective anthropogenic activities—such as the management of irrigation practices, organic matter levels, and vegetation coverage—are critical for mitigating soil salinization. By adopting optimized irrigation techniques and maintaining an appropriate balance of organic matter inputs, the long-term sustainability of cultivated lands can be ensured, reducing the adverse effects of salinization on agricultural productivity and soil health. In oases, each influencing factor exhibits a distinct spatial-geographic effect on soil salinization. Variations in landform, vegetation and population distribution, slope, and hydrological characteristics determine the intensity and feedback mechanisms of their influence on salinization. This study advocates that addressing soil salinization in oases requires analyzing its driving factors and mechanisms at a micro-scale. Specific mechanisms of salinization and their influencing factors should be examined within the context of individual landscapes and geomorphic units. By synthesizing the salinity characteristics and driving mechanisms across all landscape units within the oasis, an integrated model for comprehensive oasis-wide salinization management can be developed.

4.2. Regional Differences in Soil Salinization in the Keriya Oasis

The research results indicate that the deterioration of oases is concentrated in the peripheral areas, which are the transitional zones between oases and deserts [83]. The Keriya Oasis Interlaced Area is located downstream of the oasis or at the edge of the alluvial fan [84]. It is the final area for salt transport [85]. Due to the topography of the Keriya Oasis, the salt carried by surface runoff and groundwater accumulates in the interconnected areas at lower altitudes [86]. And due to the gradual flattening of the terrain and the absence of drainage channels, the salt cannot continue to migrate but can only remain and accumulate [87]. The irrigation water within the oasis also accumulates in the interlocking areas due to the terrain conditions [88]. In some areas within the oasis, a large amount of irrigation water infiltrates during the summer, resulting in a strong leaching effect, significantly reducing the salt content in the shallow soil [24]. The soil salinization remains in a stable state, and the well-developed drainage system also plays an important role [89]. The high vegetation coverage in the western part of the oasis reduces soil water evaporation and inhibits capillary rise [90]. The eastern part of the oasis is the core agricultural area [91]. The drip irrigation agriculture and the well-developed drainage facilities make it possible to improve the salinization problem [89].

4.3. Implications for Land Use Policy and Management

The spatial modeling of soil salinization presented in this study emphasizes the need for proactive and adaptive land use policies in arid regions like the Keriya Oasis. The integration of BNs with GIS offers a data-driven approach to identifying degradation-prone areas and prioritizing mitigation efforts [30,38]. The observed concentration of salinization in degraded and transitional land-use zones suggests the importance of regulating land conversion and promoting sustainable irrigation practices [54,92]. Policies should support the implementation of precision irrigation, salt-tolerant cropping systems, and managed aquifer recharge to mitigate the risk of secondary salinization [22,23,93,94]. Strategic land zoning, coupled with incentives for ecological restoration (e.g., vegetation cover, organic amendments), can enhance long-term soil resilience [95]. Moreover, participatory land-use planning involving local farmers and institutions has been shown to improve policy uptake and management outcomes [96,97]. This study’s spatial-probabilistic framework supports evidence-based policy development by enabling decision-makers to visualize salinization hotspots and evaluate future land-use scenarios under uncertainty.

5. Conclusions

The purpose of this study was to investigate the differences in soil salinization in internal regions of the Keriya Oasis. The Keriya Oasis is a small-scale, ecologically fragile arid area, and the existence of internal differences is the main reason for the difference in salinization trends. Using a BNs model combined with remote sensing, field-based EC data, and ArcGIS analysis, the spatial distribution and trends of salinization—improvement, stability, and degradation—were mapped and quantified. The model demonstrated strong predictive performance, with most variable chains showing errors below 25%, validating its robustness for complex eco-environmental analysis. Salinization is influenced by multiple interacting factors, including population density, soil texture, slope, and vegetation cover, as revealed through PLS-SEM analysis. Farmland tends to show lower salinization due to irrigation and organic matter input, whereas ecotone areas are more vulnerable due to poor drainage and limited water availability. Nonetheless, some ecotone zones exhibit improvement due to favorable topography and natural drainage. The findings emphasize that salinization processes and their drivers vary across landscape units, requiring tailored management strategies. Effective practices such as optimized irrigation and organic matter enhancement are critical to reducing salinity and sustaining agricultural productivity. This research supports the development of integrated, landscape-specific salinization management approaches and highlights the importance of high-resolution monitoring for future refinement.