Remote Sensing of Soil Alkalinity and Salinity in the Wuyu’er-Shuangyang River Basin, Northeast China

Bai, Lin; Wang, Cuizhen; Zang, Shuying; Zhang, Yuhong; Hao, Qiannan; Wu, Yuexiang

doi:10.3390/rs8020163

Cited by 56 publications

(59 citation statements)

References 29 publications

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“…There is a positive and significant correlation between pH and EC (r = 0.57; p≤0.01) pH and Na + (r =0.59; p≤0.01) and Cl − (r =0.63) and SO 4 2− (r = 0.51) signifying that the pH of the soil is primarily influenced by the Cl − and SO 4 2− content (Table 2). Bai et al, (2016) also reported positive correlation between pH and EC and Na + ions in the Wuyu'er-Shuangyang River Basin, Northeast China. The pH variation in the area is small as indicated by low CV which can be attributed to high buffering capacity of the soils and absence of carbonates in the saturation extract (Sharma and Gupta, 1986).…”

Section: Soil Phmentioning

confidence: 79%

“…Vadivelu et al, (2001) also reported positive significant correlation between available K and organic carbon and clay. Under saline and sodic soils, K fertilization management may need to be altered because of potassium competition with other cations especially Na + in the plant and to the effects of salinity in K reactions in soil (Bar-Tal et al, 1991). The coefficient of variation varied sharply with depth indicating lateral and vertical variation.…”

Section: Available Potassium (K)mentioning

confidence: 99%

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Geoinformatics for Quantifying Salt Affected Soils in Gohana, Haryana Using Soil Techniques

Grewal¹,

Singh²,

Grewal³

2017

Int.J.Curr.Microbiol.App.Sci

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Section: Soil Phmentioning

confidence: 79%

Section: Available Potassium (K)mentioning

confidence: 99%

Geoinformatics for Quantifying Salt Affected Soils in Gohana, Haryana Using Soil Techniques

Grewal¹,

Singh²,

Grewal³

2017

Int.J.Curr.Microbiol.App.Sci

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“…Due to the human activities, climate, geology, and terrain conditions, these mid-latitude semi-arid grasslands are salinized and alkalized at various degrees [32][33][34]. As a result, the Songnen grasslands are at different succession stages with diverse community compositions and, hence, show a typically heterogeneous landscape.…”

Section: Test Areamentioning

confidence: 99%

Temporal Interpolation of Satellite-Derived Leaf Area Index Time Series by Introducing Spatial-Temporal Constraints for Heterogeneous Grasslands

2017

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Continuous satellite-derived leaf area index (LAI) time series are critical for modeling land surface process. In this study, we present an interpolation algorithm to predict the missing data in LAI time series for ecosystems with high within-ecosystem heterogeneity, particularly heterogeneous grasslands. The algorithm is based on spatial-temporal constraints, i.e., the missing data in the LAI time series of a pixel are predicted by the phenological links with other pixels. To address the uncertainties in the construction and selection of reference curves in a heterogeneous landscape, the algorithm constructs a reference dataset for each missing data in the LAI time series from all pixels showing very strong linear phenological links with the target pixel within a region. We also use an iterative process to update the available spatial-temporal constraints. We tested the algorithm with an eight-day composite Moderate Resolution Imaging Spectroradiometer (MODIS) LAI product in the Songnen grasslands, Northeast China in 2010 and 2011. The validation dataset was generated based on high quality time series by artificially adding data gaps. The algorithm achieved high overall interpolation accuracies with high coefficient of determination R 2 (>0.9) and low root mean square error (RMSE) (<0.2) in both dry (2010) and wet (2011) years. The algorithm showed advantages in predicting missing data for different seasons and proportions of missing data versus the algorithm that uses regional average LAI curve as a reference. These results suggest that the proposed algorithm could more effectively characterize spatial-temporal constraint information in heterogeneous grasslands for temporal interpolation.

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“…There is renewed interest in the use of broadband multispectral imagery for regional soil salt content prediction (e.g., [4,5,[9][10][11][12][13][14][15][16]). Generally, these studies include (1) the bands' selection and investigation of spectral indices, including salinity indices and vegetation indices (e.g., [12,13]); (2) the optimized combination of bands and spectral indices for modeling, such as [4,5,14]; and (3) the long-term soil salinity dynamic analysis, such as in References [15,16].…”

Section: Introductionmentioning

confidence: 99%

Agricultural Soil Alkalinity and Salinity Modeling in the Cropping Season in a Spectral Endmember Space of TM in Temperate Drylands, Minqin, China

Sun

Jiang

2016

Remote Sensing

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This paper presents the potential of the four-image spectral endmember (EM) space comprising sand (SL), green vegetation (GV), saline land (SA), and dark materials (DA), unmixed from Landsat TM/ETM+ to map dryland agricultural soil alkalinity and salinity (i.e., soil alkalinity (pH) and soil electrical conductivity (EC)) in the shallow root zone (0-20 cm) using partial least squares regression (PLSR) and an artificial neural network (ANN). The results reveal that SA, SL, and GV fractions at the subpixel level, and land surface temperature (LST) are necessary independent variables for soil EC modeling in Minqin Oasis, a temperate-arid system in China. The R 2 (coefficient of determination) of the optimized parameters with the ANN model was 0.79, the root mean squared error (RMSE) was 0.13, and the ratio of prediction to deviation (RPD) was 1.95 when evaluated against all sampled data. In addition to the aforementioned four variables, the DA fraction and the recent historical SA fraction (SAH) in the spring dry season in 2008 were also helpful for soil pH modeling. The model performance is R 2 = 0.76, RMSE = 0.24, and RPD = 1.96 for all sampled data. In summary, the stable EMs and LST space of TM imagery with an ANN approach can generate near-real-time regional soil alkalinity and salinity estimations in the cropping period. This is the case even in the critical agronomic range (EC of 0-20 dS·m −1 and pH of 7-9) at which researchers and policy-makers require near-real-time crop management information.

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Remote Sensing of Soil Alkalinity and Salinity in the Wuyu’er-Shuangyang River Basin, Northeast China

Cited by 56 publications

References 29 publications

Geoinformatics for Quantifying Salt Affected Soils in Gohana, Haryana Using Soil Techniques

Geoinformatics for Quantifying Salt Affected Soils in Gohana, Haryana Using Soil Techniques

Temporal Interpolation of Satellite-Derived Leaf Area Index Time Series by Introducing Spatial-Temporal Constraints for Heterogeneous Grasslands

Agricultural Soil Alkalinity and Salinity Modeling in the Cropping Season in a Spectral Endmember Space of TM in Temperate Drylands, Minqin, China

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