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Article

Land Surface Parameterization at Exposed Playa and Desert Region to Support Dust Emissions Estimates in Southern California, United States

by
Yen-Ben Cheng
*,
Hank Dickey
,
Yohannes T. Yimam
,
Brian Schmid
,
Bronwyn Paxton
,
Maarten Schreuder
and
Reed Tran
Formation Environmental, LLC, 1631 Alhambra Blvd., Suite 220, Sacramento, CA 95816, USA
*
Author to whom correspondence should be addressed.
Remote Sens. 2022, 14(3), 616; https://doi.org/10.3390/rs14030616
Submission received: 4 December 2021 / Revised: 19 January 2022 / Accepted: 24 January 2022 / Published: 27 January 2022
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Versions Notes

Abstract

:
Remote sensing technologies provide a unique opportunity to identify ground surfaces that are more susceptible to dust emissions at a large scale. As part of the Salton Sea Air Quality Mitigation Program (SSAQMP) of the Imperial Irrigation District (IID), efforts have been made to improve our understanding of fugitive, wind-blown dust emissions around the Salton Sea region in Southern California, United States. Field campaigns were conducted for multiple years to evaluate surface conditions and measure the dust emissions potential in the area. Data collected during the field work were coupled with remote sensing imagery and data mining techniques to map surface characteristics that are important in identifying dust emissions potential. Around the playa domain, surface crust type, sand presence, and soil moisture were estimated. Geomorphic surface types were mapped in the desert domain. Overall accuracy ranged from 91.7% to 99.4% for the crust type mapping. Sand presence mapping showed consistent and slightly better accuracy, ranging from 96.2% to 99.7%. Soil moisture assessment agreed with precipitation records. Geomorphic mapping in the desert domain achieved accuracy above 93.5%, and the spatial pattern was consistent with previous studies. These land surface condition assessments provide important information to support dust emissions estimates in the region.

1. Introduction

Dust emissions caused by high wind speeds have a significant impact on global climate, terrestrial ecosystems, and public health [1,2,3,4]. The principle of dust emissions is a function of the power of wind to erode and the resistance of a potentially emissive surface to erosion [5,6]. The entire mechanism involving chemical, physical, and biogeological processes is complex and can be significantly heterogeneous in spatial and temporal domains [3,5,7,8,9]. While much effort has been put toward the better understanding, mapping, and modeling of dust sources and emissions over the past few decades, challenges and uncertainties still exist [3,5,10,11]. Dust researchers face the challenge of the diverse nature of landforms, local surface conditions, and the associated emissions potential when modeling potential dust emissions at a large scale [9,12]. To model dust emissions, one should consider crucial factors such as threshold friction velocity, the minimum friction velocity required to initiate movement of soil particles, and the variability in erodibility [5,13,14]. Some land surface characteristics, such as soil moisture, particle size, and degree of crusting, have been reported to influence the variability of the surface erosion thresholds [5,15,16,17,18]. Remote sensing and Geographic Information System (GIS) technologies have often been used in wind erosion risk and dust emission mapping studies. This is largely because these technologies can provide valuable land surface parameterization and land cover type information over a large area with frequent revisit.
To support dust emission studies, remote sensing techniques have been used as a reliable and cost-effective tool to identify emission sources and areas susceptible to emission: emission “hot spots” [1,3,19,20,21]. In addition, satellite imagery can provide valuable land surface parameterizations required as input for emission models—for instance, soil particle size distribution and crust types [3,22,23]. Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER) images were utilized along with field measurements to provide land use classification and vegetation coverage in Inner Mongolian grasslands, China [24] to study wind erosion risk resulting from intensive grazing. Crust types are often used to characterize playa surfaces and their emissive characteristics [4,17,25]. For instance, in a study focused on field measurements of dust emission, Sweeney and colleagues [25] define different playa surfaces encountered in the Mojave Desert as gravel-covered beach ridges, mud cracked silt/clay crusts, continuously crusted surfaces without cracks, and salt crusts ranging from smooth to rough or botryoidal. In a similar study, playa surfaces at Yellow Lake playa, West Texas, USA, was differentiated, by surface type—playa, aeolian ripples, and lunette dune; and crust type—botryoidal, slightly botryoidal, smooth, and irregular, to parameterize emissions flux sampling [17]. Remote sensing techniques have been successfully employed to partition playa and/or desert surfaces into different crust types [22,23,26]. Rozenstein and Karnieli [23] were able to separate spectrally distinct Biological Soil Crusts (BSCs) and bare soil surfaces in a dune environment between Israel and Egypt. To retrieve useful land surface information from remote sensing observations, image classification techniques are often used.
Classification of remotely sensed image data is one of the most studied topics in the field of remote sensing due to its wide range of ecological, environmental, and socioeconomic applications [27,28,29,30]. Approaches to classify remote sensing data vary from relatively straightforward algorithms based on clustering of reflectance values and band ratio spectral indices to more sophisticated methods based on multivariate regression and machine learning [27,29,30,31]. Data mining and machine learning techniques such as distribution random forest (DRF) have been widely utilized in land surface mapping and monitoring applications with remote sensing data in recent years [31,32,33,34,35]. Classification on remote sensing imagery can be further categorized into two techniques: a pixel-based approach and object-based image analysis (OBIA) [28,36]. Pixel-based approaches consider the image pixel as the basic unit of analysis, and this technique has been developed and applied for the last few decades [28,30,37]. With the advances of high-resolution imagery in recent years, pixel sizes are often smaller than the objects of interest. With the increase in spatial resolution, an alternative approach, the OBIA, was developed and often utilized with high spatial resolution remote sensing data [38]. Instead of processing each individual pixel, the OBIA technique analyzes remote sensing data based on objects of interest as a group of pixels [36,38,39]. Instead of considering a remote sensing image as a collection of individual pixels, this method performs segmentation to generate objects (a group of pixels with similar quantitative features) and to conduct analysis based on objects instead of pixels [28,36,38].
Soil moisture is an important parameter that plays a critical role in a wide range of ecological, environmental, and hydrological processes—for instance, water erosion, water infiltration, and evapotranspiration [40,41]. Furthermore, soil moisture is an important driver of the potential of surfaces to produce dust emissions during high wind conditions [42,43]. Remote sensing techniques provide a powerful tool to characterize soil moisture over large spatial extent [44,45]. Previous studies have shown how surface moisture correlated with the interaction of electromagnetic radiation with soils; thus, various methods have been developed to use optical, thermal, and microwave remote sensing data to monitor soil moisture content [41,44,46,47,48,49,50]. Among the different methodologies, optical methods are particularly valuable because satellite observations at optical wavelengths can usually provide higher spatial resolution, compared to thermal and microwave data [40]. Use of passive optical remote sensing data to monitor soil moisture is often based on reflectance in the shortwave infrared (SWIR) spectral region [40,49,51]. In this approach, simple correlations are formulated between soil moisture and surface reflectance. Although this approach requires careful calibration, it is a common and straightforward approach and has been used in many previous studies [52,53,54,55].
In our recent studies, a series of field campaigns were conducted with the goal to better understand dust emissions potential at the exposed playa and desert region to the west of the Salton Sea, a terminal lake located in southern California [56,57]. Dust emission potential represents the dust emission flux of a surface when subjected to a wind-driven friction velocity or sheer stress [58]. Crust type, the presence of surface sand, and soil moisture were identified as the most influential characteristics on erodibility of the playa surface [56,57]. The desert region near the Salton Sea is a complex assemblage of geomorphic surfaces. Partitioning the area into landform-based classes helps to evaluate the extent that each surface type and condition contributes to the overall dust emissions in the study area. This paper describes the utilization of remote sensing techniques to map important surface characteristics in support of dust emissions estimates. This study was conducted in support of the Salton Sea Air Quality Mitigation Program (SSAQMP) as part of a broader effort to quantify emissions from exposed playa and desert areas in the Salton Trough [56,57].

2. Methodology

2.1. Study Site

The Salton Sea is a terminal lake located in the northern portion of the Imperial Valley in Southern California, USA, approximately 130 km northeast of San Diego (Figure 1). The Sea was formed in the early 20th century when the Colorado River was accidentally and temporarily diverted west into the Salton Trough. The level of the Salton Sea has been declining in recent years [16,59]. In this study, the exposed land surface due to the declining sea level is defined as our playa study domain, shown in Figure 1. The extent of the Salton Sea waterbody was delineated on a yearly basis during the intra-annual lowstand, informed by United States Geological Survey (USGS) gauge elevation data [57]. The Modified Normalized Difference Water Index (MNDWI) [60] derived from Sentinel-2 imagery from the European Space Agency (ESA) was used to extract the Salton Sea waterbody. The MDNWI was designed to enhance open water features and has been widely used to map waterbodies [60,61,62]. Bathymetric data supplemented the approach on portions of the playa affected by sheet flow at the outlet of drains. The resulting shoreline was compared to the end-of-year 2002 shoreline to determine the exposed playa [57]. The playa domain was approximately 84.6 km2 at the end of 2018 and 96.8 km2 at the end of 2019 [57]. Additionally, a desert area west of the Salton Sea was defined as our desert study domain, as dust emissions from this region are generally transported east toward the sea during the predominant high winds from westerly directions. The desert study domain is bounded by the Imperial Valley, the Mexican-US border, the Peninsular Range, and Desert Shores (Figure 1). The desert study domain is approximately 4150 km2.

2.2. Field Campaign and Data Collection

The majority of the dataset was collected in field campaigns that were designed to provide ground-truth coupled with remote sensing data for surface parameterization within the playa study domain. All these data collected were utilized either as training data for model development or as validation data for an accuracy assessment in the next steps. A total of 17 ground-based surface survey campaigns were conducted in 104 days between June 2017 and May 2020 to characterize playa surfaces. These campaigns were designed to characterize surface properties related to dust emission potential in the study domain [56,57]. A standard set of survey data was collected during each field campaign to provide a consistent assessment of surface characteristics, including, but not limited to, crust type, soil moisture, and sand presence.
The desert study domain is not as dynamic or varying compared to the playa domain. It also covers a much greater spatial extent. Therefore, additional ground-truth points collected over 14 field campaigns on 39 days between June 2014 and April 2020 were utilized for the geomorphic mapping of the desert domain. Furthermore, additional points were selected by photo-interpretation informed by these ground-truth data and by random selection of points from maps previously developed by the California Geological Survey [63] in the area. Locations of the data collected are shown in Figure 2.

2.3. Imagery Data and Processing

Two Pleiades satellite images, acquired in October 2018 and September 2019, were used to map the crust type and sand presence in the playa study domain. The Pleiades imagery provides orthorectified multispectral (blue, green, red, near-infrared [NIR]) data with spatial resolution of 2 m. The data were converted to top-of-atmosphere reflectance using the Radiometric Calibration routine in ENVI 5.4 software (Harris Geospatial Solutions, Inc., Boulder, CO, USA). Various band ratio indices related to spectral characteristics, vegetation, and soil crust were derived from the imagery [64,65,66]. Gray Level Co-occurrence Matrix (GLCM) values associated with image texture features were also calculated from the calibrated imagery. These index values were used as predictors in development of crust type and sand presence classifiers. Definitions and formulas of these various predictors are summarized in Table 1.
Observations collected with Operational Land Imager (OLI) onboard the Landsat 8 satellite were used for soil moisture mapping in the playa domain. Landsat 8 Collection 1 Level 2 data products were downloaded from the USGS between June 2018 and June 2020. Data from the SWIR 1 band (1570–1650 nm) were used in this study for soil moisture mapping. The images were visually inspected and screened for artifacts (e.g., clouds, haze, smoke) before analysis. Ultimately, 32 images collected between June 2018 and June 2020 were implemented.
Geomorphic surface mapping conducted in the desert domain utilized National Agriculture Imagery Program (NAIP) imagery. The NAIP imagery contains three bands (red, green, blue) in the visible spectral region. Alternative representation of true color images (hue, intensity, and saturation) was also calculated from the imagery. Additionally, 5 m spatial resolution NEXTMap Digital Terrain Model (DTM) data derived from airborne Interferometric Synthetic Aperture Radar (IFSAR) were acquired (NEXTMap, https://www.intermap.com/nextmap, accessed on 1 December 2021). The ortho-rectified 1 m resolution dataset representing the intensity of the SAR signal values used to generate the DTM was also acquired to provide additional information. The radar return intensity values were useful for the discrimination of surface-particle-size-based surface type classes (e.g., sand- vs. silt-dominated). Various terrain attributes (e.g., elevation, slope) were derived using the System for Automated Geoscientific Analyses GIS software (SAGA GIS, http://www.saga-gis.org, accessed on 20 November 2021) toolbox to provide environmental information related to soil and surface forming at landscape level. Detailed parameters used as predictors in desert geomorphic surface mapping can be found in Table 2.

2.4. Image Segmention

The Object-Based Image Analysis (OBIA) technique is often used to analyze remote sensing data [38,39]. In this study, the OBIA approach was used to segment an image into homogenous objects for crust type and sand mapping in the playa domain and geomorphic surface mapping in the desert domain, using Trimble eCognition Developer v9.4.0 x64 software (Trimble Inc., Sunnyvale, CA, USA). This product has been widely used in various studies related to classification and feature extraction from remote sensing data [68,69,70,71]. Individual multispectral imagery bands were imported into the software, and image segmentation was performed at several exploratory scales. An appropriate segmentation scale factor was chosen, which derived objects representative of the density of the training data and the size of playa features of interest. A scale factor is a unit-less factor that varies given the imagery resolution, bit depth, type, and other parameterized weighting. Derived objects within a single analysis event may vary in size and shape based on homogeneity of surface features. In subsequent analysis events, with identical input imagery specifications and parameterization, a common scale factor may be applicable, but should be evaluated specific to that event.

2.5. Machine Learning

Machine learning techniques have been widely utilized in land surface mapping and monitoring applications with remote sensing data in recent years as an effective and efficient approach [31,32,33,34,35]. Advantages of these machine learning algorithms include their capability to model complex class signatures, to accept a variety of input predictor data, and to not make assumptions about data distribution [31]. Machine learning algorithms are made available by the open-source H2O platform (H2O.ai, https://www.h2o.ai/, accessed on 10 November 2021) for straightforward access and implementation [72]. H2O enables the implementation of various machine learning, deep learning, and artificial intelligence algorithms including Random Forests (RF), Extremely Randomized Trees (XRT), Gradient Boosting Machines (GBM), and Neural Network (NN) algorithms [72,73,74,75]. This platform has been utilized in previous land surface mapping and monitoring studies with remote sensing data [32,34]. H2O’s Automatic Machine Learning (AutoML) framework evaluates and optimizes multiple learning algorithms (e.g., RF, GBM, NN) at once to attain better predictive performance. This framework was utilized in this study to develop classifiers for crust type and sand presence mapping in the playa domain, and geomorphic surface type mapping in the desert domain. Predictor parameters (Table 1 and Table 2) at field sampling locations were extracted for model development. Prior to model development, the entire dataset was partitioned into a training dataset and validation dataset. Considerations were given to balance the class distribution within the training dataset. Therefore, within the training dataset, each class contains approximately the same number of samples to ensure fair representation of each class. Only the training dataset was utilized in development of the various classifiers. During the development, models were instructed to stop after three rounds if the model failed to further reduce error. Performance of each model was assessed and reported using a confusion matrix with the training dataset and with the independent validation dataset.

2.6. Playa Soil Moisture Mapping

Soil moisture around the Salton Sea is subject to variation temporally and spatially due to precipitation events as well as infrequent flooding due to wave action during high wind events. An empirical model between the Landsat 8 SWIR 1 band (1570–1650 nm) and surface soil moisture was developed for the playa domain by gathering ground-truth and photo-interpretative points during two Landsat 8 overpasses on 11 June 2017 and 30 June 2018 [57]. A total of 469 points were used to develop the classifier of the empirical soil moisture model. Among the 469 points, 67 ground-truth points were focused on portions of the playa with shallow slope and diffuse moisture gradients. During the campaign, two soil moisture classes—“dry” (no soil moisture present) and “wet” (wilting point to field capacity or wetter)—were assessed in the field. The volumetric soil moisture content of the “dry” and “wet” classes was verified from 57 samples. The water content of the dry class was characterized as follows: lower quantile, median, and upper quantile of 0.9%, 2.4%, and 11.3% water by volume, respectively. The wet class was characterized as follows: lower quantile, median, and upper quantile of 15.3%, 22.8%, and 35.9% water by volume, respectively. A threshold of 0.33 for the Landsat 8 SWIR 1 values was identified as an appropriate classifier to differentiate between “dry” and “wet” surface soil moisture classes. Pixels with values higher than the threshold are classified as “dry” while the others are classified as “wet” [57]. This empirical model was applied to 32 images from June 2018 through June 2020 to provide soil moisture information (dry or wet) in the playa domain.

3. Results

Within the playa domain, small water bodies and playa vegetation were first delineated from open playa (bare soil) using Pleiades imagery. This was achieved using classifiers based on XRT by the AutoML procedure and visual inspection. Water bodies have strong absorption features across the visible and NIR spectral region while healthy vegetation contains unique spectral characteristics due to chlorophyll. These features make both classes clearly distinguishable from open playa.

3.1. Crust Type Mapping

Playa surfaces are regularly characterized by partitioning unique surfaces into classes based on texture, relief, and landform. Classes and descriptors are often adjusted to account for unique conditions at a given playa. In this study, selected crust types were adapted from previous literatures to represent the unique playa surface conditions at the Salton Sea [4,17,25]. Five crust types represent the majority of the open playa area: no-crust, smooth, weak botryoidal, botryoidal, and barnacle beds. Descriptions and pictures of these distinctive crust types are shown in Table 3. These five crust types are the classes to identify and map in crust mapping analysis. The GBM model was selected by the AutoML procedure in H2O for surface crust mapping for the 2018 and 2019 images. The NDVI, the ratio of NIR to all bands, and the Zabud Index were the top three predictors for the October 2018 image, while mean NIR reflectance, NDVI, and the GLCM standard deviation were identified as the top three predictors for the September 2019 image. Crust type mapping results for September 2019 are shown in Figure 3. More detailed results and geomorphic features around the Bombay Beach area are shown in Figure 4. Detailed accuracy assessments for the classifications are reported in Table 4 and Table 5 for October 2018 and September 2019 images, respectively. With the training datasets, the crust type classification achieved an overall accuracy from 98.7% to 99.4%. The classifications were further verified using the independent validation dataset, and overall accuracy from 91.7% to 97.7% was achieved.

3.2. Sand Presence Mapping

For sand presence mapping in the playa domain, two classes—sand and no sand—were identified as important parameters to understand and estimate emissions within the area. Therefore, in this study, classification models were developed to map these two classes in the area. The GBM model was selected by the AutoML procedure in H2O to map sand presence for the 2018 and 2019 images. Sand presence was assessed in 10% surface cover intervals; the threshold between less than 10% was “no sand” and greater that 10% was “sand present.” These two groups provided a clear differentiation in dust emissions potential [56,57]. The Zabud Index, NIR, and NDVI were identified as the top three predictors for the October 2018 image, whereas the sum of visible bands, the ratio of the green band to all visible bands, and the blue reflectance were identified as the top three predictors for the September 2019 image. Sand presence mapping results in the playa domain for September 2019 are shown in Figure 5. Sand distribution associated with fluvial and aeolian sand sources in the western playa domain is also shown in Figure 5. Accuracy assessments for the classifications are reported in Table 6 and Table 7. With the training datasets, the sand presence classification achieved accuracy from 96.2% to 99.7%. The classifications were further verified using the independent validation datasets and achieved accuracy from 96.2% to 96.8%.

3.3. Soil Moisture

An empirical model was applied on the Landsat 8 data SWIR 1 band to derive a surface soil moisture map within the playa domain as two classes: “dry” and “wet.” This threshold was selected to provide a more conservative view of wetness in the original design. This was later validated by a field campaign conducted on 15 April 2020. A total of 85 locations on the playa were visited, and soil moisture conditions were assessed. Among the 85 locations, 22 locations were identified as “dry,” while 63 locations were identified as “wet.” A corresponding Landsat 8 image from 16 April 2020 was analyzed using this empirical model described above. All 22 “dry” locations were classified as “dry” by the Landsat 8 imagery. Among the 63 “wet” locations, 44 locations were classified as “wet.” This is consistent with the development of the model to provide a conservative assessment of soil moisture, as described above. Overall, the model based on the Landsat 8 SWIR 1 band exhibited a 78% accuracy. A total of 32 Landsat 8 images collected from June 2018 to June 2020 were analyzed to create soil moisture maps. The annual average of wetness within the playa domain from July 2019 and June 2020 is shown in Figure 6. For each image analyzed, the ratio of the number of “wet” pixels to total pixels within the playa domain was calculated as playa percent wet. Temporal variation of playa percent wet is shown in Figure 7. Daily precipitation data were collected from two stations (#041 Calipatria/Mulberry; #218 Thermal South) of the California Irrigation Management Information System (CIMIS) stations and one station (Fish Creek Mountain California) from the Remote Automatic Weather Stations (RAWS) network around the Salton Sea area. Daily precipitation data were plotted and are shown in Figure 7.

3.4. Desert Geographic Mapping

The desert domain in this study (Figure 1) consists of complex geomorphic surfaces. In the context of understanding dust emissions, the desert study domain was classified into landform-based classes and subclasses. Table 8 summarizes the classes and subclasses for the geomorphic mapping; it also displays whether each surface was determined to be emissive. These classes and subclasses were defined and slightly modified based on previous studies [76]. Examples of these subclasses are demonstrated in Figure 8. The geomorphic surface mapping was generated using a GBM model selected by the AutoML procedure. The most important variables in the prediction of subclasses were the diffuse insolation for the spring equinox, DTM, and ORI. The classification map is shown in Figure 9. Accuracy assessments of the classification are reported in Table 9, with training and validation datasets, respectively. Overall accuracy of the classification was 98.5% with the training data and 93.5% with the validation dataset.

4. Discussion

Dust emissions estimates and modeling is an interdisciplinary research that includes geomorphology, soil physics, meteorology, fluid dynamics, air chemistry, and ocean biology [3]. Remote sensing technologies and data provide a powerful tool to map and monitor wind erosion potential and to support dust emissions estimates. As part of an effort to improve our understanding of dust emissions around the Salton Sea region in Southern California (Figure 1) [56,57], this study reports remote sensing of land surface parameterization in support of dust emissions estimates. A series of studies and field campaigns has been conducted for multiple years within the playa and desert domain to measure dust emission potential and characterize surface conditions [56,57]. The measurements allowed us to establish the relationship between the dust emission potential and specific surface characteristics such as crust types, soil moisture, sand presence, and geomorphic surface types. These parameters were selected to be mapped for their strong influence on dust emissions [4,5,15,16,56,57] and because they can be scaled in a feasible manner from point data up to a regional landscape using remotely sensed data resources based on previous studies [22,23,26]. The relationship between these parameters and dust emission potential will then be applied to the mapping results to estimate dust emission potential within the study domain. More detailed information on the field campaigns, data analysis, and results can be found in relevant studies [56,57].

4.1. Remote Sensing Data and Classification

Crust types and sand presence were mapped for the playa study domain (Figure 1) on two dates in 2018 and 2019. Geomorphic surface types were classified for the desert study domain (Figure 1). These analyses were conducted using remote sensing data coupled with statistical machine learning techniques. Similar techniques for land surface and soil mapping have been reported in various studies previously. Quantitative remote sensing of soil properties, including organic matter, carbonate, and mineral content, though, can be challenging to achieve due to effects from vegetation cover, atmospheric conditions, spatial and spectral resolution of the data, provides the basis for this type of analysis [22,45]. Other geospatial data including topographical and environmental parameters can be applied to provide extra information and to improve accuracy [77]. Lacoste, Lemercier and Walter [77] used a regression tree-based algorithm to map soil parent material (SPM) in northwestern France. Land use data derived from Moderate Resolution Imaging Spectroradiometer (MODIS) and topographical attributes derived from 50 m Digital Elevation Model (DEM) data were utilized. Accuracy rates from 54% to 81% were reported from the study. Similarly, soil survey maps for approximately 85,000 ha in northern Iran were updated using machine learning techniques coupled with Landsat images and ASTER Global Digital Elevation Model (GDEM) data. The overall error between 48.5% to 56.6% was reported based on Soil Taxonomy great group, subgroup, and series levels [78]. ASTER data were also utilized with Support Vector Machine (SVM) data to map soil types in eastern Germany [79]. Overall accuracy of the classification varied based on training site distribution and input variable selection, and the best overall accuracy of 83% was reported [79]. Three statistical-based machine learning models (Weights of Evidence, Frequency Ratio, and Random Forest) were utilized with remote sensing data, including from Landsat and MODIS, to detect dust sources and to produce a dust source susceptibility map for northeastern Iran [20]. The analysis leveraged lithology, slope, soil, geomorphology, NDVI, and distance to water as input data. Accuracy from 82% to 91% using the training dataset and 81% to 88% using the validation dataset were reported, while Random Forest performed the best [20]. A semi-arid playa area in Bolivia was partitioned into four surface types— salty surface, silt-rich surface, clay-rich surface, and pure salt—using Landsat data and maximum likelihood classification [22]. Accuracies of 88% to 100% were reported based on training or validation datasets [22]. Identification of Biological Soil Crusts (BSCs) in the northwestern Negrev dunes across the Israel–Egypt border was studied [23]. Classification between BSCs and other four land surface types was performed using remote sensing data based Crust Index (CI), NDVI, and Thermal Curst Index (TCI) [23]. Overall accuracy of 86.2% was achieved when all three indices were utilized [23]. In this study, accuracy of at least 91.7% was achieved for the crust type and sand presence mapping in the playa domain and geomorphic surface mapping in the desert domain (Table 4, Table 5, Table 6, Table 7 and Table 9). In general, accuracies achieved in this study using either training or validation datasets were consistent with each other, while the errors were lower compared with previous soil mapping studies using similar techniques [20,77,78,79,80]. One factor may be the high-resolution remote sensing data utilized in the study. In contrast to Landsat (30 m) or MODIS data (250 m or 500 m), Pleiades imagery has a 2 m spatial resolution and, hence, a much smaller pixel size. Smaller pixels are less likely to contain mixed classes, and this may improve overall accuracy due to purity of the signal. Another factor may be the abundance of training data utilized in the study to capture the unique characteristics of the various classes.

4.2. Crust Development and Spatial Distribution on the Playa

In the playa study domain, development of crust types is a function of many contributing factors. It has been observed in situ that newly exposed playa surfaces begin as weak, unconsolidated, and smooth. Through the precipitation of salt, induced by the evaporation of saline water at the surface, the crust incrementally becomes strong, consolidated, and rough (botryoidal). Crust development generally occurs with the length of exposure, but its strength is affected by several factors, including mineralogy, precipitation, and erosion. Precipitation events dissolve salts and allow them to re-precipitate. Typically, after precipitation events, crusts degrade to the previous crust on the development sequence. For example, botryoidal crusts tend to become weak botryoidal crusts, and weak botryoidal crusts tend to become smooth crusts. Changes due to erosion (buffing and/or scouring) also usually represent a degradation on the development spectrum. These observations are generally consistent with crust development sequences recognized and reported in previous studies [26,81,82]. Relating the various factors to crust type distribution around the playa domain is a complex subject, and partitioning the impact of individual contributing factors is challenging and warrants further investigation.
Furthermore, geomorphological processes are another factor controlling the distribution of playa surface types and their erodibility [19,22]. Playa margins are a complex assemblage of geomorphic landforms (e.g., beach ridges, aeolian dunes, coastal spits and bars, deltas, splay systems) that can be used to interpret past depositional events (runoff, re-deposition, dune formation/encroachment) [83,84].
Areas of low relief are being exposed rapidly, particularly in near the New River and Whitewater River Deltas. This relatively rapid exposure generates an abundance of poorly developed smooth playa with diffuse contacts between playa crust types. Areas with intermediate relief, such as the Alamo River Delta, have been observed to have shallow, wave-cut terraces bounded by beach ridges formed by the fluctuating elevation of the Salton Sea. Beach ridges are a common playa feature, formed and subsequently abandoned by receding shorelines [84]. At these areas, laterally extensive stages of playa crust development are partitioned by linear beach ridges. Other portions of the playa with intermediate relief also exhibit shallow terraces, specifically the Tule Wash Fan and the playa bounded by Bombay Beach and the Niland Boat Ramp. Terraces at these locales are often delineated by barnacle bed beach ridges. Unlike the deltaic sites where sediment is delivered directly to the Sea by perennial rivers and redistributed by currents, these sites experience deposition events from ephemeral flow from broad sandy washes in the west and abundant, shallow, silty gulleys in the east. Sediment deposited by these flows is superimposed on Salton Sea playa deposits, adding complexity to the distribution of crust types. Fluvial deposition often forms smooth, brown, mud-cracked crusts that form next to playa-derived crusts.
Fluvial deposition often occurs on the upslope side of beach ridges. However, as accommodation space increases with the receding Salton Sea, fluvial processes can bisect beach ridge deposits, continue downslope, reworking playa surfaces and evening out terraces in the process. The chronology of these events is less apparent farther away from the shoreline, where degraded beach ridges become incorporated into the surrounding playa and their topography becomes more subdued. Buried ridges can often only be identified by a few barnacles on the surface or a strip of vegetation that has favored the relatively coarse, well-drained material. Examples of some of these geomorphic features are displayed in Figure 4. Areas with high relief that experience minimal exposure, specifically the eastern portion of the Sea north of Bombay Beach, are populated by beach zones that are characteristically less sensitive to the long-term regression of the Salton Sea due to their slow exposure rate.

4.3. Sand Presence

The migration of sand onto playa surfaces from external sources primarily occurs on the west side of the playa study domain. Aeolian deposition driven by strong westerly winds and fluvial deposits delivered by extensive, sand-laden, ephemeral creeks are the key mechanisms contributing to surficial sand deposits on the playa. A notable example of aeolian transport is the encroachment of the Salton Sea Dunes onto exposed playa surfaces at the Naval Test Base (Figure 5). Despite having a diminution in sand supply, the extensively characterized dune field has the capacity to deliver large amounts of sand onto playa surfaces [85,86,87,88]. The three primary tributaries on the west side of the Salton Sea include Arroyo Salada, Tule Wash, and San Felipe Creek (Figure 5). These tributaries deposit sediment across two alluvial fans, where sand is then available for aeolian redistribution. The larger of the two fans is located south of Salton City and is a composite of Arroyo Salada and Tule Wash (Figure 5). The San Felipe Fan is the smaller of the two fans, located approximately 15 km south (Figure 5). Sand deposited by these tributaries is distributed as diffuse sand drifts and linear strips of coppice dunes. Sand deposited onto playa surfaces is often reworked by longshore currents, swash zones, or aeolian activity. The quantity and extent of loose surficial sand deposits fluctuate as new deposition occurs, deposits are modified, or sand is sequestered via integration with developing salt crusts. Our results are generally consistent with the knowledge of sand deposition and movement in the region.

4.4. Soil Moisture

The assessment of soil moisture using remote sensing techniques has been studied for playa and desert surfaces at various spatial and temporal scales [89,90]. For instance, Levy and Johnson [89] developed a reflectance-based soil moisture index to monitor soil moisture fluctuations at Alvord Desert playa. Scheidt, Ramsey and Lancaster [90] assessed soil moisture at the White Sands Dune Field in New Mexico to build a relationship between potential soil erosion, soil moisture, and thermal inertia. Soil moisture within the playa study domain was assessed using Landsat 8 data with a 16-day revisit time in this study. Soil surface moisture is expected to exhibit greater temporal variation than crust types and sand presence because soil moisture is driven by frequency and intensity of precipitation and local weather conditions. Temporal variation of the soil moisture estimates from June 2018 through June 2020 are assessed in Figure 7. The percentage of the playa domain classified as wet (solid dotted line) is plotted and compared with daily precipitation data from three nearby meteorological stations (Figure 7). Precipitation measured at these stations reflects the late-summer to early-fall monsoonal and winter precipitation regimes that influence this region [91]. The frequency of events and annual totals from July 2019 and June 2020 were notably higher than those from the previous year for all stations. As one can observe in Figure 7, the temporal variation of soil moisture estimates agrees with the precipitation patterns. For instance, soil moisture estimates were higher in fall and winter months resulting from the significant influence of winter storms in these two years. Soil moisture estimates also responded to precipitation events, as expected. For example, playa percent wet increased significantly as a precipitation event occurred in fall 2019 after the dry summer months. Furthermore, average playa percent wet (dashed lines in Figure 7) between July 2019 and June 2020 was higher than the previous year, as the result of higher annual precipitation.

4.5. Desert Geomorphic Mapping

The desert landscape in our study domain was classified into various geomorphic surface types to improve our understanding of dust emissions in this region. Spatial extents of the various classes and subclasses are summarized in Table 10. Among the subclasses, bedrock and sand and gravel (alluvial) are the dominant subclasses within the region (Table 10). In Figure 10, the geomorphic surface map is compared with results from a previous mapping project by the California Geological Survey [63] conducted in this domain. The distribution and classification of these geomorphic surface mapping results are consistent with previous mapping efforts. Of the nine desert surface subclasses that are considered to contribute to dust emissions, the sand sheet, sand and gravel (alluvial), silt-dominated (paleolake), and dry wash subclasses account for the most acreage (Table 10). In a previous study around the region [4], dry washes, sand dunes, and distal alluvial fans were identified as the most emissive surfaces in the Salton Trough and the nearby Eastern Mojave Desert. Contrarily, silt/salt-crusted playas and desert pavements were identified as the least emissive surfaces. Although the sand sheets and the small coppice dunes superimposed upon them are not exactly the same as the Kelso Dune Field sampled in a previous study [4], all sand-dominated surfaces within the domain are considered to be emissive. Generally, two geomorphic assemblages are found to consistently produce windblown dust plumes. The first is the large contiguous sand sheets incised with wide, shallow, sandy dry washes, and the second is the outer fringes of alluvial fans where fine sand is deposited. Relatively non-emissive assemblages include the undisturbed silt-dominated (paleolake) surfaces and offshore playa surfaces. Both of these surfaces strongly resemble the relatively non-emissive silt-crusted Silver Lake playa sampled by Sweeney, McDonald and Etyemezian [4].
One should note that there may be some uncertainties in the results presented in this study. For instance, while we leverage extensive field campaign and ground truthing in this study, as shown in Figure 2, there are regions that were not covered by the survey due to limitation of resources, landownership, and the extensive spatial coverage of the study site, especially in the desert domain. Since the data collected were utilized as training or validation data for the classification, the coverage of the data may inherently affect the results. Similar discussion on the impact of field survey distribution and coverage may be found in previous studies [92,93]. In addition, uncertainties may be brought in the results due to the satellite data quality [93], for instance, the Landsat data used in this study. Initial radiometric stability of better than 0.3% was reported [94] while a succeeding study reported temporal uncertainty of better than 0.5% for Landsat 8 data when using Pseudo Invariant Calibration Sites (PICS) [95]. This could be another source contributing uncertainties in the results reported in the study. Additional field campaigns and data analysis in the future may help to further validate the results and assess the uncertainties.

5. Conclusions

Dust emission is a complex process and can vary significantly in both spatial and temporal domains. In this study, we present a surface mapping framework for the exposed playa and desert domain near the Salton Sea in Southern California, USA. By leveraging extensive ground-truth data collection and site visits during multiple field campaigns across multiple years, important surface characteristics were defined to support dust emissions estimates in the region. This was accomplished by coupling remote sensing data with statistical machine learning algorithms. In general, good accuracies were achieved by this mapping framework. The results were consistent with site knowledge and related environmental and geomorphic characteristics. These surface characteristics in the playa and desert domains provide important land surface parameterizations that will allow the following: (1) the quantification of dust emissions within the region; (2) the identification of “hot spot” areas more susceptible to dust emissions; and (3) the ability to monitor the temporal variation of dust emissions within the region.

Author Contributions

Conceptualization, B.S., H.D. and Y.T.Y.; Y.-B.C., H.D. and B.P. contributed to the overall methodology, workflow development, analysis, and validation; data curation, H.D. and Y.-B.C.; H.D. and Y.-B.C. contributed to original draft writing and preparation, writing—review and editing, Y.-B.C., H.D., M.S. and Y.T.Y.; visualization, H.D. and R.T.; supervision, B.S., Y.T.Y. and Y.-B.C.; funding acquisition, B.S. All authors have read and agreed to the published version of the manuscript.

Funding

This research and writing was supported by the Imperial Irrigation District, Service Agreement No. 8100002362, funding is reimbursed by the Quantification Settlement Agreement Joint Powers Authority, who administers funding of environmental mitigation requirements related to the QSA water transfers. The views expressed herein do not necessarily reflect the views of the funding agencies.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

The data presented in this study are openly available in the following links. Salton Sea Air Quality Mitigation Program Documents: https://saltonseaprogram.com/aqm/team-documents.php (accessed on 1 December 2021) and Salton Sea Air Quality Mitigation Program Data Portal: https://saltonseaprogram.com/aqm/data-portal/data-portal.php# (accessed on 1 December 2021).

Acknowledgments

This study was conducted in support of the Imperial Irrigation District-Salton Sea Air Quality Mitigation Program (SSAQMP) and is part of a broader effort to quantify emissions from exposed playa and desert areas in the Salton Sea Airshed. The authors specifically thank Jessica Humes, Mark Sweeney, James King, William Porter, and Amato Evan as well as the anonymous reviewers of this manuscript for their very valuable guidance, input, suggestions, and critiques.

Conflicts of Interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

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Figure 1. Playa and desert study domains around the Salton Sea region. Sources: Esri, HERE, Garmin, Intermap, Increment P Corp., GEBCO, the U.S. Geological Survey (USGS), FAO, NPS, NRCAN, GeoBase, IGN, Kadaster NL, Ordnance Survey, Esri Japan, METI, Esri China (Hong Kong), © OpenStreetMap contributors, and the GIS User Community.
Figure 1. Playa and desert study domains around the Salton Sea region. Sources: Esri, HERE, Garmin, Intermap, Increment P Corp., GEBCO, the U.S. Geological Survey (USGS), FAO, NPS, NRCAN, GeoBase, IGN, Kadaster NL, Ordnance Survey, Esri Japan, METI, Esri China (Hong Kong), © OpenStreetMap contributors, and the GIS User Community.
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Figure 2. Surface survey campaign locations in the playa and desert domains around the Salton Sea region. Landsat 8 image courtesy of the USGS.
Figure 2. Surface survey campaign locations in the playa and desert domains around the Salton Sea region. Landsat 8 image courtesy of the USGS.
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Figure 3. Playa crust type distribution from September 2019. Landsat 8 image courtesy of the USGS.
Figure 3. Playa crust type distribution from September 2019. Landsat 8 image courtesy of the USGS.
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Figure 4. Playa crust type distribution and geomorphic features around the Bombay Beach area from September 2019. Background image: Pleiades© CNES 2019, Distribution Airbus DS.
Figure 4. Playa crust type distribution and geomorphic features around the Bombay Beach area from September 2019. Background image: Pleiades© CNES 2019, Distribution Airbus DS.
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Figure 5. Sand distribution in the playa domain and related fluvial and aeolian sand sources from September 2019. Landsat 8 image courtesy of the USGS.
Figure 5. Sand distribution in the playa domain and related fluvial and aeolian sand sources from September 2019. Landsat 8 image courtesy of the USGS.
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Figure 6. Annual average wetness between July 2019 and June 2020 within the playa domain. Landsat 8 image courtesy of the USGS.
Figure 6. Annual average wetness between July 2019 and June 2020 within the playa domain. Landsat 8 image courtesy of the USGS.
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Figure 7. Temporal variation of playa percent wet and daily precipitation information from nearby weather stations.
Figure 7. Temporal variation of playa percent wet and daily precipitation information from nearby weather stations.
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Figure 8. Examples of desert surface types: (A) Dry Wash; (B) Sand-Dominated (Alluvial); (C) Sand and Gravel (Alluvial); (D) Sand Dunes; (E) Sand Sheet; (F) Sand with Gravel Lag; (G) Silt-Dominated (Paleolake); (H) Gravel and Sand (Paleolake); (I) Offshore Playa.
Figure 8. Examples of desert surface types: (A) Dry Wash; (B) Sand-Dominated (Alluvial); (C) Sand and Gravel (Alluvial); (D) Sand Dunes; (E) Sand Sheet; (F) Sand with Gravel Lag; (G) Silt-Dominated (Paleolake); (H) Gravel and Sand (Paleolake); (I) Offshore Playa.
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Figure 9. Geomorphic surface mapping results in the desert domain. Landsat 8 image courtesy of the USGS.
Figure 9. Geomorphic surface mapping results in the desert domain. Landsat 8 image courtesy of the USGS.
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Figure 10. Desert surface type (top panel) comparison with previous mapping results by California Geological Survey (2014) at (bottom panel). Landsat 8 image courtesy of the USGS.
Figure 10. Desert surface type (top panel) comparison with previous mapping results by California Geological Survey (2014) at (bottom panel). Landsat 8 image courtesy of the USGS.
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Table
Table 1. Features used in OBIA process and as predictors in machine learning base classification.
Table 1. Features used in OBIA process and as predictors in machine learning base classification.
DescriptionCalculationReferences
Spectral Characteristics
Blue BandBlue
Green BandGreen
Red BandRed
NIR BandNIR
Blue Ratio to Visible BandsBlue/(Blue + Green + Red)
Green Ratio to Visible BandsGreen/(Blue + Green + Red)
Red Ratio to Visible BandsRed/(Blue + Green + Red + NIR)
NIR Ratio to All Bands NIR/(Blue + Green + Red + NIR)
Sum of Visible BandsBlue + Green + Red
Sum of All BandsBlue + Green + Red + NIR
Biological Crust Index(1 – 2 × |Green − Red|)/((Green + Red + NIR)/3)[64]
Crust Index1 − (Red − Blue)/(Red + Blue)[65]
Zabud Index((Blue − Green)2 + (Green − Red)2 + (Red − NIR)2)0.5[66]
NDVI (Normalized Difference Vegetation Index)(NIR − Red)/(NIR + Red)
GDVI (Green Difference Vegetation Index) (NIR − Green)/(NIR + Green)
Textural Feature
Average Value of GLCM [67]
Standard Deviation of GLCM
GLCM Angular Second Moment
GLCM Contrast
GLCM Correlation
GLCM Dissimilarity
GLCM Entropy
GLCM Homogeneity
Table
Table 2. Parameters used as predictors in desert geomorphic surface mapping.
Table 2. Parameters used as predictors in desert geomorphic surface mapping.
Spectral CharacteristicsTypeSpatial Resolution
BlueSurface reflectance1 m
Green
Red
Intensity
Hue
Saturation
Terrain Attributes
Elevation Topography5 m
Aspect
Profile Curvature
Slope
Diurnal Anisotropic HeatingMorphometry
Effective Air Flow Height
Terrain Ruggedness Index
Terrain Surface Texture
Topographic Position Index
Vector Ruggedness Measure
Wind Effect (Winward and Leeward Index)
Diffuse Insolation (Annual, Spring Equinox, Winter Solstice)Lighting and Visibility
Direct Insolation (Annual, Spring Equinox, Winter Solstice)
Sky View Factor
Visible Sky
Topographic Wetness IndexHydrology
Interferometric Synthetic Aperture Radar Measurements
Ortho-Rectified Radar Image (ORI) 1 m
Table
Table 3. Description of crust types for playa surface mapping. The white frame in the pictures is 1 m by 1 m.
Table 3. Description of crust types for playa surface mapping. The white frame in the pictures is 1 m by 1 m.
Crust TypeDescriptionPicture
No CrustThis crust type is present (1) when playa has been recently exposed and a salt crust has not had time to form, or (2) when sand has intruded onto the playa, or (3) when the surface has been pulverized and replaced by loose material. Remotesensing 14 00616 i001
SmoothThis is the first crust type to form when playa is exposed and minimal crust development has occurred. It has a low relief and can sometimes be accompanied by mud cracks or pedestal development. Remotesensing 14 00616 i002
Weak BotryoidalThis crust is similar to botryoidal, but it looks either less developed or more abraded than botryoidal. The smaller second order of mounds that forms on the top has not been formed yet or has been abraded. This crust type is found in areas that have been allowed to experience some intermediate amount of crust development. Remotesensing 14 00616 i003
BotryoidalThis crust has a mottled, rounded texture resembling a bunch of grapes and typically includes multiple orders of small adjacent mounds. It is often found farther away from the Sea, where the crust has had time to develop and desiccate away from disturbance. Remotesensing 14 00616 i004
Barnacle BedsBarnacle beds are long linear beach ridge features. This biogenic surface type is composed of dead barnacle shells (~1 cm long). These deposits are formed by wave action. Other playa crust types accrete against (typically upslope) barnacle beds. Barnacle beds are often reworked by fluvial events and/or are integrated into developing salt crust. These surfaces must have >30% barnacles present on their surface to be considered barnacle beds. Remotesensing 14 00616 i005
Table
Table 4. Confusion matrix for crust type classification for October 2018. Total sample size: training data = 2420; validation data = 171.
Table 4. Confusion matrix for crust type classification for October 2018. Total sample size: training data = 2420; validation data = 171.
Training Data; Overall Accuracy = 98.7%Validation Data; Overall Accuracy = 97.7%
Producer’s AccuracyUser’s AccuracyProducer’s AccuracyUser’s Accuracy
Barnacle Bed99.2%99.6%100.0%96.8%
Botryoidal98.9%98.9%95.2%95.2%
No Crust99.5%98.2%100.0%100.0%
Smooth97.8%98.6%100.0%97.4%
Weak Botryoidal98.2%98.0%93.8%97.8%
Table
Table 5. Confusion matrix for crust type classification for September 2019. Total sample size: training data = 4869; validation data = 659.
Table 5. Confusion matrix for crust type classification for September 2019. Total sample size: training data = 4869; validation data = 659.
Training Data; Overall Accuracy = 99.4%Validation Data; Overall Accuracy = 91.7%
Producer’s AccuracyUser’s AccuracyProducer’s AccuracyUser’s Accuracy
Barnacle Bed99.9%100.0%96.1%89.2%
Botryoidal99.9%98.8%100.0%87.0%
No Crust100.0%98.9%96.6%84.8%
Smooth100.0%99.7%89.8%94.4%
Weak Botryoidal97.5%99.9%90.3%92.1%
Table
Table 6. Confusion matrix for playa sand presence for October 2018. Total sample size: training data = 1328; validation data = 249.
Table 6. Confusion matrix for playa sand presence for October 2018. Total sample size: training data = 1328; validation data = 249.
Training Data; Overall Accuracy = 96.2%Validation Data; Overall Accuracy = 96.8%
Producer’s AccuracyUser’s AccuracyProducer’s AccuracyUser’s Accuracy
No Sand97.3%95.2%97.9%93.9%
Sand95.2%97.3%96.1%98.7%
Table
Table 7. Confusion matrix for playa sand presence for September 2019. Total sample size: training data = 3132; validation data = 692.
Table 7. Confusion matrix for playa sand presence for September 2019. Total sample size: training data = 3132; validation data = 692.
Training Data; Overall Accuracy = 99.7%Validation Data; Overall Accuracy = 96.2%
Producer’s AccuracyUser’s AccuracyProducer’s AccuracyUser’s Accuracy
No Sand100.0%99.4%95.7%98.7%
Sand99.4%100.0%97.4%91.8%
Table
Table 8. Classes and subclasses for desert geomorphic surface characterization.
Table 8. Classes and subclasses for desert geomorphic surface characterization.
ClassSubclassDescriptionEmissive Surface Type
1—Dry Wash UnitsDry WashEphemeral drainage dominated by fine- to coarse-grained sand. Undisturbed silt found in dry washes is often present as a friable, thin, mud-cracked sheet.Yes
2—Alluvial Fan UnitsSand-DominatedAlluvial sand typically located near the distal portion of the fan.Yes
Sand and GravelAlluvial sand capped by gravel lag. Typically located near the middle of the fan.Yes
CobblesAlluvial fan deposits consisting of sand, gravel, and cobbles. Typically located near the top of the fan.No
3—Sand UnitsSand DunesActive eolian dune and erosional interdune surface. Large asymmetrical, barchan, and linear dunes are the most common in this region. Dunes are >1.5 M and typically fine- to medium-grained.Yes
Sand SheetActive eolian deposit. Flat to low angle, uniform, expansive sand surface. Typically fine- to medium-grained. Coppice dunes <1.5 m in height.Yes
Sand with Gravel LagSand sheets superimposed by a fine gravel lag.Yes
4—Paleo LakebedSilt-DominatedLacustrine silt deposits, typically from pre-historic Lake Cahuilla.Yes
Cobble over SiltLarge cobbles regularly distributed among silt situated along the margin of pre-historic Lake Cahuilla. The cobbles serve as armory for the vulnerable underlying silt.No
Gravel and SandA mixture of gravel and sand present on old beach ridges formed by wave action.Yes
5—Rock UnitsSandstoneHighly friable, heavily eroded sandstone. Often taking the form of steep gulleys.No
BedrockUndifferentiated bedrock. A consolidated hard surface that is not emissive.No
6—Offshore Playa UnitOffshore PlayaIndependent depressions that once held water have now formed delicate mud-cracked silt (e.g., Clark Dry Lake).Yes
Table
Table 9. Confusion matrix for geomorphic surface classification. Total sample size: training data = 102,725; validation data = 11,107.
Table 9. Confusion matrix for geomorphic surface classification. Total sample size: training data = 102,725; validation data = 11,107.
Training Data
Overall Accuracy = 98.5%		Validation Data
Overall Accuracy = 93.5%
Producer’s AccuracyUser’s AccuracyProducer’s AccuracyUser’s Accuracy
Dry Wash96.1%98.6%95.6%94.9%
Gravel and Sand (Paleolake)99.9%98.7%95.7%97.8%
Sandstone100.0%98.1%96.6%90.4%
Bedrock99.7%99.7%94.1%97.6%
Offshore Playa100.0%100.0%100.0%100.0%
Sand-Dominated (Alluvial)99.7%97.5%97.5%92.3%
Sand and Gravel (Alluvial)97.3%99.1%93.3%91.0%
Cobbles (Alluvial)100.0%99.0%99.2%92.6%
Sand Dunes99.7%96.7%95.6%93.9%
Sand Sheet92.0%98.4%91.3%93.0%
Sand with Gravel Lag99.6%96.2%92.4%81.3%
Silt-Dominated (Paleolake)97.5%98.6%90.8%92.1%
Cobble over Silt (Paleolake)99.8%100.0%100.0%89.5%
Table
Table 10. Spatial extents of geomorphic surface type subclasses in the desert study domain.
Table 10. Spatial extents of geomorphic surface type subclasses in the desert study domain.
ClassKm2Area (%)SubclassKm2Area (%)
Rock1559.1838Sandstone124.073
Bedrock1434.4935
Sand863.4720Sand Dunes1.14<1
Sand Sheet804.8919
Sand with Gravel Lag57.441
Alluvial Fan999.5524Sand-Dominated (Alluvial)16.83<1
Sand and Gravel (Alluvial)950.4123
Cobbles (Alluvial)32.31<1
Dry Wash283.617Dry Wash283.617
Paleolake405.4410Silt-Dominated (Paleolake)367.569
Cobble over Silt (Paleolake)0.79<1
Gravel and Sand (Paleolake)37.09<1
Other39.601Offshore Playa12.67<1
Developed26.93<1
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Cheng, Y.-B.; Dickey, H.; Yimam, Y.T.; Schmid, B.; Paxton, B.; Schreuder, M.; Tran, R. Land Surface Parameterization at Exposed Playa and Desert Region to Support Dust Emissions Estimates in Southern California, United States. Remote Sens. 2022, 14, 616. https://doi.org/10.3390/rs14030616

AMA Style

Cheng Y-B, Dickey H, Yimam YT, Schmid B, Paxton B, Schreuder M, Tran R. Land Surface Parameterization at Exposed Playa and Desert Region to Support Dust Emissions Estimates in Southern California, United States. Remote Sensing. 2022; 14(3):616. https://doi.org/10.3390/rs14030616

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Cheng, Yen-Ben, Hank Dickey, Yohannes T. Yimam, Brian Schmid, Bronwyn Paxton, Maarten Schreuder, and Reed Tran. 2022. "Land Surface Parameterization at Exposed Playa and Desert Region to Support Dust Emissions Estimates in Southern California, United States" Remote Sensing 14, no. 3: 616. https://doi.org/10.3390/rs14030616

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