Application of remote sensing and GIS techniques for exploring potential areas of hydrothermal mineralization in the central Eastern Desert of Egypt

The integration of remotely sensed data allowed the successful characterization of the hydrothermal alteration zones of the Abu–Gaharish area in the Central Eastern Desert of Egypt using image transformation techniques. The integration of several evidential maps highlighted the plausible areas with high concentrations of argillic and phyllic, key hydrothermal minerals that reflect the intensity of hydrothermal effects and the probable sites of ore bodies. The excellent prospective zone identified in the map occupies around 1.39% of the study area. Kaolinite–smectite minerals with correlation scores of around 0.97 were consistent with areas of hydrothermal alteration and mining activities; however, propylitic minerals were confined to basic metavolcanics and serpentinites. The resulting predictive map was assessed using existing mining data with significant consistency; therefore, ﬁeld veriﬁcation is essential. The overall results showed that remotely sensed data represent a valuable mapping tool for geological and mineral resources reconnaissance in the arid regions


Introduction
Satellite remote sensing provides valuable spatial and temporal information on the Earth's resources. Since NASA's first Landsat satellite was launched in 1972, key advances have been made in the field of geological reconnaissance. Mineral resources originating from hydrothermal activity have been identified using remotely-sensed data. The variable spatial, radiometric, and spectral resolution of modern remote sensing data presents opportunities for targeting potential areas for new mineral prospects [1][2][3][4][5][6][7][8][9]. Hydrothermal activity occurring through fracture/fault zones modifies the physical and chemical properties of the country rock [10]. The characterization of hydrothermal alteration zones (HAZs) and their grade is important for identifying potential areas of mineral resources [1,[11][12][13], as the metals have a tendency to occur in the most highly altered rocks [10].
In the last two decades, ASTER data have been successfully used to identify HAZs for mineral resources prospecting [1,3,8,20,21,[27][28][29][30][31][32]. As ASTER was the first multispectral spaceborne sensor capable of identifying OH-bearing minerals using its 14 spectral bands, particularly those minerals within the SWIR region [8,9,25], the characterization of key hydrothermally altered mineral assemblages and the definition of the geometry of the HAZs using ASTER data was found to be effective for identifying potential areas of mineral resources [8,31,33]. SWIR data has allowed the identification of specific categories of hydrothermal minerals, such as phyllosilicates, clays, carbonates, and sulfates, depending on their spectral signatures [9].
Geographic Information System (GIS) tools have been used to produce integrative maps through digital overlay methods [8,38,39]. Knowledge-driven approaches integrating multicriteria decision-making depending on expert judgement have also been used to produce predictive maps [40][41][42]. Such approaches employs ranked binary evidential maps. Several evidential maps can therefore be combined to obtain prospective maps [41].
In this study, we tested the application of these data and remote sensing approaches for the identification of HAZs in the study area of the Central Eastern Desert (CED), which is characterized by a dry environmental setting and a lack of vegetation. As no remote sensing exploration information is available regarding the Abu-Gaharish Au-Cu-W prospect, the analysis of ASTER data was necessary to enable the future mapping of the spatial distribution of HAZs in the area, as well as the identification of the key hydrothermal minerals indicating the nature of the mineral resources prospects.

Geological setting of the study area
The Abu-Gaharish area belongs to the Arabian-Nubian Shield (ANS), which covers approximately 53 km 2 from northeast Africa to Arabia, between the latitudes 26°21 16.45 and 26°25 19.53 N, and longitudes 33°3 6 25.94 and 33°40 50.43 E (Figure 1). The study area is located south of the boundary between the North Eastern Desert (NED) and the Central Eastern Desert (CED) of Egypt (Figure 1a). This belt is composed of Neoproterozoic island-arc volcanic and volcanosedimentary rocks, which are part of an ophiolitic complex that was intruded by granitoids.
The geological map of Conoco [43] shows that the study area comprises mainly calc-alkaline granitoids, named "Older Granites (750-610 Ma; [44,45])" and "Younger Granites" (610-550 Ma; [45][46][47]). The "Younger" or "Pink Granites" intruded the ophiolitic rocks, the volcano-sedimentary rocks, as well as acidic to intermediate metavolcanics and their associated pyroclastics. The Abu-Gaharish granitic rocks occupy the majority of the study area and display both NE-SW and NW-SE trends. Based on geochemical and petrographic examination carried out by Aton [48], the granite pluton represents a late post-orogenic highly evolved phase of magmatic stage that is rich in Nb, W, Ta, Snand U. The pluton is crosscut by rhyolitic and aplitic dikes along with quartz veins trending NE-SW.
Mining activity has taken place during the New Kingdom 16th century BC and the 11th century BC in the study area and mining boreholes exist in various parts [49]. At present, Aton Company discovered new Au (±W-Cu) mineralization at north Abu Abu-Gaharish [50]. These new zones in the north extend along the eastern contact of the Gaharish granite over a strike length > 5 km in length. Such surface mineralized zone contains visible gold associated with quartz veins [50] which affected by structural discontinuities, including shearing. The gold mineralization zones at Abu Gaharish are strongly structurally controlled. Noteworthy, the mineralization in the northern part that comprise plausible amount of auriferous W-Bi-Cu bearing quartz veins is consistent to areas of extensively phyllic to argillic alteration zones that most likely consist of felsic volcanics in contact with the Abu-Gaharish granite and extends along the granitic contact (NNE-SSW, NE-SW). The contact between the granite pluton of Abu-Gaharish and metavolcanic rocks to east also contain Au (±W-Bi) mineralization and the granite pluton itself as well through sheeted veins of quartz. The mineralization zone that extends NE through metavolcanics is rich in W (wolframite and scheelite); however, many areas at north and west of the main mineralization zone are rich in gold.
The southern area hosts two prospects, including the main zone. In the last few decades, tungsten ores such as scheelite and wolframite have been exploited in Abu-Gaharish quartz veins. The areas of mineralization are also located close to the contact zone between the coarse-grained pink granite stocks and the Hammamat wall rock [49]. Noteworthy, the Hammamat clastics (610-585 Ma; [51]) comprise siltstones, greywacke and siltstones and conglomerates greywacke that were affected by contact metamorphism. Noteworthy, the wadi sediments cover wide parts of the pluton, so the granites appear like granitic "islands". The Aton [1] report revealed mineralization in this granite and below the wadi sediments using Ground Penetration Radar (GPR) geophysical survey.
ASTER data was collected on-board the TERRA spacecraft in December 1999 by NASA and METI (the Ministry of Economic Trade and Industry of Japan). The spectral channels of ASTER were acquired from the NASA Land Processes Distributed Active Archive Center (LP DAAC). Three categories of spectral information were collected, including three VNIR bands, six SWIR bands and four TIR bands. The SWIR bands were transformed into valuable information using ENVI v.5.4. The ASTER SWIR spectral bands that recorded electromagnetic radiation between the wavelengths of ∼ 1.60 and 2.45 µm were used to discriminate between the absorption signatures of different groups of hydrothermal minerals, including Fe/Mg-OH, Al-OH, and CO 3 [26].
One scene from the ASTER cloud-free level (in HDF file format, 1B bands acquired on 7 October 2007) was analysed in the area of interest. This level of processed radiance recorded at the sensor (in Wm −2 ·sr −1 ·µm −1 ) is derived from level 1A by correcting the geometric distortion and applying the radiometric coefficient. The pre-processing step included cross-talk improvements and orthorectification of bands. The data was georegistered to zone 36 of the Universal Transverse Mercator (UTM) World Geodetic System 1984 (WGS84) using ENVI software. In order to standardize and minimize the disturbances due to the atmosphere, altitude, sensors and sun radiance, a log-residual algorithm was applied to the SWIR bands [20,52]. This allowed the composition of the target rock units to be identified from the data, by matching the defined endmembers to known signatures from the spectral library of the United States Geological Survey (USGS). This procedure was followed to define the hydrothermal alteration minerals in the study area using SWIR data for mineral characterization [8,20,31,53].
False colour combination methods, PCA, band ratios, and spectral analysis were used to delineate the zones of hydrothermal alteration using ENVI 5. The PCA approach is a statistical method used to transform a number of related spectral bands into a smaller number of uncorrelated spectral channels. This approach has frequently been applied for detecting HAZs [1,18,32] and was employed to identify which PC image could be used to predict the occurrence of specific minerals, on the basis of loading eigenvectors of the particular spectral channels. Mineral indices such as the OH-bearing altered minerals Index (OHI), and the Kaolinite Index (KAI), [2,16] were extracted using the ASTER Level-1B radiance from the sensor data, as follows: OHI = The identification of minerals was performed by subpixel spectral mapping to distinguish mixed pixels from rejected pixels. Through this approach, the minerals present were defined from the map on the basis of the spectral signature of the end-member, by matching with the signatures of reference minerals in the spectral library [18,20]. The Minimum Noise Fraction (MNF) transformation [54] was applied to obtain a pixel purity index in order to extract the highest number of spectrally pure pixels from the input MNF data. These results were used to define end-members using multidimensional visualization for spectral classification, to guide the mineral characterization.
The Shuttle Radar Topography Mission (SRTM) consisted of an interferometric radar system that flew onboard the space shuttle Endeavour during an 11day mission in February 2000 ( [55,56]). The recording wavelength was around 5.6 cm. The mission produced a high-quality global digital elevation model (DEM) at a resolution of 1 arc second ( ∼ 30 m). This DEM was used in this study to visualize the topography of the terrain and extract the lineaments cutting through the area. A hillshaded relief image derived from the SRTM was extracted using Arc GIS v.10.5 software to highlight the lineaments of interest. A sun azimuth of 315°and an altitude angle of 30°were applied to the DEM to visualize the terrain.
The processed data were georeferenced to zone 36 of the Universal Transverse Mercator (UTM) World Geodetic system 1984 (WGS 84) and saved, visualized and combined using ArcGIS v.10.5.

Remote sensing
Using Kufman Landsat-8 OLI band ratios 7/5, 5/4, 6/7 in R, G, and B, respectively, the granitoids rocks were revealed in cyan; the metavolcanics (MV) in reddishorange; the basic metavolcanics, serpentinites (Sp), and metasediments (MS) in blue; and the areas of hydrothermal alteration in light cyan (Figure 2a). The intrusive basic rocks to the south and north of the granitoid pluton were most likely depicted in blue colour with rounded boundaries. Band ratio 6/7 highlighted the OH-bearing minerals, such as kaolinite-smectite, micas and amphiboles [36], whereas band ratios 7/5 and 5/4 revealed the iron-rich lithologies. These band ratios allowed the distinction between the granitoids and the surrounding rocks (Figure 2a).
Data processing and interpretation of the SRTM DEM revealed topographic features that range from ∼ 400 to 900 m above sea level in the study area (Figure 2b). The maximum elevations are associated with metavolcanics, serpentinites, and metasediments (MS) as well as the northwestern part of the granitic pluton, the southern part of the metavolcanics/serpentinites (Sp), and the metasediments that surround the Abu-Gaharish granites. The results of the hillshade analysis improved the visualization of boundaries and emphasized the topographic characteristics of the lineaments in the area (Figure 2c). These lineaments mainly trend NE-SW and comprise fractures/fault zones and dikes of felsic and mafic composition. The lineament density map shows that the lineaments predominantly occur within the Abu-Gaharish granites compared to the surrounding rock units (Figure 2d).
Particular band ratios of ASTER data were used to characterize the lithologies, HAZs and mineral composition of the rocks in the study area. Applying the KAI [2], MNF3 and band ratios 7/6 revealed areas of hydrothermal alteration in white tones that dominates the central part of the image, the northwest corner, and the gold mining area (Figure 3a). The pink colour indicated the granitoids and the dark blue colour indicated the basic metavolcanics. Band ratio 7/6 was used to identify zones enriched in white mica (sericite). The results of this combination of band ratios were subdivided into six classes based on the grade of the hydrothermal alteration (Figure 3b), with six representing a high grade and one representing low grade alteration. The resulting map shows areas of potential hydrothermal alteration in red (Figure 3b).
The combination of band ratios MNF3, 4/6 and 7/6 in R, G, and B, respectively, highlighted the contrast between hydrothermally altered and unaltered rocks (Figure 3c). The highest values of band ratios 4/6 and 7/6 indicated phyllic zones [26], with high grade hydrothermal alteration shown in white. These areas are located in the northeast and northwest corners of the study area as well as in the south. Band ratio 7/6 was used to identify zones enriched in white mica. The results of this analysis were classified into six grades of hydrothermal alteration (Figure 3d).
In order to discriminate between potential areas of argillic and phyllic alteration, band ratio 5 + 7/6, OHI and KAI were combined in R, G and B. This allowed areas enriched in aluminum hydroxide (Al-OH) minerals to be identified, via band ratio 5 + 7/6, as shown in white in Figure 3(e). The categorization of these combined values showed that the areas of higher hydrothermal alteration are consistent with structural features associated with granitic rocks (Figure 3f).
The combination of band ratios 4/5, 4/7, and 4/6 in R, G, and B, allowed the identification HAZs as well as the discrimination of granites, metavolcanics, and serpentinites (in pink, green, and cyan, respectively, Figure 3g). Band ratios 4/5 and 4/7 clearly improved the recognition of argillic and phyllic alteration, respectively [9]. The categorization of these combined values into six grades of alteration is shown in Figure 3(h). The results of this combination are very similar to the composite of KAI, MNF3 and 7/6 ( Figure 3a). Bands 4, 5, and 6 were selected for principal component analysis for argillic alteration mapping. The  obtained eigenvector values of the selected band transformation process are shown in Table 1. The analysis of eigenvector loadings showed that PC2 reflects a positive loading of band 4 (0.329) and a negative loading of bands 5 (−0.630628) and 6 (−0.702617). This observation is consistent with the existence of kaolinite and alunite, which are the dominant argillic alteration minerals that usually display negative signatures in ASTER bands 5 and 6. Bands 5, 6, and 7 were used to characterize phyllic alteration zones through PCA, and the eigenvector loadings are listed in Table 1. The eigenvector loadings for band 6 are positive (0.653785), whereas the loadings for band 5 are negative (−0.7502) and band 7 has a very small positive loading close to zero (0.098815). This analysis shows that the phyllic zone, consisting of illite/muscovite (sericite), is marked by a significant negative Al-OH signature in ASTER band 6. Phyllic alteration zones are therefore displayed in the darkest pixels. These pixels can be inverted to be bright by multiplying by −1.
The contrast between metasediments and metavolcanics was highlighted by the combination of the negated PC3 of bands 5, 6, and 7, PC2 of bands 4, 5, and 6, and band 4 of the ASTER data ( Figure 3i). Several zones of mixed argillic and phyllic alteration were observed in the southeastern and northwestern parts of the study area, which could represent potential prospective zones. The categorization of these combined values into six grades of hydrothermal alteration is shown in Figure 3(j).
The band operation (4 × 7)/(8 × 8) was used to emphasize areas with both argillic and phyllic alteration [9] whereas operation (4 + 6)/5 highlighted argillic areas rich in kaolinite [57]. Operation (5 + 7)/6 was used as an indicator for phyllic alteration. The combination of (5 + 7)/6, (4 × 7)/(8 × 8) and (4 + 6)/5 in R, G and B allowed the granites to be identified and shown in blue, the serpentinites and metasediments in green and the metavolcanics in magenta (Figure 3k). The granites are cut by mafic dikes shown in green. In addition to discriminating between the different lithologies in the study area, this combination also highlighted areas of hydrothermal alteration, shown in white in Figures 3(k  and l).

Prospective mapping using GIS
In the present study several datasets were combined using GIS smart tools for exploring potential areas of mineral resources. In the last few decades, remote sensing techniques have provided digital data/images that have helped progress data integration and fusion approaches [39,41]. In this study, we combined the evidential maps using a multiclass overlay method known as the knowledge-driven multi-criteria technique, which has been used in many reconnaissance studies [8,58]. In this overlay method, each target map was given a weight matching the probably grade of hydrothermal alteration and each single thematic map was sorted into zones based on the grade of hydrothermal alteration. A numeric rank ranging from 1 to 6 was given to each zone (Figure 3), where 6 is the highest plausible grade of hydrothermal alteration, and 1 is the lowest or indicates an absence of alteration [58]. The combination process takes into account the fact that each evidential map is a binary map containing prospective and non-prospective pixels. The meeting of many prospective vectors in any region of the map therefore increases the effective grade in that zone. The higher the values, the higher the prospect of finding mineral resources associated with hydrothermal activity.
The band ratios, Minimum Noise Fraction image and mineral indices that highlighted the HAZs (Figure 3a-l) were therefore integrated for the purpose of prospective mapping. Each composite map was sub-divided into six zones ranging from very low grade or absent alteration (1) to very high grade alteration (6). The maps were then merged to define the areas of optimum potential hydrothermal grade. The results of this process are mineral predictive maps showing the potential areas of mineral resources (Figure 4a).
The resulting prospective map of hydrothermal alteration (Figure 5a) subdivides the study area into seven prospective zones using the Natural Breaks Classification method in ArcGIS software packages that initiated to optimize collection of a set of values into classes of similar characteristics called "natural classes". These zones including excellent, very good, good, moderate, low, very low and bare/absent prospects that covering about 1. 39, 5.81, 16.31, 26, 25, 20.95, and 4.46% of the study area. Moreover, the potentiality values of the aforementioned classes are ranging from 15-18, 13-15, 11-13, 9-11, 7-9, 4-7, and 3-4, respectively. In the southern and central parts of the prospective map, the zone of high grade hydrothermal alteration is consistent with the Abu-Gaharish mining area, where many mining and borehole drilling activities were conducted by Aton [48,50]. The alteration in the central area (Figure 5a) occurs along fracture/fault zones within the granite pluton that require further field investigations. Moreover, in the northwestern corner of the   Figures 5(b and c); (b) Prospective area around the Abu-Gaharish mine overlain by yellow points representing the presence of the kaolinite-smectite mineral group; (c) Subset of the potential hydrothermal alteration map showing red pixels that indicate a high grade hydrothermal alteration, which is consistent with the green points derived from the scatter plot in panel g, indicating Al-OH minerals; (d, e) Obtained pixel spectra for blue and magenta points, and reference spectral curves from the USGS mineral spectral library that match brucite and talc, respectively; (f) Obtained pixel spectrum from the yellow points, and the corresponding reference spectral curve from the USGS mineral spectral library that matches kaolinite-smectite; (g) Binary scatter plot showing band ratios (5 + 7)/6 vs. 5/7 [59].
predictive map, a potentially high-grade area elongated in a NE-SW direction requires further field investigations.
The prospective map showing the target areas for hydrothermal alteration identified using GIS techniques is shown in Figure 5(a). These areas potentially host Al-OH minerals. A binary scatter plot showing band ratios (5 + 7)/6 (a proxy for the Al-OH content) vs. 5/7 (a proxy for Mg-OH content) [59] helped to identify the potential zones of Al-OH alteration as those that occupied the uppermost right-hand section of the binary plot, whereas the lowermost left-hand section highlighted the areas lacking Al-OH minerals (Figure 5g). This plot showed that the area corresponding to high grade prospects (Figure 5c) is consistent with pixels that indicate enrichment in Al-OH [59]. The green points that have a higher Al-OH content are those that are consistent with the area of potential hydrothermal alteration (Figure 5c). However, green points corresponding to areas with a lack of Al _ OH content in the right-hand section of Figure 5(c) consist of basic metavolcanics, as indicated by higher Mg-OH contents. The green points extracted from plotting band ratios 5 + 7/6 vs. 5/7 are consistent to the red pixels that reveal the higher Al-OH content Figure 5(c).
The key hydrothermal alteration minerals distributed in the study area were identified by obtaining endmembers by applying wizard sub-pixel classification of SWIR ASTER data bands. These end-members were correlated with records from the USGS mineral spectral library, using the Spectral Angle Mapper (SAM), Spectral Feature Fitting (SFF), and Binary Encoding (BE) methods, and results are shown in Figure 5(d-f). The obtained key hydrothermal end-member maps were overlain on the prospective map in order to verify the location of prospective minerals (Figure 5a-c).
To identify the key hydrothermal minerals, the obtained spectral curves were correlated with records from the USGS spectral library, with the highest correlation score representing the most likely probability. Through this process, we identified the spectra of three important minerals resulting from propylitic and argillic alteration. The first displays an absorption feature close to a wavelength of 2.335 µm, which most likely correlates with minerals bearing Mg-OH, such as chlorite and talc. The most probable candidate was found to be talc, with a correlation score of 0.944. The zone hosting this mineral lies within the basic metavolcanics and other related rocks in the southeastern part of the prospective map. The occurrences of this mineral are indicated with magenta dots in Figure 5(a). The second mineral endmember displays an intense absorption feature close to a wavelength of 2.335 µm and was found in an area comprising basic metavolcanics and serpentinites. This mineral is likely to be antigorite or brucite, with a correlation score of 0.849.
The third mineral endmember corresponds to areas of high grade hydrothermal alteration in the mining areas and at the northwestern corner of the map (Figure 5a-c). This mineral displays a significant absorption feature close to a wavelength of 2.209 µm, which corresponds to the known spectrum of kaolinite-smectite, with a correlation score of 0.961. Zones featuring these minerals likely reflect areas of argillic alteration (Figure 5b, f) as absorption features close to 2.205 µm are characteristic of kaolinite, montmorillonite, illite and sericite [20,32].

Discussion
The results of this study yielded a discrimination map illustrating the occurrence of granitoid rocks that are shown in greenish cyan, metasediments shown in reddish-orange, basic metavolcanics, metasediments and serpentinites shown in blue, and areas of hydro thermal alteration shown in light cyan. Band ratio 6/7 was effective in highlighting OH-bearing minerals, such as kaolinite-smectite, micas and amphiboles [36]. In addition, band ratios 7/5 and 5/4 revealed the Fe-rich rock units in the study area, such as the basic metavolcanics that are shown in red.
The deposition of minerals in hydrothermal systems can result from diverse processes that cause changes in the physical and chemical characteristics of hydrothermal fluids and minimize metal solubility [39]. Our analysis and interpretation of Landsat-OLI and ASTER data revealed HAZs along fracture/fault zones as well as along the eastern contact between the granite and the metavolcanics. The alteration products consist dominantly of argillic and propylitic zones. The hydrothermally altered minerals show a high reflectance in band 4 and a significant negative signature in band 6 of the ASTER data. The grade of hydrothermal alteration can be used as a guide for targeting the mineralization zones [32]. In the area of the interest, the argillic zone was previously the target of mining activities.
The ASTER data provided a reasonably data-rich basis for locating potential areas of hydrothermal alteration, through image transformation techniques. GIS approaches also yielded a very good consistency between prospective zones and mineralized zones. Using the combined kaolinite index ([band 4/band 5] × [band 8/band 6]), MNF3 and band ratio 7/6, hydrothermal alteration zones were highlighted in white tones (Figure 3a), whilst granitoids were displayed in pink. The kaolinite index [2,16] was used in this composite image to highlight areas that have prospective amounts of kaolinite and as an indication of argillic alteration zones. This combination successfully defined the prospective areas comprising high grade hydrothermal alteration and displayed these zones in white tones.
The combination of MNF3 and band ratios 4/6 and 7/6 in R, G and B also helped to identify potential areas of hydrothermal alteration. This combination provided better results for locating alteration zones characterized by Al-OH minerals (Figure 3c, d). Band ratio 4/6 produced reliable results in terms of locating occurrences of argillic minerals such as kaolinite, which is characterized by a spectrum with two significant absorption features, in band 5 and (especially) in band 6 [5,60]. Band ratio 4/6 also allowed the identification of occurrences of white mica, which displays a prominent reflectance in band 4 and significant absorption in band 6 ( Figure 3c, g), allowing areas of argillic and phyllic alteration to be highlighted [5]. In addition, band ratio 7/6 ( Figure 3a, c, e) revealed the occurrence of a white mica (sericite) alteration that can be recognized through the prominent absorption feature in band 6 [61].
The combination of the band ratio 5 + 7/6 with OHI and KAI in R, G and B also provided good results for identifying aluminum hydroxide-bearing minerals in the central part of the transformed image (Figure 3e, f), which appear as bright pixels. As phyllic minerals show a strong Al-OH absorption at a wavelength of around 2.20 µm (ASTER band 6), and bands 5 and 7 are found at the absorption flanks of band 6, the absorption Relative Band Depth (RBD) was computed as (5 + 7)/6 [59,62]. The use of the RBD in this combination allowed HAZs to be identified [28,34] as this band ratio revealed the occurrence of Al-OH minerals (Figure 3e, f), such as Al-smectite, muscovite, sericite, and illite [59,62,63]. The use of the mineral indices of Ninomiya [2,16] in this combination maximized the extracted information.
The argillic minerals were identified through the presence of a double absorption feature close to bands 5 (2.16 µm) and 6 (2.20 µm), whereas the Fe-OH minerals such as jarosite and/or Fe-sericite were identified in band 7. In addition, phyllic zones rich in illite-sericite yielded a single prominent negative signature at a wavelength of 2.205 µm (band 6) [5]. The combination of band ratios 4/5, 4/7, and 4/6 in R, G, and B therefore revealed the location of hydrothermal alteration zone in white tones (Figure 3g, h). Using this combination, the granitoids appear in pink and the metavolcanics, metasediments and serpentines are shown in green.
Gathering this remotely-sensed information ( Figure  4) regarding the hydrothermal alteration in the study area using GIS techniques, locations for the occurrence of HAZs were provided (Figure 5a). This information therefore revealed the locations of prospective areas for mineral resources derived from hydrothermal activity, as the economic aggregates of metals such as Au, W, and Cu in the Abu-Gaharish area are most likely related to zones of intense hydrothermal alteration (Figures 5a, Figure 6). This is because HAZs are a potential location for the occurrence of base and precious metal deposits [10]. These zones are located in the central part of the study area, as well as near the southern contact between the granites and the metasediments and to the northwest of the Abu-Gaharish granites (Figure 5a).
Although the use of combinations of band ratios, mineral indices and RBD successfully characterized the nature and location of the HAZs, certain key minerals were challenging to identify. Spectral analysis curves were therefore used to identify specific minerals [18,20,31]. These revealed three types of hydrothermal alteration minerals, including kaolinite-smectite, talc and brucite, which belong to argillic and propylitic zones. Propylitic zones are characterized by the presence of Mg-OH and CO 3 mineral species, and host chlorite, epidote and calcite with absorption signatures matching ASTER band 8 [9,26,30,32,64]. Talc and brucite were also identified within the basic metavolcanics and serpentinites that surround the granites (Figure 5a, d, e). In addition, the identification of the kaolinite-smectite group of minerals, which contain Al-OH, indicated the potential areas for prospective mineral resources related to hydrothermal alteration. Brucite is a magnesium hydroxide that is commonly associated with serpentinites. A binary plot of band ratios (5 + 7)/6 (indicating minerals bearing Al-OH) vs. 5/7 (indicating Mg-OH and carbonate minerals such as chlorite, epidote, and amphiboles; [59]) was effective in discriminating between the areas hosting and lacking Al-OH minerals. Pixels located on the right side of this binary plot were consistent with areas of potential hydrothermal alteration (Figure 5c, g), hosting minerals of the kaolinite-smectite group, and therefore correspond to potential ore bodies.
The recent field investigation of the Gaharish area conducted by Aton [50] revealed the presence of quartz veins bearing Au and W-Bi-Cu in an area of significant argillic and phyllic alteration within a thick section of felsic volcanics close to the boundary with the Gaharish granite. The mineralization along the granitic pluton contact suggests an intrusion-related style of gold mineralization [48]. By comparing the results of our study with the existing geological map (Figures 5 and 6), most of the ore mineralization was observed to occur within the most areas of high hydrothermal intensity. This is because the hydrothermal ore body probably located in areas of high intensity of hydrothermal alteration [8,42]. The presence of mineralized zones along the contact of the granite pluton and country rocks and sheeted quartz veins cutting the granite itself and country rocks revealed the existence of multiphase of mineralizations that need further field investigations in the future.

Conclusions
The Abu-Gaharish area of the CED of Egypt is largely composed of granitoids, metavolcanics, and metasediments. Image transformation techniques using Land sat-8 OLI and ASTER data represent a powerful and costeffective approach for application during the reconnaissance stage of mineral exploration. The use of band ratios and mineral indices for ASTER data through GIS spatial analysis techniques allowed the identification of the location of high grade hydrothermal alteration zones. This was achieved by combining ranked thematic predictor maps. The spatial distribution of hydrothermal alteration minerals in the study area consists of three potential prospective areas. The first area is located in the south of the study area and is consistent with the existing mining area of Abu-Gaharish, which constitutes the new Aton company prospect. The second area is located in the northwestern corner, extending in a NE-SW direction, and is probably related to felsic dikes with quartz veins. The third area is clearly associated with fracture/fault zones within the granites. The examination of spectra allowed key hydrothermal minerals to be identified, including kaolinite-smectite, talc and brucite, revealing the existence of both argillic and propylitic alteration zones. The areas enriched in kaolinite-smectite are restricted to areas with a high prospective potential.