Mineralogical and Environmental Geochemistry of Coal Combustion Products from Shenhuo and Yihua Power Plants in Xinjiang Autonomous Region, Northwest China

The mineralogical and geochemical characteristics of feed coals and coal combustion products (CCPs) from the Shenhuo and Yihua Power Plants in Xinjiang Autonomous Region, were studied by means of proximate analysis, Power X-ray diffraction (XRD), scanning electron microscopy with Energy Dispersive X-ray analyzer (SEM-EDX), inductively coupled plasma atomic emission spectrometry (ICP-MS) and inductively coupled plasma mass spectrometry (ICP-AES). The environmental geochemistry of CCPs was evaluated by Al-normalized enrichment factor as well as European Standard EN-12457 leaching test. Two feed coals have the characteristics of low sulfur content, medium to high volatiles matter yields, medium moisture content, super low to medium ash yield, medium to high calorific value and low mineral content. The main crystalline facies in fly ash and slag are quartz and mullite, with a small amount of calcite, and some unburned carbon. Hematite, SrSO4 and barite also can be observed in fly ashes by SEM. Typical plerophere occurs in fine fly ash rather than the coarse fly ash. The concentration of most trace elements in CCPs falls within the lower concentration range of European fly ashes. With respect to the partitioning behavior of trace elements during coal combustion, S is highly volatile, and Mg, Na, Zn, B, Co, As, Nb, Zr, Cu and K also show certain volatility, which may to some extent emit to the atmosphere. Furthermore, leaching experiments show that leachable concentrations of most of the potentially toxic elements in CCPs are low, and the CCPs fall in the range between inert and nonhazardous landfill material regulated by the 2003/33/EC Decision.


Introduction
China is the largest producer and consumer of coal in the world [1], which relies on coal for 70% of its energy needs. In 2018, coal consumption reached 2.7 billion tons [2], or about 1.9 billion tons of oil equivalent (1 ton of oil is equivalent to 1.43 tons of standard coal), accounting for 50.58% of global coal consumption. According to the China's 13th five-year plan (2016-2020) for National Economic and Social Development, China plans to cap coal consumption at 4.1 billion tons by 2020 [3], which implies coal consumption will rise sequentially [4][5][6]. The use of coal resources promotes economic development, meanwhile, air pollutants, particulate matter, as well as CCPs from coal combustion cause serious environmental problems [7][8][9][10].
With increasing environmental concerns, the need for research on potential applications for CCPs has become more environmentally relevant [11]. Nowadays, a large proportion of CCPs has been used for different purposes worldwide [9,[12][13][14]. However, large volumes of the world's CCPs, especially unexploited fly ashes are still discharged into ash ponds, landfills, and/or lagoons [15][16][17]. The CCPs may contain relatively high concentrations of elements of environmental concern. A number of these elements may be present in highly leachable species, increasing their potential environmental and health impacts, especially when large amounts of CCPs are disposed of in lagoons and landfills. Furthermore, the emplacement of CCPs also involves significant costs and environmental impacts associated with landfill disposal [9]. On the other hand, the high volume of coal usage in China has increasingly focused attention on the valuable elements that may occur in the coal and associated ash (e.g., Ge, Ga, U, rare earth elements and Y, Nb, Zr, Se, V, Re, Au, and Ag, as well as the base metal Al) [1]. Coal and coal ash can also be considered as an economic source of strategically important valuable elements, when these elements in several coals (or coal ashes) and some coal-bearing strata occur at concentrations comparable to or even higher than those in conventional economic deposits [18][19][20]. For instance, two Chinese (Lincang and Wulantuga) and one Russian (Spetzugli, Pavlovsk Coalfield) Ge-bearing coal deposits are currently being mined where Ge is recovered from the fly ash, with the Ge production from these deposits accounting for more than 50% of the total industrial Ge production in the world [21,22]. Laudal et al. (2018) study suggests that rare earth elements can be extracted from lignite by acidic solution [23];  found that rare earth elements recovery use staged precipitation from a leachate generated from coarse coal refuse [24]. In addition, CCPs might also be utilized as other recoverable resources for various applications depending on the manifold physico-chemical characteristics of CCPs, for instance, synthesis of zeolite, geopolymer, recovery of cenospheres, and so on [9,25,26]. As a consequence, investigations into the various characteristics of CCPs are environmentally beneficial and of high economic and social significance from the viewpoint of both CCP disposal and CCP utilization.
There are enormous coal resources from several large coal basins, with various coal characteristics in Xinjiang, and a number of studies have been extensively carried out on the Xinjiang coals and coal ashes [27][28][29]. Dai et al. (2015) reported that the Yili coals are characterized by high concentrations of U (up to 7207 µg/g), Se (up to 253 µg/g), Mo (1248 µg/g), and Re (up to 34 µg/g), as well as As (up to 234 µg/g) and Hg (up to 3858 ng/g), and industrial materials can be extracted from it [29]. The super-large eastern Junggar coals are of high quality with low trace element concentrations except Na, Sr, and Ba [25,26]. The Xinjiang lignite mined from Shaerhu coalfield (SEHc) easily causes severe fouling and corrosion because of its high sodium and chlorine contents [30].  adopted sequential chemical extraction experiment (SCEE) to quantitatively determine the arsenic occurrence modes of high-arsenic coal from Hanshuiquan district, Santanghu Coalfield [31]. Furthermore, previous studies have also been made on the structural properties of coal and the variation of ash content of coal ash in Xinjiang [32][33][34]. The environmental characteristics of CCPs, especially the leaching and partitioning behavior, are extremely important properties that influence their further disposals and applications. The Leaching Environment Assessment Framework (LEAF) proposed by the United States Environmental Protection Agency was adopted by Zhang et al. (2019), discussing the modes of occurrence and causes of mobility of trace elements in CCPs [35]. Yang et al. (2019) investigate leachate and mobility of elements in uranium-enriched coal ash with thermo chemical treatment [36].  reported that CCPs from two power plants in Xinjiang has low environmental threat, which is beneficial to the subsequent application [37]. Nevertheless, given the aforementioned various characteristics of coals in Xinjiang, the CCPs generated are supposed to have diverse characteristics with different environmental implications. Therefore, the significance of research on various characteristics of CCPs in Xinjiang cannot be overemphasized. Due to the increasing energy demand in China and large clean coal resources in Xinjiang, especially in Junggar coal field, recently, there are many coal-fired power plants near the Junggar coalfield, which produce a large amount of CCPs. The present study aims at investigating the mineralogical and environmental geochemistry of feed coals and CCPs from the Shenhuo and Yihua power plants, located in eastern Junggar coalfield, with emphasis on the study of trace elements, especially their leaching potential and partitioning behavior during combustion, in order to assess their environmental impacts and potential for further application [35,36,38].

Sampling and Power Plant Description
Sampling was carried out at two pulverized coal combustion (PCC) power plants in Xinjiang Province, viz., the Shenhuo and Yihua power plants ( Figure 1). The Shenhuo and Yihua power plants are located in the Wucaiwan mining area, eastern Junggar coalfield. It is very convenient for the feed coal transportation due to superior geographical position. Plasma Atomic-Emission Spectrometry (ICP-AES) (Iris Advantage TJA Solutions, Thermo Fisher Scientific, MA, USA) for major and selected trace elements (Ti, Mn, P, B, Ba, Cu, Ni, Sr, Zn and V), and by Inductively-Coupled Plasma Mass Spectrometry (ICP-MS) (X-Series II Thermo, Thermo Fisher Scientific, Waltham, MA, USA) for most trace elements. Logically the content of above trace elements must be higher than the detection limit of ICP-AES. We do it as an intra-comparison exercise, which is a way to compare both results and know if the determination results are precise. As aforementioned, extensive studies have been carried out on leaching of coal combustion byproducts [35,36,38]. In this paper, the European Standard leaching test EN-12457 [46] was applied to fly ash and slag samples to evaluate the leaching potential of major and trace elements. The standard EN 12457 batch leaching test (Liquid/Solid ratio of 10 L per kg in MilliQ water which were produced by Mill-Q ultrapure water preparation system), 24 h agitation at ambient temperature) was undertaken on the CCP samples to study the solubility and mobility of trace elements from the CCPs. Thereafter, the solution was filtered, respectively, and the leachable concentrations of major and trace elements in the extracts were measured by ICP-AES and ICP-MS.

Data Treatment
In order to measure the distribution of elements in flue gas, fly ash and slag during coal burning in Shenhuo and Yihua power plant, Al is considered as a non-volatile element, and aluminum normalization enrichment factor, is used to quantify the enrichment of the major and trace elements in fly ash (EFA) and slag (EFS) [37,47,48]. Meanwhile, normalized (fly ash + slag)/feed coal enrichment factors (total enrichment factors, EFT) is calculated by the following formula: EFT = EFA × A + EFS × B, where A and B are the production proportion of the fly ash and slag (90% and 10% respectively) When the enrichment coefficient EFA or EFS > 1, it indicates that the element is enriched in fly ash or slag. The enrichment coefficients of low volatile elements are≈1, those of high volatile elements are <1. EFT can indirectly determine the volatility of each element in feed coal. Thus, EFA < 1, EFS < 1 The operating conditions of both plants are characterized by pulverized-coal (PC) boilers, electrostatic precipitators (ESP) and a limestone-gypsum wet flue gas desulfurization system (WFGD). The two power plants are both fed with a blend of coals from different coal fields in Xinjiang but mainly from the Junggar coal basin.
The feed coal, fly ash, and slag samples were simultaneously collected at the Shenhuo and Yihua PCC power plants in July 2017. One feed coal (S-C), one slag (S-Slag), and two fly ash samples (one coarse and one fine fraction from different rows of the electrostatic precipitators (ESP), S-FAf, S-FAc, respectively) were taken from the Shenhuo power plant. One feed coal (Y-C) one fly ash (Y-FA) and one slag (Y-Slag) sample were collected from the Yihua PCC plant.
The fly ash/slag ratio was 9:1 (90% and 10% of the production, respectively) at both Shenhuo and Yihua power plants. Furthermore, the production of fine and coarse fractions of fly ash in the Shenhuo power plant with a 2:3 fine/coarse fly ash ratio should be noted.
Around 1kg of each sample were collected, split, and 50 g of each sample were crushed and milled to different grain size for subsequent analyses.

Methods
Proximate analysis of feed coal was performed following ASTM-Standards D3173-11, D3174-12 (2018), and D3175-18 [39][40][41]. Elemental analysis (N, C, S, H) of feed coal, fly ash, and slag were determined by an Element instrument (Vario EL III, Elementar Trading (shanghai), Shanghai, China). Grain size distribution of CCPs was analyzed by Mastersizer2000 (Malvern Instruments, Worcestershire, UK). The mineralogical composition was analyzed by XRD and SEM-EDX. When applying XRD map scanning, the interval of 2 theta is 2.6-70 • , and step length is 0.01 • . Semiquantitative XRD analysis was performed by using the matrix flushing method devised by Chung (1974) and calculating the integrated area of the main peak for the different mineral phases in each sample [42]. Fluorite (CaF2) in binary mixtures was used as an internal standard to determine the diffraction constants against fluorite for each mineral phase [43]. This method is based on the XRD intensity ratio between a crystalline phase and an internal standard. This method first requires the calculation of the XRD constants for each crystalline phase by applying the Klug and Alexander equation [44]. Subsequently, the material under study is spiked with the internal standard and analyzed by XRD to obtain the proportions of each crystalline phase of the sample. The microstructure of minerals and morphology of CCPs were observed by QUANTA840 SEM-EDX (FEI, Hillsboro, OR, USA).
Feed coal, fly ash, and slag samples were acid-digested by using a two-step digestion method devised by Querol et al. [45]. The resulting solutions were then analyzed by Inductively-Coupled Plasma Atomic-Emission Spectrometry (ICP-AES) (Iris Advantage TJA Solutions, Thermo Fisher Scientific, MA, USA) for major and selected trace elements (Ti, Mn, P, B, Ba, Cu, Ni, Sr, Zn and V), and by Inductively-Coupled Plasma Mass Spectrometry (ICP-MS) (X-Series II Thermo, Thermo Fisher Scientific, Waltham, MA, USA) for most trace elements. Logically the content of above trace elements must be higher than the detection limit of ICP-AES. We do it as an intra-comparison exercise, which is a way to compare both results and know if the determination results are precise.
As aforementioned, extensive studies have been carried out on leaching of coal combustion by-products [35,36,38]. In this paper, the European Standard leaching test EN-12457 [46] was applied to fly ash and slag samples to evaluate the leaching potential of major and trace elements. The standard EN 12457 batch leaching test (Liquid/Solid ratio of 10 L per kg in MilliQ water which were produced by Mill-Q ultrapure water preparation system), 24 h agitation at ambient temperature) was undertaken on the CCP samples to study the solubility and mobility of trace elements from the CCPs. Thereafter, the solution was filtered, respectively, and the leachable concentrations of major and trace elements in the extracts were measured by ICP-AES and ICP-MS.

Data Treatment
In order to measure the distribution of elements in flue gas, fly ash and slag during coal burning in Shenhuo and Yihua power plant, Al is considered as a non-volatile element, and aluminum normalization enrichment factor, is used to quantify the enrichment of the major and trace elements in fly ash (EF A ) and slag (EF S ) [37,47,48]. Meanwhile, normalized (fly ash + slag)/feed coal enrichment factors (total enrichment factors, EF T ) is calculated by the following formula: EF T = EF A × A + EF S × B, where A and B are the production proportion of the fly ash and slag (90% and 10% respectively) When the enrichment coefficient EF A or EF S > 1, it indicates that the element is enriched in fly ash or slag. The enrichment coefficients of low volatile elements are≈1, those of high volatile elements are <1. EF T can indirectly determine the volatility of each element in feed coal. Thus, EF A < 1, EF S < 1 or EF T < 0.9 indicate that the elements in the feed coal volatilize (the error of this method is about 10-15%).

Feed Coal Characteristics
Eastern Junggar coal is high volatile bituminous, with vitrinite reflectance of 0.40-0.50%. As shown in Table 1, the feed coals of Shenhuo and Yihua power plants show the characteristics of low sulfur content, super low to high volatile matter yield, medium moisture content, low-medium ash yield and medium-high calorific value. The feed coals belong to medium-high volatile bituminous, which is basically in line with previous studies [49]. Table 1. Proximate analyses of feed coals from Shenhuo and Yihua power plants. Y-C, feed coal from Yihua power plant; S-C, feed coal from Shenhuo power plant; ad-air dry basis; db-dry basis; daf-dry, ash-free; ar-as received basis; HTA-high temperature ash, VM-volatile matter; CV-calorific value.   2 ) are the major minerals occurring in two feed coals. In addition, traces of gypsum (CaSO 4 ·2H 2 O) and calcite (CaCO 3 ) were also detected in S-C. In general, the total mineral content of feed coals is low, among which the content of clay minerals and quartz is relatively high, while that of pyrite is lower, due to the continental sedimentary coal-forming environment.
The concentrations of major and trace elements in feed coals are listed in Table 2. Compared with the average content of major elements in Chinese coals [50], calcium and sodium are slightly higher, while the depletion of aluminum, iron, and titanium is obvious, and the content of, magnesium and potassium is close to the average ( Table 2).
As described in the Table 2, the concentrations of trace elements in feed coals are compared with the average for China coals reported by Dai et al. (2012) and world low-rank coals reported by Ketris and Yudovich (2009) [26,51]. According to the concentration coefficients normalized to average trace element concentration for Chinese and worldwide coals [29], except Sr and Ba in S-C, the contents of most elements in two feed coals fall in the lower range of the worldwide concentration ranges, and lower than the average values of worldwide coals [51]. Analogously, when compared with the content in Chinese coals, only Sr and Ba in S-C are higher than the average value, and content of other elements are low (Figures 2 and 3). In summary, except for Sr and Ba in S-C, the content of other trace elements in feed coals, including those closely related to the environment, e.g., As, Hg, Be, Cr, Co, Ni, Cu, Zn, Se, Mo, Cd, Sn, Sb, Pb, Bi is relatively low. The higher Sr and Ba content in feed coal is consistent with those in eastern Junggar coals [26]. Consequently, the feed coal of Shenhuo and Yihua power plants, from the perspective of environmental protection, possesses high quality.

Physical Characteristics
As shown in Figure 4, through Mastersizer2000 particle size analysis, it is obvious that the particle size of S-FAf is smaller than that of S-FAc. S-FAc is characterized by a trimodal lognormal

Physical Characteristics
As shown in Figure 4, through Mastersizer2000 particle size analysis, it is obvious that the particle size of S-FAf is smaller than that of S-FAc. S-FAc is characterized by a trimodal lognormal

Physical Characteristics
As shown in Figure 4, through Mastersizer2000 particle size analysis, it is obvious that the particle size of S-FAf is smaller than that of S-FAc. S-FAc is characterized by a trimodal lognormal grain size distribution with a prevalent coarse mode over two fine mode (Figure 4). The particle size of S-FAc is concentrated around 150 um, which is between 0.4 and 503 µm, with P10 (10th percentile) of 2.58 µm, P50 of 64.84 µm and P90 of 239.05 µm. By contrast, S-FAf shows a bimodal grain size distribution, with one peak of around 5µm and the other of 60 µm. The particle size of S-FAf is between 0.4 and 282 µm, with P10 of 1.96 µm, P50 of 14.41 µm and P90 of 98.47 µm. The characteristics of Y-FA is similar to S-FAf, with one peak of around 3µm and the other of 40 µm. The particle size of Y-FA is between 0,4 and 224 µm, with P10 of 1.23 µm, P50 of 8.03 µm and P90 of 67.18 µm, suggesting that the particle size of Y-FA is the tiniest among the three fly ashes.
while those of S-FAf, S-FAc, Y-Slag, and S-Slag are 3.6%, 3.4%, 0.1%, and 0.6% respectively. The LOI values of fly ash are greater than that of slag, which is not only related to destruction of the unburned carbon present, but also to breakdown of mineral phases (e.g., decomposition of carbonates, oxidation of sulfides, release of structure water from clay minerals, and dehydration of lime) and to water physically adsorbed on measured samples (e.g., CaO that is rich in fluidized-bed combustion (FBC) ashes) [53].
Both fly ash and slag samples from Shenhuo and Yihua power plants demonstrate typical aluminosilicate compositions, with SiO2 contents higher than those of iron and aluminum oxides. The total content of SiO2, Al2O3, and Fe2O3 is 72.4%, 71.2% and 71.5%, respectively in S-FAf, S-FAc and Y-FA, which is slightly lower than that in the S-Slag (79.9%) and Y-Slag (74.4%). The major element composition indicates that Shenhuo and Yihua power plants produces Class F fly ash, characterized by SiO2 + Al2O3 + Fe2O3 ≥ 70%, and LOI < 6% [54]. I t is worth nothing that Class F fly ash is usually considered to be a combustion product of higher rank coals, while Class C fly ash generally comes from the combustion of lower rank coals [55]. The determining factor, however, should be the major element composition rather than the source coal rank.]

Mineralogical Characteristics
The characteristics of fly ash are to some extent dependent on the elemental concentrations and modes of element occurrence in feed coals as well as on the combustion conditions [22,[56][57][58][59]. Fly ash and slag produced from the same feed coal generally have a similar chemical composition, but in common cases, different particle sizes and phase compositions [58]. With respect to fly ash samples, both S-FAf, S-FAc and Y-FA are made up of a predominant Al-Si-Ca-Fe amorphous glass matrix (83%, 77.6% and 86.5% respectively), with different proportions of quartz, mullite (3Al2O3·2SiO2), calcite (CaCO3) as major crystalline components (Table 3; Figure 5a  The moisture of fly ash and slag samples is very low (0.02-0.9%) and falls within the ranges determines for EU fly ashes (Table 3). Moisture content of the over-drying process after sampling. Y-FA shows the highest moisture (0.9 FAf is similar to FAc, but low to Y-FA. The moisture content of slag is close to 0, probably owing to %) among the combustion residues. The loss on ignition (LOI) values of fly ash and slag samples fall within the lower range of European fly ashes [52] or even below the minimum value. Y-FA shows the highest LOI value (5.3%) while those of S-FAf, S-FAc, Y-Slag, and S-Slag are 3.6%, 3.4%, 0.1%, and 0.6% respectively. The LOI values of fly ash are greater than that of slag, which is not only related to destruction of the unburned carbon present, but also to breakdown of mineral phases (e.g., decomposition of carbonates, oxidation of sulfides, release of structure water from clay minerals, and dehydration of lime) and to water physically adsorbed on measured samples (e.g., CaO that is rich in fluidized-bed combustion (FBC) ashes) [53].
Both fly ash and slag samples from Shenhuo and Yihua power plants demonstrate typical aluminosilicate compositions, with SiO 2 contents higher than those of iron and aluminum oxides. The total content of SiO 2 , Al 2 O 3 , and Fe 2 O 3 is 72.4%, 71.2% and 71.5%, respectively in S-FAf, S-FAc and Y-FA, which is slightly lower than that in the S-Slag (79.9%) and Y-Slag (74.4%). The major element composition indicates that Shenhuo and Yihua power plants produces Class F fly ash, characterized by SiO 2 + Al 2 O 3 + Fe 2 O 3 ≥ 70%, and LOI < 6% [54]. I t is worth nothing that Class F fly ash is usually considered to be a combustion product of higher rank coals, while Class C fly ash generally comes from the combustion of lower rank coals [55]. The determining factor, however, should be the major element composition rather than the source coal rank.]

Mineralogical Characteristics
The characteristics of fly ash are to some extent dependent on the elemental concentrations and modes of element occurrence in feed coals as well as on the combustion conditions [22,[56][57][58][59]. Fly ash and slag produced from the same feed coal generally have a similar chemical composition, but in common cases, different particle sizes and phase compositions [58]. With respect to fly ash samples, both S-FAf, S-FAc and Y-FA are made up of a predominant Al-Si-Ca-Fe amorphous glass matrix (83%, 77.6% and 86.5% respectively), with different proportions of quartz, mullite (3Al 2 O 3 ·2SiO 2 ), calcite (CaCO 3 ) as major crystalline components (Table 3; Figure 5a,b). Lime (CaO), periclase (MgO), anhydrite (CaSO4) are present in much lower proportions, and magnetite was also detected in S-FAc and Y-FA. Although not detected by XRD, BaSO4 and SrSO4 were observed under SEM-EDX in three fly ashes (Figure 5f,j,g,h,n,o,p). The occurrence of BaSO4 and SrSO4 is probably attributed to the high content of Sr and Ba in the feed coals, which is mainly fed with Junngar coal. Moreover, plerosphere, cenosphere and unburned carbon can also be observed by SEM-EDX in fly ashes (Figure 5k,m). Cenospheres are one of the most desired byproducts of coal combustion process nowadays [60]. It has a hollow spherical structure and can be applied in a wide range of industrial applications, due to their superior properties; such as low bulk density, high thermal resistance, high workability and high strength [61]. Plerosphere is a typical fly ash structure, which can be formed due to capture of microspheres by a cenosphere during combustion [62]. Plerosphere with a quantity of hollow microspheres both can reduce the emission of fine particles into the atmosphere and enrich elements inside itself.
As aforementioned, the glass matrix content of S-FAf and Y-FA is high, however, the content of crystalline components is lower than that of S-FAc, which may be attributed to the larger grain size and pores of the coarse ash when compared to those of fine ash, forasmuch minerals tend to crystallize in the pores of coarse ash.
When compared with EU fly ashes [48], the content of crystal minerals in fly ash basically falls in the low EU range, nevertheless glass matrix contents are in the upper range of EU fly ashes. Fly ash has high calcite content, which may be attributed to the high calcite content in feed coal, or because of the calcite formed by adding lime in the flue gas desulfurization device. The occurrence of mullite is attributed to the decomposition of kaolinite, illite, and other clay minerals in the coals. The higher content of mullite in fly ash corresponds to the higher characteristics of aluminum minerals in feed coals. The occurrence of lime is due to the decomposition of feed-coal calcite into CaO and CO 2 at around 900 • C. The occurrence of periclase is usually related to the presence of MgO in fly ash.
Cenospheres are one of the most desired byproducts of coal combustion process nowadays [60]. It has a hollow spherical structure and can be applied in a wide range of industrial applications, due to their superior properties; such as low bulk density, high thermal resistance, high workability and high strength [61]. Plerosphere is a typical fly ash structure, which can be formed due to capture of microspheres by a cenosphere during combustion [62]. Plerosphere with a quantity of hollow microspheres both can reduce the emission of fine particles into the atmosphere and enrich elements inside itself.  With respect to slag sample, S-Slag and Y-Slag also contains aluminium-silicate amorphous glass matrix as major constituent (56%, 75% respectively). S-Slag has variable contents of anorthite and mullite as the main crystalline phases (Table 4). Furthermore, quartz and calcite are also present in minor proportions. The content of mullite, quartz and calcite in slag is higher than those of fly ash, while quartz and hematite can be detected in microscopic perspective under SEM (Figure 5c-e). Y-Slag is made up of quartz, anorthite and augite as crystalline phases (Table 4). Significantly, the anorthite content in the S-Slag and Y-Slag reaches 23.6% and 4.6%. Although the content of sodium and calcium in fly ash is higher than that in slag, anorthite content is much higher in slag than in fly ash, indicating that the majority of anorthite is formed from a combination of aluminosilicate matrix and sodium calcium oxide in slag. Similarly, augite is formed from the cooling crystallization of aluminosilicate.

Geochemical Characteristics
As demonstrated in Table 4, the concentrations of Ca and S are higher in fly ash than in slag, which is consistent with the previous study that fly ash samples have higher content of anhydrite than slag. The concentration of Fe shows an opposite trend, due to the density of iron, or to the formation of magnetite at high temperatures. With the exception of Ca, S and Fe, the concentrations of other elements in fly ash samples are approximate to that in slag samples. When compared with the concentrations of major oxides in EU fly ashes [48], Na concentrations in three fly ashes and two slags are higher than its maximum value in EU fly ashes. Aluminum, Ca, Fe, K, Mg and S concentrations fall within the middle concentration range of EU fly ashes.
Overall, the concentrations of trace elements in CCPs are very low. When compared with the average values of EU fly ashes, concentrations of most trace elements in fly ashes and slags are between the corresponding 25th percentile (P25) and P75 values of EU fly ashes (Figure 6), and those of some elements, such as Li, Be, V, Cr, Co, Ni, Zn, As, Se, Rb, Mo, Cd, Sn, Sb, Th and U are even lower than or similar to the corresponding P25 values of EU fly ashes ( Figure 6). Furthermore, the contents of Be, As, Se, Cd, Sn, Th, U in fly ash are even lower than or close to the minimum values of EU fly ash. Nonetheless, B, Sr and Ba in three fly ashes show higher concentrations, greater than or similar to the maximum values of EU fly ashes. As regards Yihua power plant, the concentrations of most elements are higher in Y-FA than in Y-Slag with the exception of Fe, K, Y, Zr and Nb (Table 4). Comparing the element concentrations between S-FAf and S-FAc from Shenhuo power plant, with the exception of Li, B, Cr, Sr and Pb, the concentrations of most elements are higher in S-FAf than in S-FAc, which is consistent with previous studies [37,45,47]. It is worth noting that because of the REY non-volatile properties during coal combustion, the REY are not expected to partition between fly ash, bottom ash, and slag [18].

Enrichment and Partitioning of Major and Trace Elements
According to the EF calculated on the strength of element concentrations in feed coals, elements can be classified as four groups in both power plants (Table 5, Figure 7).

Enrichment and Partitioning of Major and Trace Elements
According to the EF calculated on the strength of element concentrations in feed coals, elements can be classified as four groups in both power plants (Table 5, Figure 7). to some extent exhibit partial volatile proportions. The volatility of As, Nb, Zr, Cu and K may be due to the presence of highly volatile metal chlorides, and the temperature of ESP is high. As regards the Yihua plant, S shows similar partitioning as at the Shenhuo plant, with the highest volatile fraction (54%), and as described for the Shenhuo plant, only 5% of S is emitted into the atmosphere, whereas 49% of S is retained in the FGD. The remaining S is all retained in fly ash. The higher volatile fraction of S at the Shenhuo plant may be due to a lower content of Ca. Mg (13%), Na (18%), B (25%), Co (26%), and Zr (20%) also display relatively high volatile proportions. The remaining elements of two power plants have no obvious volatile behavior, furthermore, when compared with the concentrations of elements in slag, and more than 70% partition of each element is retained in fly ash because of the much higher production of fly ash in regard to slag.  For the Shenhuo power plant, the elements are classified as follows: (a) Elements abounded in fly ash and exhausted in slag: Ca, Mg, Na, B, P, Co, Ga, Pb; (b) elements abounded in slag and exhausted in fly ash: Fe; (c) elements with unapparent abundance or exhaustion in fly ash and slag: Ti, V, Zn, Th, Ba and REEs; (d) elements exhausted in both fly ash and slag: K, S, Cu, As, Rb, Zr, Nb.
Likewise, for the Yihua power plant, the elements are classified as follows: (a) Elements abounded in fly ash and exhausted in slag: Ca, Cr, Ni, As, Pb; (b) elements abounded in slag and exhausted in fly ash: Fe, K, Zr; (c) elements with unapparent abundance or exhaustion in fly ash and slag: P, Ti, Li, V, Ni, Ba and REEs; (d) elements exhausted in both fly ash and slag: Mg, Na, B, Co, Zn, S. The elements which are abounded in fly ash and exhausted in slag, displaying volatile or semi-volatile behavior during the combustion process, then condensing in the fly ash through ESP (the temperature falls from 1300 • C to about 150 • C). Ca and Pb are the commonable elements in this group at both power plants. Mg, Na, B, P, Co and Ga are enriched in fly ash at the Shenhuo power plant and Cr, Ni, and As at the Yihua power plant. As described above, the reason why Fe is enriched in slag and exhausted in fly ash at both power plants is because of its high density and/or reactivity to be magnetic. The elements without abundance in fly ash or slag are those that typically exhibit non-volatile behavior during combustion. It is those volatile elements in coal combustion that are partly exhausted in both fly ash and slag, especially S. As mentioned above, As, Nb, Zr, Cu and K present exhaustion at the Shenhuo power plant, suggesting that the ESP temperature is too high for As and other elements to condense out of the gas stream. At Yihua power plant, Mg is exhausted both in fly ash and slag, together with Na, B, Co and Zn. The partial volatility of these elements may be attributed to a higher ESP temperature at the Yihua than at the Shenhuo power plant.
The partitioning for major and trace elements at the ESP and boiler in Shenhuo and Yihua PCC plants were calculated by normalized EFt with the fly ash (90%) and slag (10%) production ( Figure 8). For the Shenhuo power plant, S is the element with the highest volatile portion at ESP (80%). However, considering that the retention efficiency of S in general power plants is 90%, the content of S discharged into the atmosphere is about 8%, 72% of which is retained in the FGD device, with most of the remaining S reserved in the fly ash. As (30%), Nb (30%), Zr (20%), Cu (20%), and K (20%) also to some extent exhibit partial volatile proportions. The volatility of As, Nb, Zr, Cu and K may be due to the presence of highly volatile metal chlorides, and the temperature of ESP is high.
volatile fraction (54%), and as described for the Shenhuo plant, only 5% of S is emitted into the atmosphere, whereas 49% of S is retained in the FGD. The remaining S is all retained in fly ash. The higher volatile fraction of S at the Shenhuo plant may be due to a lower content of Ca. Mg (13%), Na (18%), B (25%), Co (26%), and Zr (20%) also display relatively high volatile proportions. The remaining elements of two power plants have no obvious volatile behavior, furthermore, when compared with the concentrations of elements in slag, and more than 70% partition of each element is retained in fly ash because of the much higher production of fly ash in regard to slag.   As regards the Yihua plant, S shows similar partitioning as at the Shenhuo plant, with the highest volatile fraction (54%), and as described for the Shenhuo plant, only 5% of S is emitted into the atmosphere, whereas 49% of S is retained in the FGD. The remaining S is all retained in fly ash. The higher volatile fraction of S at the Shenhuo plant may be due to a lower content of Ca. Mg (13%), Na (18%), B (25%), Co (26%), and Zr (20%) also display relatively high volatile proportions. The remaining elements of two power plants have no obvious volatile behavior, furthermore, when compared with the concentrations of elements in slag, and more than 70% partition of each element is retained in fly ash because of the much higher production of fly ash in regard to slag.

Leaching Potential
The leaching experiment simulates the process of different elements' dissolution and migration of CCPs, which are piled in open space and leached by natural rain (acid rain). Subsequently, the concentrations of elements in leaching solution were determined by ICP-AES and ICP-MS to reveal the occurrence mode and migration characteristics of various elements in CCPs (Table 6). Most elements are capable of leaching, and according to the European Council Decision 2003/33/EC [46], whether the element content is hazardous or not is classified after leaching experiment. The leachable concentrations of Ca, Mg, Na, S and Si (major elements) as well as B, Cr, Mn, Se, Sr, Mo, Ba (trace elements) in CCPs from both power plants are comparatively high, falling within inert to non-hazardous range for landfill materials. The concentrations of Cr, Se, Mo, and Ba from S-FAf are considered as non-hazardous landfill materials, and those of remaining elements fall within the inert range for landfill materials. In terms of leachability of elements, the leachable concentrations of most trace elements are higher in S-FAf than in S-FAc, and slag presents the lowest leachability, which is relevant to the concentrations of elements present in corresponding samples. Overall, CCPs from the Shenhuo and Yihua power plant belong to inert landfill materials, indicating that they can be utilized with low environmental implication. Table 6. Element concentrations of fly ash and slag leachates compared with EU fly ash leachates [52] and inert, non-hazardous, and hazardous limit values of some toxic elements for landfill materials.