Content Characteristics of Rare Earth Elements in Stone Coal and Parting in Southern Shaanxi, China ()
1. Introduction
Stone coal is a kind of inferior sapropelite which is formed in ancient strata. It has the characteristics of high ash, high sulfur, low carbon content, low calorific value, accompanying many kinds of metal elements and so on [1] [2] [3] . China’s stone coal resources are widely distributed and have rich reserves, which cover more than 20 provinces and regions, and the amount of stone coal in southern Qinling Mountain is the most [4] . Ankang City is located in the southern part of Shaanxi Province, south of Qinling Mountain and north of Bashan Mountain. It is famous for the existence of stone coal resources (Figure 1), and it belongs to the North Daba Mountain fold system of Kunlun Qinling tectonic belt [5] . The stone coal of Ankang is mainly distributed in the Cambrian system of Hanbin district, Ziyang county, Langao county, Pingli county and Zhenping county and Silurian system. The available stone coal reserves in southern Shaanxi are more than 300 million ton [6] [7] [8] , which can guarantee the comprehensive utilization of 3 million t stone coal projects for more than 100 years. The stone coals of southern Shaanxi contain vanadium, molybdenum, uranium, selenium, gallium, phosphorus, silver, zinc, copper, cadmium, cobalt, platinum, lead, palladium, nickel, yttrium and so on [9] [10] [11] [12] . And the purity of vanadium is generally high, which can reach the value of exploitation; the next ones are molybdenum, uranium, phosphorus, silver and other elements [13] .
Luo et al. have counted the selenium content in the lower Cambrian Lujiaping formation (41.0 μg/g), the Jianzhuba formation (18.5 μg/g) and the Lower Silurian Daguiping formation (14.0 μg/g) in the southern Qinling Mountains [9] [10] [14] . They consider that the hot magma of early Cambrian system volcanic
Figure 1. The sampling point distribution diagram.
activity is the main source of selenium element in the stone coal, and the main factor is the adsorption of organic matter and clay [9] . Hu et al. [15] , Tang et al. [16] , Tang [17] and Li et al. [18] tested for arsenic content in stone coal of southern Shaanxi, and the results showed that arsenic content in stone coal was much higher than that in Chinese coal [19] . Chen et al. [20] found that the highest fluorine content of stone coal in Daba Mountain and parts of Qinling Mountains was 4688.0 μg/g, which led to the prevalence of fluorosis. To sum up, the trace element geochemistry of stone coal in southern Shaanxi mainly concentrates on the statistics of vanadium, selenium, fluorine, arsenic and other elements. The source of the above elements, the state of occurrence, and the environmental effect and so on are analyzed. The study of rare earth elements in southern Shaanxi stone coal is relatively weak [21] .
Due to their stable chemical properties and high degree of homogenization, there are rare earth elements often hidden with some geological evolution information and considered as good geochemical indicators, which have always been the focus of geochemical research [22] [23] . There are few reports on the REE contents, distribution patterns and geochemical characteristics of δCe and δEu in stone coals of southern Shaanxi province. This study aims to explore the characteristics of rare earth elements in stone coal of southern Shaanxi, and provide a plan for the comprehensive utilization of stone coal.
2. Sample Collection and Experiment
Stone coal mining in southern Shaanxi has a long history [24] [25] . The samples were collected from Ankang City and Hanzhong City of Shaanxi Province and distributed in Zhenping County, Pingli County, Ziyang County and Zhenba County in this research (Figure 1). Sample YLEW was collected from Yulaoerwan Coal Mine in Zhenping County, sample BX was collected from Baxian Coal Mine in Pingli County, sample YDH was collected from Yuduhe Coal Mine in Pingli County, sample HYL was collected from Hualing Village of Baxian Town, Pingli County, and sample XCY was collected from Xiaoteyuan Village of Huoxi Township in Ziyang County. Sample YJB was collected from Yuanjiaba Coal Mine in Zhenba County, sample AJS was collected from Anjiashan Coal Mine in Zhenba County, sample BSX was collected from Baishuixi Coal Mine in Zhenba County, and sample RCX was collected from Rencun Xiang Coal Mine in Zhenba County. In this study, three types of samples were collected: “-C” for coal, “-P” for parting and “-A” for coal ash. The sample was condensed according to the method of four fractions of pile cones, and one sample was broken and ground in order to make the particle size of the sample was less than 200 mesh. Determination of rare earth elements in stone coal by microwave digestion and inductively coupled plasma mass spectrometer (Table 1).
3. Content Characteristics of Rare Earth Elements
3.1. Content Characteristics of REEs in Stone Coal
The REEs contents of XCY-C (179.81 μg/g) was higher than that of the mean
Table 1. The rare earth element content (μg/g) and related parameters of stone coal and parting from southern Shaanxi province, China.
aChina coals, data from Dai et al. (2012) [19] ; bWorld coals, data from Ketris and Yudovich (2009) [26] ; cUpper crust continental, data from Taylor and McLennan (1985) [27] . L/H = (LREE/HREE).
value of China coal (135.89 μg/g), the content of light rare earth elements (99.51 μg/g) is slightly lower than the mean value of light rare earth elements (102.83 μg/g) in China coal (102.83 μg/g). The content of heavy rare earth elements (80.30 μg/g) was higher than the mean value of heavy rare earth elements in China coal (33.06 μg/g), the ratio of light and heavy rare earth elements is quite different. The content of Y is 2 times higher than that of in China coal, which is the main reason for the high content of heavy rare earth elements. Compared with the mean value of world coal, the rare earth elements in XCY-C stone coal samples are obviously enriched, which is twice that of the mean value of world coal (68.47 μg/g), and the heavy rare earth element content is 5 times that of the mean value of world coal (16.50 μg/g). The REEs content of XCY-C coal samples is close to the abundance value of upper crust (168.37 μg/g), and it also shows that the light rare earth elements content is lower than the abundance value of upper crust (132.48 μg/g), and the heavy rare earth elements are higher than that of upper crust (35.89 μg/g). The HYL-C, YDH-C and BX-C are collected from Pingli County, these contents of rare earth elements differ greatly among the three samples (21.21 μg/g - 100.61 μg/g). The REEs contents of HYL-C (100.61 μg/g) is higher than that of the mean value of world coal, lower than that of the mean value of China coal and the abundance value of upper crust, the REEs contents of YDH-C (21.21 μg/g) and BX-C (36.95 μg/g) are much lower than the mean value of China coal, the mean value of world coal and the abundance value of upper crust, it shows that the REEs is seriously depleted. The REEs contents of (45.18 μg/g) of YLEW-C is much lower than that of the mean value of China coal, the mean value of world coal and the abundance value of upper crust, and the depletion of rare earth elements are serious. The RCX-C, YJB-C, AJS-C and BSX-C were collected from Zhenba County, and the contents of rare earth elements in the four samples vary greatly. The contents of rare earth elements of BSX-C (106.92 μg/g) is higher than that of the mean value of world coal, lower than that of the mean value of China coal and the abundance value of upper crust. The contents of rare earth elements in RCX-C (12.55 μg/g), YJB-C (19.69 μg/g) and AJS-C (32.20 μg/g) are far lower than the mean value of China coal, the mean value of world coal and the abundance value of upper crust. The contents of rare earth elements in stone coal in southern Shaanxi is generally lower than the mean value of China coal and the abundance value of upper crust, which is close to the mean value of world coal, and it shows the characteristics of serious REEs loss and uneven distribution in general with large regional differences (Table 1).
3.2. Content Characteristics of REEs in Parting
The contents of rare earth elements (53.76 μg/g) in the parting of YDH-P are close to the mean value of world coal. Compared with the corresponding stone coal bed (YDH-C), the contents of rare earth elements increased obviously about 2 times. The ratio of light and heavy rare earth elements varies greatly, showing that light rare earth elements are more enriched in parting. The contents of rare earth elements (290.87 μg/g) in YLEW-P is obviously higher than that the mean value of China coal, the mean value of world coal and the abundance value of upper crust, which is 4.25 times of the mean value of world coal and 6.44 times of the corresponding YLEW-C. Especially, the contents of light rare earth elements (271.10 μg/g) were obviously enriched, and the ratio of light rare earth elements to heavy rare earth elements reached 13.71. The contents of rare earth elements in the four parting samples of RCX-P, YJB-P, AJS-P and BSX-P vary greatly (76.64 μg/g - 138.08 μg/g). Compared with the corresponding stone coal bed (RCX-C, YJB-C, AJS-C, BSX-C), the contents of REE increased 6.11 times, 6.63 times, 2.46 times and 1.29 times of the corresponding coal seam respectively. The ratio of heavy and light rare earth elements increase, it shows that the light rare earth elements in the parting samples are more enriched. The contents of rare earth elements in parting in southern Shaanxi is generally higher than that in corresponding stone coal seam (Table 1).
3.3. Content Characteristics of REEs in Coal Ash
The samples of XCY-C and HYL-C were selected and the samples of stone coal were incinerated at 815˚C. Then the contents of rare earth elements in the combustion products were determined. The enrichment of rare earth elements (350.12 μg/g and 168.68 μg/g) in coal ash are higher than that the mean value of China coal, the mean value of world coal and the abundance value of upper crust (Table 1). The enrichment ratio of rare earth elements in coal ash and raw coal samples are defined as the enrichment ratio. There are found that the enrichment ratios of light and heavy rare earth elements are close to each other. The ash yield (44.16% and 51.56%) was smaller than that of the corresponding raw coal (Figure 2). The enrichment of rare earth elements in coal ash indicates that the rare earth elements in stone coal samples mainly exist in inorganic materials. The similar enrichment ratios indicate that the rare earth elements are light, the heavy rare earth elements exist in the same state and the differentiation degree is close to each other.
3.4. The Average Content Characteristics of REEs in Stone Coal, Parting, and Coal Ash
In order to better summarize the content characteristics of rare earth elements in stone coal, parting and coal ash in southern Shaanxi, China. The samples were classified and averaged. The results are shown in Table 1. AVGC is the average value of stone coal samples, AVGP is the average value of parting samples, and AVGA is the average value of coal ash samples. The average value of rare earth elements in stone coal, parting and coal ash samples was divided by the mean value of China coal, the mean value of world coal and the abundance value of
Figure 2. The enrichment ratio of rare earth elements in coal ash and raw coal.
upper crust, and the corresponding enrichment coefficient was obtained (Figures 3-11).
According to the enrichment coefficient, compared with the mean value of China coal, the content of rare earth elements in stone coal is lower than the mean value of China coal (0.26 - 0.80) (Figure 3). Compared with the mean value of world coal, all light rare earth elements and most heavy rare earth elements are lower than the mean value of world coal, Y, Er and Yb are higher than the mean value of world coal. Y is 1.74 times of the mean value of world coal (Figure 4). Compared with the abundance value of upper crust, all the rare earth elements were lower than the abundance value of upper crust (0.25 - 0.67), and the light rare earth loss was higher than the heavy rare earth loss (Figure 5).
Compared with the mean value of China coal, the contents of all heavy rare earth elements in parting samples are lower than the mean value of China coal (0.23 - 0.68), half of light rare earth elements are higher than the mean value of China coal, La, Ce and Sm are higher than the mean value of China coal, and Pr,
Figure 3. The ratio of the average of rare earth elements content in stone coal and China coal.
Figure 4. The ratio of the average of rare earth elements content in stone coal and world coal.
Figure 5. The ratio of the average of rare earth elements content in stone coal and UCC.
Figure 6. The ratio of the average of rare earth elements content in parting and China coal.
Figure 7. The ratio of the average of rare earth elements content in parting and world coal.
Figure 8. The ratio of the average of rare earth elements content in parting and UCC.
Figure 9. The ratio of the average of rare earth elements content in coal ash and China coal.
Figure 10. The ratio of the average of rare earth elements content in coal ash and world coal.
Figure 11. The ratio of the average of rare earth elements content in coal ash and UCC.
Nd and Eu are lower than the mean value of China coal (Figure 6). Compared with the mean value of world coal, all light rare earth elements are higher than the mean value of world coal (1.57 - 2.37), half of heavy rare earth elements are lower than the mean value of world coal, Gd, Tb, Y and Er are higher than the mean value of world coal, Dy, Ho, Tm and Lu are lower than the mean value of world coal (Figure 7). Compared with the abundance value of upper crust, all soil elements were lower than the abundance value of upper crust (0.42 - 0.94), and the heavy rare earth loss was higher than the light rare earth loss (Figure 8).
Compared with the mean value of China coal, the content of all rare earth elements in coal ash is higher than the mean value of China coal (1.18 - 4.22). The average content of 8 elements (Sm, Eu, Gd, Tb, Dy, Y, Er and Yb) is more than twice that of the mean value of China coal, with Er reaching 3.19 times and Y 4.22 times (Figure 9). Compared with the mean value of world coal, all rare earth elements are higher than the mean value of world coal (2.29 - 9.14), and the average content of 6 elements (Sm, Eu, Tb, Dy, Y, Er and Yb) is more than 4 times of the mean value of world coal, in which Er is 6.14 times and Y is 9.14 times (Figure 10). Compared with the abundance value of upper crust, except for Ce, the other rare earth elements were all higher than the abundance value of upper crust (1.24 - 3.49), and the enrichment degree of heavy rare earth elements was higher than that of light rare earth elements, especially Y element, which was 3.49 times of the abundance value of upper crust (Figure 11).
4. Conclusion
Southern Shaanxi is a well known stone coal occurrence area in China. Stone coal is widely distributed and abundant in reserves. There are a variety of rare metal elements (V, Mo, Ga, etc.) associated with stone coal. However, the content of rare earth elements in stone coal is not high, which is generally lower than the mean value of China coal. Compared with the mean value of world coal, light rare earth elements are lower than the mean value of world coal, and Y, Er and Yb heavy rare earth elements are higher than the mean value of world coal. Compared with the abundance value of upper crust, all the rare earth elements are lower than the abundance value of upper crust, showing that the light rare earth deficit is higher than the heavy rare earth deficit. The low content of rare earth elements in stone coal indicates that the supply of rare earth elements in the source area is limited, and the rare earth elements are constantly lost during the evolution of coal seams. The rare earth elements are obviously more abundant in the parting than in the corresponding coal seam, generally about 2 - 6 times. This phenomenon implies that different sedimentary environments are the main factors that lead to the increase of rare earth elements, and the formation environment of parting is more conducive to the enrichment of rare earth elements. Rare earth elements were significantly enriched in coal ash, which was higher than the mean value of China coal, the mean value of world coal and the abundance value of upper crust. The enrichment of rare earth elements in coal ash indicates that the rare earth elements in stone coal samples are mainly found in inorganic materials. The similar enrichment ratio indicates that the occurrence of light and heavy rare earth elements is the same and the differentiation degree is similar.
Acknowledgements
This work was supported by the National Natural Science Foundation of China [No. 41802187] and [No. 41672145], the scientific research program funded by Shaanxi provincial education department [No. 18JK0521], and the program of geological research institute for coal green mining of XUST (Xi’an University of Science and Technology) [No. MTy 2019-09].