Mineralogy and Geochemistry of Nephrite Jade from Yinggelike Deposit, Altyn Tagh (Xinjiang, NW China)

: The historic Yinggelike nephrite jade deposit in the Altyn Tagh Mountains (Xinjiang, NW China) is renowned for its gem-quality nephrite with its characteristic light-yellow to greenish-yellow hue. Despite the extraordinary gemological quality and commercial signiﬁcance of the Yinggelike nephrite, little work has been done on this nephrite deposit, due to its geographic remoteness and inaccessibility. This contribution presents the ﬁrst systematic mineralogical and geochemical studies on the Yinggelike nephrite deposit. Electron probe microanalysis, X-ray ﬂuorescence (XRF) spectrometry, inductively coupled plasma mass spectrometry (ICP-MS) and isotope ratio mass spectrometry were used to measure the mineralogy, bulk-rock chemistry and stable (O and H) isotopes characteristics of samples from Yinggelike. Field investigation shows that the Yinggelike nephrite orebody occurs in the dolomitic marble near the intruding granitoids. Petrographic studies and EMPA data indicate that the nephrite is mainly composed of ﬁne-grained tremolite, with accessory pargasite, diopside, epidote, allanite, prehnite, andesine, titanite, zircon, and calcite. Geochemical studies show that all nephrite samples have low bulk-rock Fe / (Fe + Mg) values (0.02–0.05), as well as low Cr (0.81–34.68 ppm), Co (1.10–2.91 ppm), and Ni (0.52–20.15 ppm) contents. Chondrite-normalized REE patterns of most samples exhibit strong to moderate negative Eu anomalies (0.04–0.67), moderate LREE enrichments, nearly ﬂat HREE patterns, and low Σ REE contents (2.16–11.25 ppm). The nephrite samples have δ 18 O and δ D values of 5.3 to 7.4% (cid:24) and –74.9 to –86.7% (cid:24) , respectively. The mineralogy, bulk-rock chemistry, and O–H isotope characteristics are consistent with the dolomite-related nephrite classiﬁcation. Based on mineral paragenetic relationships, three possible mineral crystallization stages are recognized: (1) diopside formed by prograde metasomatism; (2) nephrite jade formed by retrograde metasomatism and replacement of Stage I anhydrous minerals; (3) hydrothermal alteration after the nephrite formation. Features of transition metal contents indicate that the color of the Yinggelike nephrite is likely to be controlled by the Fe 2 + , Fe 3 + , and Mn. Yellowish color is related to Mn and especially Fe 3 + , while greenish color is related to Fe 2 + . Our new mineralogical and geochemical results on the Yinggelike nephrite provide better constraints on the formation of other nephrite deposits in the Altyn Tagh Mountains, and can facilitate future nephrite prospecting and research in the region. epidote, allanite, prehnite, andesine, titanite, zircon, and calcite. Geochemical analyses shows that

In NW China, the giant Hetian nephrite belt extends about 1300 km from the West Kunlun Mountains to the Altyn Tagh Mountains, forming the largest nephrite belt in the world and hosting tens of important nephrite deposits. Magmatic intrusions in this belt were likely the main driving force behind the nephrite formation [16]. Compared to the many studies on the nephrite deposits in the West Kunlun [17][18][19][20][21], nephrite deposits in the Altyn Tagh have been much less investigated [37][38][39][40]. With more nephrite deposits being discovered in the recent years, the Altyn Tagh Mountains have become a major nephrite production region in China, with over half of the nephrites mined in the Qiemo and Ruoqiang Counties [40].
The Yinggelike nephrite deposit (Ruoqiang County) is famous for producing the highly valued yellow-hue nephrite, which is locally called the "Huangkou variety" (i.e., (greenish)-yellow variety). The deposit was first mined in the late Manchurian "Qing" Dynasty (early 1900s), paused for over 100 years due to geopolitical instability, and the production restarted in 2004 [41]. In recent years, the demand for and price of the high-quality yellow nephrite has increased markedly [42]. Despite the extraordinary gemological quality and commercial significance of the Yinggelike nephrite, it has not been well studied due to the geographic remoteness and inaccessibility of the deposit, including tough mountain traffic, difficult terrains, and high elevation. Previous studies only briefly introduced the geological features of the Yinggelike deposit [43,44], but no research has been carried out on the nephrite mineralogy and geochemistry of this deposit. Therefore, this study provides the first systematic geological investigation, mineralogical and geochemical analyses, with the aims of establishing the mineral crystallization stages and the gemological significance of the nephrite.
Minerals 2020, 10, x FOR PEER REVIEW 3 of 23 geological setting, mostly located at the contact between dolomitic marble and intermediate-felsic intrusion [19]. The nephrite deposits from the Shache-Yecheng, and Hetian-Yutian sections are distributed in the Kunlun Mountains, while those from Qiemo-Ruoqiang section are distributed in the Altyn Tagh Mountains (Figure 1a).
The Yinggelike nephrite deposit (Ruoqiang County) is located geologically inside the Central Altyn massif [45]. Local stratigraphy comprises mainly the Bashikuergan Group, the Altyn Tagh Group, and the Kurukesayi gneissic suite (Figure 1b) [43]. The Bashikuergan Group contains weakly metamorphosed clastic sedimentary rocks, interpreted to be Mesoproterozoic. The Paleoproterozoic Altyn Tagh Group is mainly composed of amphibolite, dolomitic marble, schist, gneiss, quartzite and mafic-ultramafic rocks. The Neoproterozoic Kurukesayi gneissic suite is a set of metamorphosed granodiorite-monzogranite-K-feldspar granite. This gneissic suite was intruded and dismembered by the locally widespread early Paleozoic granitoids. Major faults in the study area are ENE-trending. This area has likely experienced multiple orogenic processes, accompanied by multiphase and intensive tectono-magmatic activities [43].
The Yinggelike open pit is situated around 70 km south of Ruoqiang County and is more than 3200 m above sea-level. The Paleoproterozoic dolomitic marble and amphibolite of Altyn Tagh Group, and early Paleozoic granitoids are exposed in the mine (Figures 1c and 2a,b). The nephrite is found in the folded grayish-white/-black banded dolomitic marble, and is restricted by faults developed along the contact zone between dolomitic marble and granitoids (Figure 2a,b). The Yinggelike open pit is situated around 70 km south of Ruoqiang County and is more than 3200 meters above sea-level. The Paleoproterozoic dolomitic marble and amphibolite of Altyn Tagh Group, and early Paleozoic granitoids are exposed in the mine (Figures 1c and 2a,b). The nephrite is found in the folded grayish-white/-black banded dolomitic marble, and is restricted by faults developed along the contact zone between dolomitic marble and granitoids (Figure 2a,b).

Samples
Eleven nephrite samples were collected from the Yinggelike nephrite deposit, of which five (H-1, H-2, H-3, H-4, H-5) were collected from the open pit (N 38°29′26″, E 88°18′05″) and six (Q-1, Q-2, Q-3, Q-4, Q-5, Q-6) were purchased from the mine. Refractive index (RI), specific gravity (SG), and Vickers hardness of all the samples were determined. The RI and SG were examined by the distant vision method and hydrostatic weighing method, respectively, following the procedures outlined by [50,51]. The Vickers hardness was examined by the Microvickers hardness tester and converted to Mohs hardness by calculation [52]. During the hardness test, 1 kgf was used as the load value. The gemological properties are listed in Table 1.

Samples
Eleven nephrite samples were collected from the Yinggelike nephrite deposit, of which five (H-1, H-2, H-3, H-4, H-5) were collected from the open pit (N 38 • 29 26 , E 88 • 18 05 ) and six (Q-1, Q-2, Q-3, Q-4, Q-5, Q-6) were purchased from the mine. Refractive index (RI), specific gravity (SG), and Vickers hardness of all the samples were determined. The RI and SG were examined by the distant vision method and hydrostatic weighing method, respectively, following the procedures outlined by [50,51]. The Vickers hardness was examined by the Microvickers hardness tester and converted to Mohs hardness by calculation [52]. During the hardness test, 1 kgf was used as the load value. The gemological properties are listed in Table 1.

Methods
Chemical compositions of nephrite and backscattered electron (BSE) images were acquired at the Institute of Geology, Chinese Academy of Geological Sciences (CAGS) in Beijing, China, using a JXA-8100 Electron Microprobe Analyzer (EMPA). Analysis conditions included 15 kV acceleration voltage, 10 nA beam current, and 3 µm spot size. The analytical precision was ±2%. Matrix corrections were carried out using the ZAF correction program supplied by the EMPA manufacturer. The EMPA standards included: andradite for Si and Ca, rutile for Ti, corundum for Al, hematite for Fe, eskolaite for Cr, rhodonite for Mn, bunsenite for Ni, periclase for Mg, albite for Na, K-feldspar for K and barite for Ba.
Bulk-rock chemical compositions were acquired using an AXIODmAX X-ray fluorescence (XRF) spectrometer at the Hebei Institute of Regional Geology and Mineral Resources (HIRGMR) in Langfang, China. All samples were cleaned, crushed, and milled to <200 mesh with an agate mortar. Whole-rock powder samples (0.7 g) were mixed with 5.2 g Li 2 B 4 O 7 , 0.4 g LiF, 0.3 g NH 4 NO 3 (500 g/L) in a 25 mL porcelain crucible. The powder mixture was transferred to a platinum alloy crucible, and 1 mL LiBr solution was added before the sample was dried. The powder mixture was then melted in an automatic flame fusion machine at 1200 • C for 10 min and casted into glass discs for XRF analysis. Standard samples were prepared using the same procedure. The XRF operating conditions included an accelerating voltage of 30 kV (for Na-P, K, Ca), 40 kV (Ti) and 60 kV (Mn, Fe), beam current of 120 mA (for Na-P, K, Ca), 90 mA (Ti) and 60 mA (Mn, Fe) and collimators of 300 µm (for Al, Si) and 700 µm (all others). Analytical uncertainties were generally better than 1%. FeO was determined by K 2 Cr 2 O 7 titration after the samples were dissolved in HF and H 2 SO 4 .
Concentrations of trace elements (including rare earth elements (REEs)) were obtained using an X Series II inductively coupled plasma mass spectrometer (ICP-MS) at HIRGMR. The samples were ground in an agate mortar to 200 mesh. The analysis procedure followed the Silicate Rocks-Part 30as method recommended by the State Standard of the People's Republic of China (GB) [53]. The operating conditions included an analogue detector voltage of 1890 V, PC detector voltage of 2890 V, vacuum level of 2 to 2.4 mbar, scanning time of 60 s, and integration time per element of 0.5 s. The internal standard Rh was used to correct for any analytical drift and matrix effects. The standard deviations for trace elements in the blank samples varied from 0.0005 to 0.8759 and were generally less than 0.05.
Oxygen and hydrogen isotope analyses were acquired in the laboratory at the Beijing Research Institute of Uranium Geology. Nephrite samples were first crushed to <60 mesh to separate the minerals. The rare impurities were removed by hand-picking under the microscope to ensure high purity. The purified samples were then ground to 200 mesh in an agate mortar for oxygen and hydrogen isotope analyses. Oxygen was liberated from the samples by reaction with BrF 5 [54] and converted to CO 2 on a platinum-coated graphite rod. Oxygen isotope compositions were measured with a Delta V Advantage Isotope Ratio Mass Spectrometer. Analyses of GBW-04409 (quartz) during this study yielded an average δ 18 O value of 11.11% (recommended value = 11.11% ; Chinese Standard Reference Material GBW-04409) [55]. Precision of the oxygen isotope analyses is better than 0.2% . For hydrogen isotopic compositions, the samples were first degassed of labile volatiles by heating under vacuum to 120 • C for 3 h. Constitutional water was released by heating the samples to approximately 1200 • C in an induction furnace. The released water was converted to hydrogen by passage over heated zinc powder at 400 • C [56]. The hydrogen isotope compositions were analyzed using a MAT-253 Mass Spectrometer with ±2% precision. Analyses of Peking University standard water during this study gave an average δD value of -64% (recommended value = -64.8% ; Chinese Standard Reference Material PKU Standard Water) [55]. Stable isotope data for hydrogen and oxygen are reported as δD and δ 18 O per mille (% ) relative to SMOW.

Gemological Properties
The conventional gemological properties of the 11 Yinggelike nephrite samples are listed in Table 1. The nephrite samples appear similar to typical nephrites except for the color. All the samples are light-yellow to greenish-yellow with fine texture (Figures 3 and 4), and are translucent with sub-vitreous to greasy luster. Polished samples have commonly sub-vitreous luster. Their reflective index (RI) ranges from 1.60 to 1.62, and specific gravity (SG) from 2.88 to 2.96. The Mohs hardness ranges from 5.8 to 6.2. The gemological properties are similar to typical nephrite jade [23,57].

Gemological Properties
The conventional gemological properties of the 11 Yinggelike nephrite samples are listed in Table 1. The nephrite samples appear similar to typical nephrites except for the color. All the samples are light-yellow to greenish-yellow with fine texture (Figures 3 and 4), and are translucent with subvitreous to greasy luster. Polished samples have commonly sub-vitreous luster. Their reflective index (RI) ranges from 1.60 to 1.62, and specific gravity (SG) from 2.88 to 2.96. The Mohs hardness ranges from 5.8 to 6.2. The gemological properties are similar to typical nephrite jade [23,57].

Gemological Properties
The conventional gemological properties of the 11 Yinggelike nephrite samples are listed in Table 1. The nephrite samples appear similar to typical nephrites except for the color. All the samples are light-yellow to greenish-yellow with fine texture (Figures 3 and 4), and are translucent with subvitreous to greasy luster. Polished samples have commonly sub-vitreous luster. Their reflective index (RI) ranges from 1.60 to 1.62, and specific gravity (SG) from 2.88 to 2.96. The Mohs hardness ranges from 5.8 to 6.2. The gemological properties are similar to typical nephrite jade [23,57].

Tremolite
Based on the occurrence, paragenesis and chemical composition, two generations of tremolite can be classified: undeformed (Tr-I) and deformed (Tr-II). Tr-I is very rare and occurs as euhedral porphyroblasts of approximately 200 µm long and 60 µm wide (Figure 5a). Some Tr-I grains form rhombohedral pseudomorphs of carbonates (Figures 5b and 6a) and were partially replaced by Tr-II. In some cases, Tr-I grains also replaced rounded/oval diopside, and were themselves replaced by Tr-II (Figure 6b). The fine-grained, non-directional micro/cryptocrystalline Tr-II grains are the main form of tremolite in the Yinggelike nephrite ( Figure 5). Aggregates of Tr-II commonly exhibit fine fibrous-felted texture (Figure 5c).

Pargasite
Pargasite is commonly found in the Yinggelike nephrite. Some pargasite grains appeared as euhedral crystals in the nephrite, with sizes of about 400 µm in length and 260 µm in width (Figure 5d), while some grains were partially replaced by tremolite (Figure 6c,d). Pargasite also replaced diopside locally (Figure 6c), indicating that it had formed before tremolite but after diopside. It is noted that this mineral is rare in other nephrite deposits in Hetian nephrite belt [18,19,37,38]

Amphibole
According to the amphibole classification diagram (Figure 7), all the Yinggelike amphiboles belong to the calcic group, and are classified as tremolite and pargasite [58]. Tremolite is mainly composed of (in wt.%) SiO2 ( (Table  3). It is almost homogeneous, and compositionally is close to the diopside end-member [59]. The FeO and Fe2O3 contents were calculated by charge balance method.

Amphibole
According to the amphibole classification diagram (Figure 7), all the Yinggelike amphiboles belong to the calcic group, and are classified as tremolite and pargasite [58]. Tremolite is mainly composed of (in wt.%) SiO 2 ( (Table 3). It is almost homogeneous, and compositionally is close to the diopside end-member [59]. The FeO and Fe 2 O 3 contents were calculated by charge balance method.

Epidote, Allanite, Andesine, Prehnite, Titanite, Zircon, and Calcite
The chemical compositions of other minor minerals are presented in Table A1. Epidote is mainly composed of (in wt.%) SiO 2 (37.14-37.       (Table 4), which resemble theoretical tremolite end-member composition. This is in agreement with our petrographic observations that tremolite is the main   (Table 4), which resemble theoretical tremolite end-member composition. This is in agreement with our petrographic observations that tremolite is the main component in the nephrite. The Fe/(Fe + Mg) ratios are 0.02 to 0.05. The transition metal contents of the nephrite purchased from the mine are listed in Table 5. As seen in Table 5, Fe 2+ , Fe 3+ and Mn contents are generally high in all the samples, followed by Ti, whereas the V, Cr, Co, Ni, Cu contents are too low (generally <10 ppm) to have significant impact on the color. Therefore, the Fe 2+ , Fe 3+ , Mn, and Ti may play an important role in Yinggelike nephrite color.   Figure 8). Photomicrographs (Figure 5g), BSE images (Figure 6e,i) and EMPA data (Table A1) suggest that mineral inclusions such as allanite and zircon in sample H-5 have generated higher trace element (including REE) contents than in the other samples (Table A2) (Table A2).   The nephrite samples contain δ 18 O = 5.3 to 7.4% and δD = −74.9 to −86.7% , exhibiting a narrow range. Hydrogen and oxygen isotope compositions in the nephrite from Yingelike and other well-known nephrite deposits worldwide are summarized in Table 6 and illustrated in Figure 9.   Table 6 for details).

Dolomite-Related Origin
Field investigation shows that the Yinggelike nephrite orebody occurs in the dolomitic marble near the intruding granitoids (Figure 2), which suggests that the Yinggelike nephrite deposit is of a dolomite-related type. This conclusion is supported by the mineralogy, bulk-rock chemistry, and O and H isotopes characteristics of the nephrite.
From the mineralogical characteristics of nephrites of different genetic origins around the world (summarized in Table 7), major differences are present between the dolomite-related (D-type) and serpentinite-related (S-type) nephrites: the main mineral of D-type nephrites is tremolite (>95 vol.%),  Table 6 for details).

Dolomite-Related Origin
Field investigation shows that the Yinggelike nephrite orebody occurs in the dolomitic marble near the intruding granitoids (Figure 2), which suggests that the Yinggelike nephrite deposit is of a dolomite-related type. This conclusion is supported by the mineralogy, bulk-rock chemistry, and O and H isotopes characteristics of the nephrite.
As summarized by the compilation of data presented in Table 6 and Figure 9. D-type nephrites tend to have relatively low δ 18 O and δD values, and vice versa for S-type ones albeit some overlapping. The δ 18 O (5.3-7.4% ) and δD (-74.9 to -86.7% ) values of the Yinggelike nephrite fall closer to many D-type nephrite deposits (esp. Alamas, Hetian and Złoty Stok) than the S-type ones in the δ 18 O vs. δD diagram. The isotopic difference from some other D-type nephrite deposits (e.g., Chuncheon; Russia) may have been caused by different formation temperatures, fluid/rock ratios, and/or protolith isotope inheritance [25,31].
Stage I is associated with granitoid intrusion (Figure 1c). Representative mineral formed during this stage is diopside (Figure 5e). Anhydrous andesine, titanite, and zircon were probably formed at this stage (Figure 6f,h,i). The prograde metasomatic process that formed the diopside can be expressed as follows: Stage II features the formation of fine and randomly oriented tremolite fibers, which contributes to the gem-quality. This stage is related to the retrograde hydrothermal alteration, during which various mineral replacement reactions had occurred. The main formation processes are as follows: (1) The dolomitic marble was replaced by tremolite. This is a common explanation for the formation of nephrite [1].
Both tremolite Tr-I and Tr-II can be formed in the reaction presented in Equation (2). The coarsegrained Tr-I formed were likely replaced by or recrystallized into later Tr-II (Figure 5b). The lower formation temperature (plus possible rapid cooling led by meteoric fluid incursion) likely deprived Tr-II of sufficient time to crystallize, which generated its characteristic micro-/cryptocrystalline texture.
(2) Stage I diopside was partially replaced by tremolite along its grain boundary and cracks (Figure 5e), either directly by Tr-II or by Tr-I and then Tr-II (Figure 6b). This process can be expressed in the following equation: Unlike most other nephrite deposits in the Hetian nephrite belt [17][18][19][20][21], pargasite is common in the Yinggelike nephrite. In some cases, Stage I diopside was replaced by pargasite, which was in turn replaced by Tr-II (Figure 6c). The Al and Na contents in pargasite are higher than those in diopside, which indicates that the process of diopside replacement by paragasite may have been the result of Aland Na-rich hydrothermal alteration (Table 3).
We suggest that the Stage II isolated calcite grains may have been completely taken up by the formation of fine-grained Tr-II, as expressed in the following equation: 2CaCO 3 (calcite) + 5Mg 2+ + 8SiO 2 + 6H 2 O → Ca 2 Mg 5 (Si 4 O 11 ) 2 (OH) 2 (tremolite) + 10H + + 2CO 2 (4) In the above equation, the tremolite formation requires Mg, which is likely derived from the dolomitic marble wallrocks leached by hydrothermal fluids, as first proposed by [75]. With the gradual consumption of calcite and production of H + ions, the hydrothermal fluid may have become more acidic. This likely led to further carbonate decomposition and produced an excess of Ca 2+ ions, which may have formed other Ca-rich intermediate reaction products such as epidote, allanite, and prehnite (Figures 5f-g and 6e-g).
Stage III, characterized by calcite veins (Figure 5h), is related to the hydrothermal processes after nephrite formation.

Gemological Significance
The general preference of yellow color (associated with royalty) in many East Asian cultures has placed yellowish nephrite (and to a lesser extent white one, which is known "suet nephrite" in China) above nephrites of other colors [16]. Nevertheless, yellow nephrite is very rare, and is only reported in South Korea and the Qinghai and Liaoning provinces in China [22,64,76]. This makes yellow nephrite even more precious.
The factors that control the coloring of nephrites are still not fully understood, and thus we compare different yellowish-colored Yinggelike nephrite samples in this study. The colors of our samples can be broadly divided into a more greenish-yellow (Q-1, Q-2, Q-3) to a light-yellow (Q-4, Q-5, Q-6) group (Figure 4). EMPA and bulk-rock XRF/ICP-MS analyses show that all the samples were mainly composed of tremolite, and were almost free of impurities (Tables 2 and 4). Therefore, the main chromogenic mineral was tremolite. The high contents of chromogenic cations such as Fe 2+ , Fe 3+ , Mn and Ti suggest that they may be important in determining the Yinggelike nephrite color. Some workers have suggested that the green color of nephrite is mainly caused by the substitution of Fe 2+ for Mg 2+ , and the yellow color may be caused primarily by Fe 3+ and Mn [15,18,19,[77][78][79][80]. Titanium by itself is not known as a coloration factor for most terrestrial minerals, and as for nephrite, it affects the coloration of the blue-violet variety [79]. We therefore propose that Fe 2+ , Fe 3+ , and Mn are the main chromogenic factors for the nephrite. The greenish color of nephrite is related to Fe 2+ , while the yellowish color is related to Fe 3+ and Mn. In addition, the greenish-yellow group has markedly higher Fe 3+ , and moderately higher Fe 2+ and Mn contents than those of the light-yellow group, which indicates that Fe 3+ is more important in giving the yellow color than Mn.
Generally, the finer the tremolite grains, the better the jade quality. Our petrographic observations indicate that the Yinggelike nephrite consists mainly of fine-grained tremolite (especially Tr-II), the aggregates of which give the nephrite a fine and compact texture (Figure 4). The randomly oriented bundles of twisted micro-fibers in the nephrite also result in its extreme toughness (Figure 5c). This toughness, combined with a relatively high Mohs hardness (5.8-6.1) (Table 1), makes the Yingglike nephrite a precious carving material.

Conclusions
In this paper, we presented the first systematic study of field geological occurrence, mineralogy, bulk-rock chemistry, and stable (O and H) isotope characteristics of nephrite from Yinggelike deposit in the Altyn Tagh Mountains (NW China). These data contribute to the overall understanding of the Yinggelike nephrite deposit.
The nephrite is dominated by tremolite, with minor minerals such as pargasite, diopside, epidote, allanite, prehnite, andesine, titanite, zircon, and calcite. Geochemical analyses shows that the nephrite samples have low bulk-rock Fe/(Fe + Mg) values and Cr, Co, and Ni concentrations. The chondrite-normalized REE patterns of most samples exhibit strong to moderate negative Eu anomalies with moderate LREE enrichment, nearly flat HREE, and low ΣREE contents. The mineral and geochemical characteristics of Yinggelike nephrite are consistent with those of the dolomite-related ones.
Mineral paragenetic relationships define three mineral crystallization stages for the Yinggelike nephrite: (1) diopside formed by prograde metasomatism; (2) nephrite jade formed by retrograde metasomatism and replacement of Stage I anhydrous minerals; (3) hydrothermal alteration after the nephrite formation. Features of transition metal contents indicate that the color of the Yinggelike nephrite is probably controlled by Fe 2+ , Fe 3+ , and Mn. Our new mineralogical and geochemical results on the Yinggelike nephrite provide better constraints on the formation of other nephrite deposits in the Altyn Tagh Mountains, and can facilitate future nephrite prospecting and research in the region.   Eu/Eu* = 2Eu N /(Sm N + Gd N ).