Geochemical Implications of Rare Earth Elements in Terra Rossa in Tropical Karst Area: A Case Study in Northern Vietnam
by
,
Zhang Liankai
1,2, 
Ji Hongbing
3,*,
Wang Shijie
2,
Luo Gang
4,
Liu Xiuming
2,
Wei Xiao
2,5,
Nguyen QuocDinh
6 and
Nguyen DaiTrung
6 1
Key Laboratory of Karst Ecosystem and Treatment of Rocky Desertification, Institute of Karst Geology, Ministry of Natural Resources, Guilin 541004, China
2
State Key Laboratory of Environmental Geochemistry, Institute of Geochemistry, Chinese Academy of Sciences, Guiyang 550081, China
3
Civil & Environment Engineering School, University of Science and Technology Beijing, Beijing 100083, China
4
Government of Duping Town, Zhenyuan County, Qiandongnan Miao and Dong Autonomous Prefecture, Guizhou Province, Qiandongnan 522625, China
5
College of Agriculture, Guizhou University, Guiyang 550025, China
6
Vietnam Institute of Geosciences and Mineral Resources, Hanoi 100000, Vietnam
*
Author to whom correspondence should be addressed.
Appl. Sci. 2020, 10(3), 858; https://doi.org/10.3390/app10030858
Submission received: 22 December 2019
/
Revised: 15 January 2020
/
Accepted: 22 January 2020
/
Published: 26 January 2020
(This article belongs to the Section Earth Sciences)
Abstract
:Featured Application
The data and methods in this article can be used for in-depth study of terra rossa in evolution process and paleoclimate reconstruction in the tropical karst regions, creating a new field for the study of laterite and paleoclimate in karst areas that lack modern eolian deposition.
Abstract
Research on weathered crusts on carbonate rock is essential for paleoenvironmental studies in karst areas. Terra rossa, widely distributed in tropical karst areas, has not been studied in terms of its material sources and geochemistry. Two typical terra rossa profiles on dolomite (SC profile located at Sang Cai, Hoa Binh province) and limestone (TG profile located at Tong Gia, Lao Cai province) in Northern Vietnam were selected to examine the geochemical characteristics and the evolutionary processes of rare earth elements (REEs). Chondrite and bedrock normalized patterns indicated that these two profiles are in situ weathering crusts, meaning they are the residual material remaining after chemical weathering of the lower carbonate rocks. The average value of total REE in the SC profile is 381.19 ppm, which is 30 times higher than the bedrock. In the TG profile, the value is 386.26 ppm, 13 times higher than the bedrock. Compared with the profiles in nearby subtropical areas in Southeast China, the REE enrichment coefficients of terra rossa in Northern Vietnam are much higher. The REE depletion was also different between the SC and TG profiles. The light and heavy REE fractionations in the SC profile are higher than in the TG profile. Paleoclimate inversion analysis shows that the SC profile experienced a stable oxidation condition, whereas the TG profile was subjected to several reducing environments since a weathering crust formed.
1. Introduction
Terra rossa (lateritic weathering crusts) surfaces on carbonate rocks occupy an important position in karst environmental systems research [1]. These weathering crusts are regarded as an area of geochemical sensitivity and ecological vulnerability [2]. Carbonate rocks, covering approximately 15% (22 million km2) of the world’s total land area, are mainly distributed in tropical and subtropical areas, such as Southeast Asia, the Mediterranean coast, and the Southeastern region of North America [3,4]. Southeast Asia is the largest contiguous karst area on Earth [5,6]. Showing strong effects of geochemistry and pedogenesis, the karst geology, geomorphology, and lateritic weathering crusts were formed as unique geological bodies compared with non-karst regions [7].
After multi-stage development, terra rossa recorded information about paleoenvironment and paleoclimatic changes [8,9]. This information is vital for paleoclimate analysis, especially in the karst regions that lack Cenozoic sediments [10,11]. In Southeast Asia, extensive amounts of lateritic weathering crusts overlaying carbonate rocks formed an intact area of terra rossa distribution within the tropical–subtropical monsoon climatic zones. The regions thus became ideal for the formation and evolution of research on lateritic and carbonate rock weathering. Some studies focused mostly on subtropical [12,13,14] and Mediterranean regions [15,16,17]; few focused on the tropical karst areas. Although Muhs and Budahn [18] researched the sources of laterite in the tropical West Indies region, they did not conduct in-depth investigations on the lateritic geochemical evolutionary processes.
Rare earth elements (REEs) serve as tracers and indicators of sources, weathering, diagenesis, and mineralization processes in the terrestrial critical zone [19]. Their contents, total amount, and combinational patterns objectively reflect the geological body’s evolutionary process, the physical and chemical conditions, as well as the source [20,21]. As such, studies of the geochemical behavior of REEs in terra rossa can contribute to reconstructing the pedogenesis effects, weathering processes, and the supergene mineralization [22,23,24].
In this study, we selected two typical terra rossa profiles, covering dolomite and limestone, to investigate the evolutionary process of REEs in the tropical carbonate lateritic crusts to reveal their implications for environmental changes, geochemical characteristics, and elemental migration.
2. Materials and Methods
2.1. Study Area Description
Northern Vietnam is located at the intersection of two tectonic zones, the Tethys oceanic trench and Pacific Rim, and has undergone considerable uplifting and erosion [25]. The chronostratigraphic stratum here is mainly comprised of Paleozoic marine sediment that formed shale and limestone. The Indochina orogenic cycle occurred 150 million years ago, during when the geosyncline uplifted gradually. This process pushed the carbonate layer upward, which formed the karst mountains 1000–2800 m tall.
The SC profile is located at Sang Cai, Hoa Binh province, Northern Vietnam (20°46’11.35” N, 104°52’29.26” E) (Figure 1), at an altitude of 1135 m. The 400–700 m thick bedrock is gray and grayish-white dolomite under the Upper Dong Giao Formation (T2dg1). The overlay on the bedrock is yellowish-brown soil (Table 1), in which the rock–soil interface (RSI) is a grey-white powder layer 1–3 mm thick. T2dg1 formation is the main karst stratum in Northern Vietnam. It is exposed at 30°–90° and has well-developed fractures. The formations are 5–40 km wide and 400 km long, stretching from the Sino-Vietnamese border northwest of the coastal area in the east [26]. Generally, the climate is tropical monsoon, with an annual average temperature of 24 °C, which is lower than at the same latitude in Asia. The average annual rainfall is 1500–2000 mm. The summer season is usually rainy and hot, affected by the southeast monsoon.
The TG profile is located at Tong Gia, Lao Cai province (22°29’1.01” N, 104°06’57.10” E) (Figure 1); at an altitude of 128 m. The bedrock of Ha Giang Formation (Є2hg2) is comprised of marble, mottled limestone, clayish limestone, and clay-sericite schist, with a thick up to 1000 m. Red river valley stretches northwest−southeast and is known for its hot and dry features. A blackish–brown layer is found at the RSI of the TG profile.
The sampling profiles were selected from the top of a hillock sited and manually excavated next to a highway. The weathering soil layer was about 100−300 cm. Detailed information and sampling sites of the two terra rossa profiles are shown in Table 1.
2.2. Samples Collection and Analytical Methods
Samples were all collected from the top of karst mountains to avoid slope deposits. The profile samples were acquired in the upward direction from the bottom to the surface, ensuring that control samples were available for each type of weathered layer including the topsoil, lateritic, and bedrock layers. Both profiles were fresh, and the structure of the weathered layers was clear. We collected 500 g soil for each point with 20−30 cm intervals between each point (Table 1). All samples were sealed within polyethylene bags before transport to the laboratories. Then, they were air-dried and finely grinded in agate mortar into 200−mesh before analysis and dissolution [27].
The concentrations of REEs and major and trace elements were determined using acid digestion methods following the analytical procedures described by Ji et al. [28]. The chemical compounds REEs and major elements were analyzed at the China Nuclear Research Institute (CNNC) using a plasma mass spectrometer (ELEMENT XR, Thermo Scientific, Waltham, MA, USA) and fluorescence spectrophotometer (Axiosm A X, PANalytical, Almelo, Overijssel, Netherlands), respectively. The test temperature was 22.9 °C, instrument precision was <5% for trace elements and 2% for major elements, and the relative error between the sample results and recommended standard was <10%. The pH was measured as follows: 10 g of air-dried soil sample was passed through 1 mm sieve and added to a 100 mL beaker, we added 25 mL of fresh deionized water, which was then stirred thoroughly and allowed to stay for 30 min. We measured the pH of the suspension with a calibrated pH meter (ST5000, Ohaus, NJ, USA). Soil total carbon (TC) and soil organic carbon (TOC) were determined using a TOC/TN analyzer (Multi N/C3100, Jena, Jena, Thuringia, Germany) in the karst environmental testing center, Ministry of Natural Resources, China, with an analysis error was less than 0.1%.
3. Results
3.1. Concentration of REEs
The REE data and relevant parameters of the two profiles are listed in Table 2. The total REE (ΣREE) in the SC profile ranged from 313.47 to 608.95 ppm and the average value was 381.19 ppm. The ΣREE of SC bedrock was 12.65 ppm. The REE concentration was 30 times higher than in the bedrock. For the TG profile, ΣREE ranged from 281.15 to 776.56 ppm (average 386.26 ppm), which is closer to that of SC profile. The ΣREE of limestone in the TG profile was 29.237 ppm, which is significantly higher than in the dolomite stone in SC.
The ΣREE in both SC and TG profiles showed fluctuating increases from top to bottom, as shown in Figure 2. For example, at the upper layer of SC profile (from 0 to −100 cm), the ΣREE was 313.47−356.24 ppm, whereas at the weathering front (–120 cm), the value was 608.95 ppm. For the TG profile, the ΣREE in the upper layer (from 0 to –180 cm) was 281.15–347.13 ppm, reaching 776.56 ppm at RSI. This suggests that the REEs gradually leached away above the RSI and accumulated at the RSI.
The ΣLREE/ΣHREE ratio is the fractionation indicator for light REE (LREE, from La to Eu) and heavy REE (HREE, from Gd to Lu and Y). The fractionation of ΣREE in the SC profile is slightly higher than in the TG profile. In the SC profile, the ΣLREE/ΣHREE ratio ranges from 2.12 to 3.23 from topsoil to RSI (average: 2.94), showing a generally declining trend with the highest value at −100 cm (3.24), and the lowest (2.12) at −120 cm (RSI) (Figure 2). For the TG profile, the trend declined with the lowest value at the RSI (−210 cm) (Figure 2). This indicates that the leaching rate of LREE increased from top to bottom with the highest value at the RSI. The HREE gradually gathered from topsoil to bottom and peaked at the RSI. This result was confirmed at the subtropical weathering crusts covering on carbonate rocks by Nesbitt [30], Lan [31], and Sun et al. [32].
Geochemical parameters such as Ce and Eu of sedimentary rocks can be used to judge material source and sedimentary environment [21]. Normally, Ce > 0.78 is a positive anomaly, and Ce < 0.78 is a negative anomaly; Eu > 1 is a positive anomaly, and Eu < 1 is a negative anomaly [27].
Ce showed a positive anomaly at the top of the SC profile, with the δCe value ranging from 1.19 to 1.30 (average: 1.22). Its negative anomalies were lower at the weathering front of RSI, where the δCe value was 0.76. The TG profile shows that the highest positive anomaly (δCe = 1.31) was at the surface soil, with the lowest negative anomaly was at the RSI (δCe = 0.29). δEu was a relatively stable negative anomaly. The δEu values for SC were 0.68 (ranging from 0.64 to 0.71) and 0.67 in the soil and bedrock, respectively. For the TG profile, δEu was 0.63, equal to the δEu value for bedrock (Figure 3).
The specific elements ratios such as (La/Yb)N, (La/Sm)N, and (Gb/Yb)N, which can indicate the differentiation characteristics of LREE and HREE, are shown in Figure 4. The (La/Yb)N in SC profile is 4.10−8.47, with the average value of 6.87 (from 0 to −120 cm), which was lower than that of sandstone, granite, and gneiss (10.39, 7.65, and 8.17, respectively) as reported by Yang et al. [33]. The value gradually decreased along the rock layer → weathering layer → arable layer direction (Figure 4), with declining LREE from topsoil to RSI as indicated by ΣLREE/ΣHREE. The averages of (La/Sm)N and (Gb/Yb)N were 3.58 and 1.31, respectively.
In the TG profile, the (La/Yb)N varies along the rock → weathering layer → arable layer direction, reaching a maximum of 10.41 in the surface soil (Figure 4). A large differentiation occurred in the surface arable layer. (La/Yb)N, (La/Sm)N, and (Gb/Yb)N in the TG profile were 8.69, 3.80, and 1.59, respectively. Those three ratios decreasing from surface to bottom indicate that LREE leached and HREE accumulated gradually from topsoil to the RSI.
3.2. Comparison with Other Geological Bodies and Profiles
Table 3 provides the REE content in different rocks, sediments, and soils on the Earth. Compared with these geological bodies and profiles, the REEs in bedrocks of dolomite and limestone in Northern Vietnam are one-half or one-third of that in weathering crust. The ΣREE in Northern Vietnam profiles was basically the same as in the subtropical profiles. The enrichment factors (EFs) of REEs in Northern Vietnam profiles were 1.5 to 2.0 times those of the subtropical karst profiles. At the RSI of Vietnam profiles, the EFs were much higher, accounting to 2.5 to 3.3 times that of Chinese subtropical profiles. Compared with the loess, marine sediment, and fluvial lacustrine deposits around the world, the ΣREE in SC and TG profile were two times higher than those geological bodies as shown in Table 3.
3.3. Normalized REE Distribution Patterns
The C1 chondrite-normalized pattern, which smooths the elements distribution curve and enables comparison with the standard sample, is often used to eliminate the jaggedness of the REE odd−even effect that occurs during weathering process [30,31,37,38,39,40]. The C1 chondrite-normalized REE distribution patterns are shown in Figure 5. The curves of these two profiles exhibited the same models: both soil and bedrocks tilted to the right and relatively flat after Sm. This indicates that LREE are enriched in the profile, whereas HREE are relatively deficient. All REE distribution patterns showed relatively tendencies in bedrock, RSI, and surface soil. This trend reflected the inheritance of crusts materials from bedrock. Two profiles expressed the V-shaped troughs for Sm anomalies, indicating negative Sm anomalies in each layer of both SC and TG profile. Ce displayed a disordered appearance, generally, showing V-type negative anomalies and nearly positive anomalies at the RSI. All elements’ C1 chondrite-normalized lines in profiles were higher than Vietnam bedrock chondrite-normalized lines (SC01 and TG01). Therefore, the tropical carbonate weathering crusts always have a high REE accumulative effect.
In the bedrock-normalized REE distribution pattern (Figure 6), the weathering crust showed significant REE enrichment. The ΣREE was more than 10 times higher than in the bedrock. The curves showed the same tendency from RSI to topsoil. The SC showed a right-out characteristic, which means LREE enrichment and HREE loss. Ce presented a positive Ce anomaly valley in both SC and TG profiles. The REE in RSI showed extremely high and fluctuating changes.
4. Discussion
4.1. Supergene Enrichment of REE
4.1.1. Enrichment of REE in Terra Rossa in Northern Vietnam
REE supergene enrichment under the weathering process had been widely reported on laterite overlaying granite, basalt, and alkaline rocks [41,42,43,44]. Some studies focused on the carbonate rock weathering crusts in subtropical areas [32,45], but few had been conducted on tropical terra rossa [13,14,24,46].
To identify the main factors that affect the enrichment of REE in Northern Vietnam, we analyzed the correlation between REE and major elements. The results are shown in Table 4. REE, LREE, and HREE are extremely significantly and positively correlated with Al2O3, Fe2O3, TiO2, and Zr, and especially with Fe. The correlation with CaO and MgO was negative, especially with SiO2. This indicates that the content of REE in the study area is controlled by SiO2, Al2O3, Fe2O3, TiO2, and Zr, etc. The laterite profile of SC and TG profiles experienced the aluminum-rich and desilication stage, during which the Si was lost, and Fe and Al were enriched. At this stage, rare earth elements were co-deposited with Al and Fe.
Rare earth minerals are generally thought to mainly exist in three forms: in mineral lattice in the form of ionic compounds, such as monazite, fluorocarbon, REE–phosphates, and REE–carbonates; dispersed in impure minerals in the form of isomorphs, such as apatite and fluorite; and adsorbed on the surface of some minerals in an ionic state, such as clay minerals and mica minerals [33].
The main clay minerals in the red soil of Northern Vietnam include illite, kaolinite, chlorite, vermiculite, montmorillonite, plagioclase, potassium feldspar and goethite (discussed separately). According to the analysis of the correlation between REEs and major elements, REEs are adsorbed in clay minerals in an ionic state at the end of weathering. REEs are thought to be mainly adsorbed in kaolinite, chlorite, montmorillonite, and goethite. REEs have a strong correlation with TiO2 and Zr, indicating that REEs may occur in minerals containing Ti and Zr in the form of cerium niobium perovskite, titanium–uranium, ilmenite, zircon, rutile, spinel, etc.
4.1.2. Effects of Organic Matter and pH on REE Enrichment
The TC and TOC contents in both profiles were low (Table 2). The average TC and TOC value in both profiles was less than 1%. In the topsoil, the TC and TOC were significantly high, related to the vegetation and abundant sources of organic carbon on the surface. The high values of TC and TOC at the RSI may due to the gathering of water and nutrient elements here, creating a suitable environment for microorganism growth. However, it was not observed potentially.
The correlation between organic carbon and REEs is generally insignificant. However, with the increase in atomic radius, the hydrating ion radii of REEs increase gradually, and the coordination ability with inorganic and organic acid ions strengthens, and the migration ability increases [47]. Complexes formed by HREE with some inorganic and organic complexes, such as bicarbonate, phosphate, and humic acids, are generally much more stable than the complexes formed by LREE [48].
The REE concentration coefficient in Figure 7 shows that the laterite profile on Vietnam carbonate rocks had strong REE enrichment ability, especially at the RSI, depicting a single peak curve for the SC profile. However, in the TG profile, two more weak peaks were observed at −90 and −150 cm in addition to the RSI peak, depicting a multi-peak curve (except for Ce) (Figure 7). Sun et al. [32] reported that a narrow and mutated alkaline barrier formed during the formation of residual soils (early stage of weathering). This barrier can effectively facilitate REE adsorption by clay minerals to form an enrichment peak. The pH of these two profiles showed weak acidity, significantly lower than that of the crust over carbonate rocks in subtropical areas in Southern China, where the average pH is 6.2 [32]. The maximum pH values in these two profiles appeared at the RSI, but with two more peaks at −60 and −90 cm in TG profile, which correspond to the peak accumulation of REE
Studies have shown that rare earth elements (except Ce) are significantly correlated with pH, and the correlation coefficient decreases with increasing atomic coefficient [49]. In this study, the correlation coefficients between REE from La to Lu and pH ranged from 0.656 to 0.639. The correlation between LREE and pH was higher than HREE. On the one hand, the pH value directly affects the solubility of REE and changes their migration behavior. The pH value can also influence the activity of iron and manganese oxides. Within the pH range of the soil, the protons of hydroxyl groups on the surface of iron and manganese oxides are easily dissociated and are thus prone to obligate adsorption with REE [50].
4.2. Differentiation Effect and Paleo-Environmental Evolution
4.2.1. Differentiation Effect
The differentiation of LREE and HREE in both SC and TG profiles showed a LREE loss and HREE aggregation from topsoil to RSI, as shown in Table 2. The two reasons for the REE differentiation are: firstly, the leaching solution from upper layer was adsorbed and filtered by the clay layer, during which the LREE was absorbed; secondly, the stability of the complexes combined with the high concentration of CO3- can form relatively stable complex with REEs, and this stability increased with increasing elements ordinal number. Therefore, the HREE removed with weathering fluid was deposited at the RSI, resulting in enrichment of HREE [51].
More LREEs were lost much more in the SC profile than in the TG profile. The SC location has a stable tropical monsoon climate that is high in temperature and precipitation due to the influence of the southeast and southwest monsoons from the Pacific and Indian Oceans. Although the differentiation of REEs was small, the content of REE contents in weathering crusts were different (Table 2).
4.2.2. Differentiation Between δCe and δEu and Significance of Paleo-Environment
Besides LREE and HREE, the geochemical parameters δCe and δEu showed obvious differentiation (Figure 3). Generally, Ce consists of Ce3+ and Ce4+ under oxidizing conditions. The latter is prone to hydrolysis and precipitates after adsorption by Fe and Mn oxides, then separates from the other REEs. This effect leads to a deficit of Ce. A δCe value of 0.78 is generally adopted as the reference value to denote a redox environment [52]. Eu has two valence states: Eu2+ and Eu3+. The former can be oxidized to become the latter under alkaline oxidizing conditions. The reverse process can occur under strongly acidic and reducing conditions. Positive and negative anomalies occur when δEu > 1 and δEu < 1, respectively [53].
The weathering profile of SC profile basically showed the stable positive abnormal process of Ce, indicating that the external REDOX environment remained stable during the weathering process since the profile was formed. The differentiation process of the TG profile was complicated. First, significant positive anomalies exist in the top of the profile, which may be related to the strong oxidation of surface tillage soil under tilling. Some studies suggested that abundant organic matter (humic acid) on the surface may also contribute to the formation of positive Ce anomalies on the surface, as the complexation of humic acid with Ce is significantly stronger than that of other REEs [54]. According to the fluctuation process of Ce in the TG profile and its negative anomaly, the weathered TG limestone profile experienced several relatively reductive climatic environments.
Ce in the SC and TG profiles showed a positive anomaly at the upper layer, but a negative anomaly in the lower layer. In the oxidation environment, Ce was oxidized into Ce4+, and then hydrolyzed and formed undissolved hydroxide. The weak acid condition accelerated the process because H+ has a catalytic effect on Ce4+ aggregation [55]. Therefore, the Ce in upper profile has a positive anomaly and less Ce leached downward. The RSI has an extremely negative anomaly interface for Ce.
Zhang et al. [56] found that the layer of the RSI was the location with a reductive environment that experienced long-term groundwater erosion, which is why the Ce has a positive anomaly in the upper section and a negative Ce anomaly in the lower section. The fluctuation of Ce in the TG weathering profile indicates the abrupt transition of the REDOX environment in the TG profile.
4.2.3. Environmental Significance of Y and Ho
Y and Ho have the same trivalent ionic radii, so they show the same geochemical behavior [57]. Under the processes of weathering, river transport, and marine deposit, Y and Ho would be significantly fractionated. The complex ability of Ho to coordinate with organic material or HCO3− is greater than that of Y, and Y shows a stronger tendency to adsorb on solid particles in water–rock interactions [28].
The ratios of Y/Ho in the SC and TG profiles both increased with depth (Figure 8). However, the ratio of Y/Ho was significantly different from that of the bedrock. For example, the Y/Ho ratio in SC was higher than in bedrock, indicating that Ho leached in the SC laterite, whereas this ratio in the TG profile was lower than in the bedrock, indicating Y leached significantly. The high concentrations of organic matter and high HCO3− in the SC caused the Ho to complex together with organic matter and HCO3−. The climate of the SC profile was hot and rainy, and the water−rock interactions were much stronger than those of the TG profile, which further exacerbated the ratio of Y/Ho. Compared with the SC profile, the Y-leaching effect in TG was significantly greater due to the dry and hot weather around SC.
5. Conclusions
Two typical weathering profiles developed on dolomite and limestone were the object of this study and our conclusions are summarized as follows:
Both SC and TG normalized weathering profiles patterns demonstrate an inheritance relationship with the bedrock. This suggests that the upper soil materials formed from the underlying carbonate rocks. The loss of distribution patterns in the upper profile and deposited at the RSI was the same as Chinese southeast subtropical carbonate rock weathering profiles. However, the enrichment factors of SC and TG profile were higher than in China. The laterization in SC was somewhat higher than in the TG profile due to the stable and high temperature oxidation environment in the SC profile. The variation of REE concentration with depth showed a single peak curve in SC, but a multi-peak curve (except for Ce) in the TG profile. The different distribution patterns of SC and TG profiles were closely related with the climate environment: the SC profile had a high temperature and rainy climate, whereas the climate for the TG profile was high temperature and dry climate. The fractionation of ΣHREE/ΣLREE, Y/Ho, and the differentiation in δCe also suggested that the SC profile had a stable redox environment since the weathering process formation, whereas the TG profile experienced several relatively reducing climatic environments.
Author Contributions
All authors have read and agreed to the published version of the manuscript. Conceptualization, J.H. and W.S.; methodology, J.H. and Z.L.; software, W.X. and L.G.; validation, J.H.; formal analysis, L.X.; investigation, Z.L., J.H., L.X., L.G., W.X., N.D., N.Q.; data curation, Z.L.; writing—original draft preparation, Z.L.; supervision, J.H.; funding acquisition, J.H. and W.S.
Funding
This project was supported by the National Basic Research Program (2013CB956700) and Natural Science Foundation of China (41473122).
Acknowledgments
We would like to express our gratitude for the invaluable assistance from Tran Minh Thuan from the Vietnam Institute of Geosciences and Mineral Resources during the fieldwork of our study.
Conflicts of Interest
The authors declare no conflict of interest.
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Figure 1.
The simplified stratigraphic sketch of the SC dolomite and TG limestone (located at Sang Cai, Hoa Binh province and located at Tong Gia, Lao Cai province, respectively, showing the location of the numbered sampling points. 1, plow layer; 2, terra rossa; 3, rock−soil interface (RSI) of dolomite rock (blackish-brown chocolate layer); 4, RSI of limestone (grey-white powder layer); 5, dolomite; 6, limestone; 7, sampling point.
Figure 1.
The simplified stratigraphic sketch of the SC dolomite and TG limestone (located at Sang Cai, Hoa Binh province and located at Tong Gia, Lao Cai province, respectively, showing the location of the numbered sampling points. 1, plow layer; 2, terra rossa; 3, rock−soil interface (RSI) of dolomite rock (blackish-brown chocolate layer); 4, RSI of limestone (grey-white powder layer); 5, dolomite; 6, limestone; 7, sampling point.
Figure 2.
Variation curve of ΣREE (the sum of REEs), ΣLREE (the sum of light REE from La to Eu), ΣHREE (the sum of heavy REE from Gd to Lu and Y), and the ratios of ΣLREE/ΣHREE with depth in SC and TG profiles. UL, RSI, DLM, and LMS denote upper layer, rock–soil interface, dolomite, and limestone, respectively. LREE and HREE denote the light REE and heavy REE as illustrated in Table 2.
Figure 2.
Variation curve of ΣREE (the sum of REEs), ΣLREE (the sum of light REE from La to Eu), ΣHREE (the sum of heavy REE from Gd to Lu and Y), and the ratios of ΣLREE/ΣHREE with depth in SC and TG profiles. UL, RSI, DLM, and LMS denote upper layer, rock–soil interface, dolomite, and limestone, respectively. LREE and HREE denote the light REE and heavy REE as illustrated in Table 2.
Figure 3.
Variation curves of δCe and δEu with depth in SC and TG profiles. δCe > 1 indicates a positive anomaly; δCe < 1 indicates negative anomaly. The same applied to Eu.
Figure 3.
Variation curves of δCe and δEu with depth in SC and TG profiles. δCe > 1 indicates a positive anomaly; δCe < 1 indicates negative anomaly. The same applied to Eu.
Figure 4.
The variation of (La/Yb)N, (La/Sm)N, and (Gb/Yb)N in SC and TG profiles. AL1, average line of (La/Yb)N from RSI to the top soil in SC profile; AL2, average line of (La/Yb)N from RSI to top soil in TG profile; P1, average point of (La/Yb)N in granite; P2, average point of (La/Yb)N in gneiss; P3, average point of (La/Yb)N in sandstone. The average data of (La/Yb)N in granite, gneiss, and sandstone were cited from Yang et al. [33].
Figure 4.
The variation of (La/Yb)N, (La/Sm)N, and (Gb/Yb)N in SC and TG profiles. AL1, average line of (La/Yb)N from RSI to the top soil in SC profile; AL2, average line of (La/Yb)N from RSI to top soil in TG profile; P1, average point of (La/Yb)N in granite; P2, average point of (La/Yb)N in gneiss; P3, average point of (La/Yb)N in sandstone. The average data of (La/Yb)N in granite, gneiss, and sandstone were cited from Yang et al. [33].
Figure 5.
C1 Chondrite-normalized REE patterns of samples of the SC and TG profiles. The concentration was normalized to Chondrite after Taylor and Mclennan [22].
Figure 5.
C1 Chondrite-normalized REE patterns of samples of the SC and TG profiles. The concentration was normalized to Chondrite after Taylor and Mclennan [22].
Figure 6.
Bedrock-normalized REE distribution patterns for samples from the SC and the TG profiles.
Figure 7.
The variation of REEs and pH with depth in (A) SC and (B) TG profiles.
Figure 8.
Variation of Y/Ho ratio with the depth in the (A) SC and (B) TG profiles. The soil layers were the same as described in Figure 7 and Table 1.
Table 1.
Detailed information and sampling sites of the two typical laterite profiles*.
| Layer | SC Profile | H (cm) | No. | TG Profile | H (cm) | No. |
|---|---|---|---|---|---|---|
| A | Blackish–brown topsoil layer | 0 | SC08 | Dark−gray topsoil layer | 0 | TG08 |
| Yellowish−brown soil layer | −20 | SC07 | Yellow soil layer | −30 | TG07 | |
| Yellowish−brown soil layer | −40 | SC06 | Yellowish−brown soil layer | −90 | TG06 | |
| B | Yellowish−brown soil layer | −60 | SC05 | Yellowish−brown soil layer | −120 | TG05 |
| Yellowish−brown soil layer | −80 | SC04 | Yellowish−brown soil layer | −150 | TG04 | |
| Yellowish−brown soil layer | −100 | SC03 | Yellowish−brown soil layer | −180 | TG03 | |
| Grey-white powder layer | −120 | SC02 | Blackish–brown layer | −210 | TG02 | |
| C | Dolomite | −130 | SC01 | Limestone | −240 | TG01 |
* A, B, and C are the soil genetic layers, corresponding to the topsoil, eluvial horizon, and bedrock, respectively; H, the depth of profile and its sampling points; SC and TG profiles are the dolomite and limestone weathered profiles in Northern Vietnam.
Table 2.
The rare earth element (REE) concentration (ppm) and the parameters in bulk samples from the SC and TG profiles *.
Table 2.
The rare earth element (REE) concentration (ppm) and the parameters in bulk samples from the SC and TG profiles *.
| Profile | SC | TG | ||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| No. | SC08 | SC07 | SC06 | SC05 | SC04 | SC03 | SC02 | SC01 | TG08 | TG07 | TG06 | TG05 | TG04 | TG03 | TG02 | TG01 |
| Depth(cm) | 0 | −20 | −40 | −60 | −80 | −100 | −120 | −130 | 0 | −30 | −90 | −120 | −150 | −180 | −210 | −240 |
| La | 57.0 | 52.7 | 48.1 | 51.3 | 58.6 | 65.3 | 103 | 2.08 | 57.4 | 56.4 | 69.5 | 56.8 | 67.0 | 51.8 | 133 | 8.11 |
| Ce | 133 | 127 | 122 | 120 | 132 | 147 | 157 | 3.94 | 141 | 96.4 | 94.2 | 113 | 106 | 85.9 | 80.8 | 7.74 |
| Pr | 12.7 | 11.6 | 11.0 | 11.6 | 13.1 | 14.1 | 25.0 | 0.48 | 12.1 | 12.0 | 14.9 | 12.1 | 14.7 | 11.4 | 34.3 | 1.25 |
| Nd | 50.9 | 45.9 | 44.4 | 46.0 | 52.0 | 55.8 | 103 | 1.92 | 47.0 | 46.5 | 58.6 | 47.6 | 57.2 | 43.5 | 134 | 4.58 |
| Sm | 10.4 | 9.03 | 9.20 | 9.12 | 10.0 | 10.8 | 21.7 | 0.38 | 8.96 | 8.81 | 11.4 | 9.54 | 11.3 | 8.65 | 30.0 | 0.80 |
| Eu | 2.25 | 1.95 | 1.98 | 1.87 | 2.16 | 2.25 | 4.44 | 0.08 | 1.73 | 1.71 | 2.19 | 1.94 | 2.14 | 1.68 | 6.68 | 0.15 |
| Gd | 9.37 | 8.12 | 7.99 | 8.62 | 10.0 | 9.52 | 19.7 | 0.40 | 8.56 | 8.36 | 9.98 | 8.60 | 10.2 | 8.10 | 32.0 | 0.66 |
| Tb | 1.85 | 1.63 | 1.54 | 1.56 | 1.77 | 1.73 | 3.96 | 0.07 | 1.47 | 1.52 | 1.77 | 1.72 | 1.86 | 1.49 | 6.76 | 0.11 |
| Dy | 9.91 | 8.84 | 8.47 | 8.87 | 9.64 | 10.2 | 21.8 | 0.38 | 7.69 | 8.06 | 9.69 | 8.92 | 9.71 | 8.18 | 37.2 | 0.68 |
| Ho | 2.05 | 1.77 | 1.83 | 1.78 | 1.93 | 2.05 | 4.09 | 0.09 | 1.54 | 1.53 | 1.87 | 1.75 | 1.96 | 1.62 | 7.56 | 0.12 |
| Er | 6.26 | 5.35 | 5.15 | 5.09 | 5.81 | 5.67 | 12.0 | 0.23 | 4.70 | 4.64 | 5.51 | 4.66 | 5.34 | 4.75 | 20.4 | 0.31 |
| Tm | 1.07 | 0.97 | 0.96 | 0.92 | 1.01 | 1.11 | 1.92 | 0.05 | 0.73 | 0.84 | 0.88 | 0.91 | 0.98 | 0.77 | 3.34 | 0.05 |
| Yb | 6.50 | 5.35 | 5.46 | 5.12 | 5.98 | 6.15 | 11.2 | 0.36 | 4.35 | 4.38 | 5.29 | 4.65 | 5.13 | 4.20 | 16.6 | 0.34 |
| Lu | 1.18 | 0.97 | 1.09 | 1.00 | 1.06 | 1.03 | 2.14 | 0.05 | 0.76 | 0.80 | 0.88 | 0.79 | 0.91 | 0.72 | 2.92 | 0.07 |
| Y | 51.8 | 45.7 | 44.3 | 45.6 | 52.8 | 53.8 | 118 | 2.15 | 43.0 | 43.9 | 52.8 | 49.7 | 52.7 | 48.4 | 231 | 4.26 |
| ƩREE | 356 | 327 | 313 | 318 | 358 | 387 | 609 | 12.7 | 341 | 296 | 339 | 323 | 347 | 281 | 777 | 29.2 |
| ΣLREE | 266 | 248 | 237 | 240 | 268 | 295 | 414 | 8.88 | 268 | 222 | 251 | 241 | 258 | 203 | 419 | 22.6 |
| ΣHREE | 90.0 | 78.7 | 76.8 | 78.6 | 90.0 | 91.3 | 195 | 3.77 | 72.8 | 74.0 | 88.7 | 81.7 | 88.8 | 78.2 | 358 | 6.61 |
| ƩLREE/ƩREE | 74.7 | 75.9 | 75.5 | 75.3 | 74.9 | 76.4 | 68.0 | 70.2 | 78.7 | 75.0 | 73.9 | 74.7 | 74.4 | 72.2 | 53.9 | 77.4 |
| ΣLREE/ΣHREE | 2.96 | 3.15 | 3.08 | 3.05 | 2.98 | 3.24 | 2.13 | 2.35 | 3.68 | 3.00 | 2.83 | 2.95 | 2.91 | 2.59 | 1.17 | 3.42 |
| (La/Yb)N | 6.29 | 7.07 | 6.32 | 7.19 | 7.03 | 7.62 | 6.60 | 4.19 | 9.47 | 9.24 | 9.42 | 8.76 | 9.37 | 8.85 | 5.75 | 17.2 |
| (La/Sm)N | 3.54 | 3.77 | 3.38 | 3.63 | 3.79 | 3.90 | 3.06 | 3.56 | 4.14 | 4.13 | 3.94 | 3.84 | 3.83 | 3.87 | 2.86 | 6.57 |
| (Gb/Yb)N | 1.19 | 1.26 | 1.21 | 1.39 | 1.38 | 1.28 | 1.46 | 0.93 | 1.63 | 1.58 | 1.56 | 1.53 | 1.64 | 1.60 | 1.59 | 1.63 |
| δCe | 1.21 | 1.26 | 1.30 | 1.21 | 1.17 | 1.19 | 0.76 | 0.97 | 1.31 | 0.91 | 0.72 | 1.06 | 0.83 | 0.87 | 0.29 | 0.60 |
| δEu | 0.70 | 0.70 | 0.71 | 0.64 | 0.66 | 0.68 | 0.66 | 0.66 | 0.60 | 0.61 | 0.63 | 0.65 | 0.61 | 0.61 | 0.66 | 0.63 |
| TC(%) | 1.4 | 0.74 | 0.58 | 0.59 | 0.48 | 0.99 | 1.75 | --- | 2.12 | 0.36 | 0.28 | 0.2 | 0.15 | 0.15 | 0.43 | --- |
| TOC(%) | 1.31 | 0.49 | 0.43 | 0.51 | 0.36 | 0.59 | 1 | --- | 2.1 | 0.31 | 0.23 | 0.14 | 0.1 | 0.1 | 0.42 | --- |
| TOC/TC | 0.94 | 0.66 | 0.74 | 0.86 | 0.75 | 0.6 | 0.57 | --- | 0.99 | 0.86 | 0.82 | 0.7 | 0.67 | 0.67 | 0.98 | --- |
* Note: ΣREE, the sum of elements from La to Lu; ΣLREE, the sum of light REEs from La to Eu; ΣHREE is the sum of heavy REEs from Gd to Lu and Y; (La/Yb)N = (La/LaN)/(Yb/YbN); (La/Sm)N = (La/LaN)/(Sm/SmN); (Gb/Yb)N = (Gb/GbN)/(Yb/YbN); δCe = (Ce/CeN)/((La/LaN)/(Pr/PrN))0.5; δEu = (Eu/EuN)/((Sm/SmN)/(Gd/GdN))0.5; N, the standard value of chondrite as reported in the literature [29]; ---, not detected.
Table 3.
Comparison of REE concentration (ppm) in different rocks, sediments, and soils on the Earth*.
Table 3.
Comparison of REE concentration (ppm) in different rocks, sediments, and soils on the Earth*.
| Elements | La | Ce | Pr | Nd | Sm | Eu | Gd | Tb | Dy | Ho | Er | Tm | Yb | Lu | ƩREE | References |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Loess | 32.3 | 67.4 | 7.00 | 28.8 | 5.70 | 12.7 | 4.60 | 0.80 | 4.40 | 0.90 | 2.60 | 0.40 | 2.60 | 0.40 | 194 | [22] |
| QS | 41.0 | 83.0 | 9.70 | 32.0 | 6.40 | 1.20 | 5.60 | 1.00 | 5.40 | 1.60 | 3.80 | 0.60 | 3.60 | 0.70 | 196 | [34] |
| UCC | 30.0 | 60.0 | 8.20 | 28.0 | 6.00 | 1.20 | 5.40 | 0.90 | 3.00 | 1.20 | 2.80 | 0.50 | 3.00 | 0.50 | 184 | [35] |
| LE | 16.4 | 30.8 | 3.70 | 17.8 | 2.90 | 0.60 | 2.90 | 0.40 | 2.50 | 0.40 | 1.00 | 0.20 | 1.30 | 0.20 | 92.0 | [36] |
| DSC | 6.90 | 5.40 | 3.40 | 4.60 | 2.00 | 1.20 | 1.90 | 0.90 | 1.30 | 0.60 | 0.80 | 0.50 | 0.70 | 0.40 | 31.0 | [14,27,32] |
| LSC | 11.3 | 15.5 | 4.80 | 7.10 | 2.50 | 0.90 | 1.70 | 0.80 | 1.30 | 0.60 | 0.80 | 0.40 | 0.70 | 0.40 | 49.0 | [14,27,32] |
| PDC | 101 | 172 | 34.0 | 138 | 36.0 | 7.00 | 25.0 | 5.00 | 21.0 | 4.00 | 10.0 | 2.00 | 11.0 | 2.00 | 566 | [14,27,32] |
| PLC | 83.0 | 121.6 | 22.0 | 87.1 | 19.2 | 4.10 | 18.2 | 2.70 | 15.7 | 2.90 | 7.80 | 1.10 | 6.60 | 0.90 | 393 | [14,27,32] |
| DNV | 2.08 | 3.94 | 0.48 | 1.92 | 0.38 | 0.08 | 0.4 | 0.07 | 0.38 | 0.09 | 0.23 | 0.05 | 0.36 | 0.05 | 12.7 | this research |
| LNV | 8.11 | 7.74 | 1.25 | 4.58 | 0.8 | 0.15 | 0.66 | 0.11 | 0.68 | 0.12 | 0.31 | 0.05 | 0.34 | 0.07 | 29.2 | this research |
| PDV | 62.3 | 134 | 14.2 | 56.9 | 11.5 | 2.41 | 10.5 | 2.01 | 11.1 | 2.21 | 6.48 | 1.13 | 6.53 | 1.21 | 381 | this research |
| PLV | 70.3 | 102 | 15.9 | 62.1 | 12.7 | 2.58 | 12.3 | 2.37 | 12.8 | 2.55 | 7.14 | 1.21 | 6.37 | 1.11 | 386 | this research |
* UCC, upper continental crust [35]; QS, quaternary sediments; LE, lithosphere on the Earth; DSC, dolomite in China; LSC, limestone in China; PLC, profile on limestone in Southern China; PDC, profile on dolomite in Southern China; DNV, dolomite in Northern Vietnam; LNV, limestone in Northern Vietnam; PDV, profile on dolomite in Northern Vietnam; PLV, profile on limestone in Northern Vietnam.
Table 4.
Correlation analysis of REE and major elements.
| REE | LREE | HREE | SiO2 | Al2O3 | Fe2O3 | MgO | CaO | Na2O | K2O | MnO | TiO2 | P2O5 | FeO | Zr | |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| REE | 1 | ||||||||||||||
| LREE | 0.999 ** | 1 | |||||||||||||
| HREE | 0.974 ** | 0.966 ** | 1 | ||||||||||||
| SiO2 | −0.818 ** | −0.814 ** | −0.827 ** | 1 | |||||||||||
| Al2O3 | 0.782 ** | 0.779 ** | 0.783 ** | −0.947 ** | 1 | ||||||||||
| Fe2O3 | 0.810 ** | 0.797 ** | 0.874 ** | −0.886 ** | 1 | ||||||||||
| MgO | −0.197 | −0.184 | −0.285 | 0.237 | −0.247 | −0.503 | 1 | ||||||||
| CaO | −0.033 | −0.011 | −0.186 | 0.182 | −0.225 | −0.342 | 0.108 | 1 | |||||||
| Na2O | −0.326 | −0.317 | −0.377 | 0.411 | −0.456 | −0.279 | 0.040 | 0.604 | 1 | ||||||
| K2O | −0.530 | −0.518 | −0.595 * | 0.759 ** | −0.700 * | −0.719 ** | 0.569 | 0.141 | 0.290 * | 1 | |||||
| MnO | −0.541 | −0.527 | −0.621 * | 0.566 | −0.487 | −0.647 * | 0.575 | 0.246 | 0.407 * | 0.629 | 1 | ||||
| TiO2 | 0.741 ** | 0.728 ** | 0.810 ** | −0.847 ** | 0.711 ** | 0.915 ** | −0.501 ** | −0.280 ** | −0.303 ** | −0.816 ** | −0.732 ** | 1 | |||
| P2O5 | −0.277 | −0.273 | −0.304 | 0.292 | −0.365 | −0.171 | −0.274 | 0.650 ** | 0.837 ** | 0.040 ** | 0.291 ** | −0.100 ** | 1 | ||
| FeO | 0.067 | 0.067 ** | 0.067 ** | 0.065 | −0.410 ** | 0.180 ** | 0.184 ** | −0.010 ** | −0.223 | −0.394 ** | −0.320 ** | 0.409 ** | −0.127 ** | 1 | |
| Zr | 0.860 ** | 0.852 ** | 0.889 ** | −0.937 | 0.861 ** | 0.971 ** | −0.434 ** | −0.225 ** | −0.295 ** | −0.768 | 0−.665 ** | 0.929 ** | −0.198 ** | 0.329 * | 1 |
Note: The correlation analysis was based on 76 samples; * significant correlation at 0.05 level; ** significant correlation at 0.01 level.
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Liankai, Z.; Hongbing, J.; Shijie, W.; Gang, L.; Xiuming, L.; Xiao, W.; QuocDinh, N.; DaiTrung, N. Geochemical Implications of Rare Earth Elements in Terra Rossa in Tropical Karst Area: A Case Study in Northern Vietnam. Appl. Sci. 2020, 10, 858. https://doi.org/10.3390/app10030858
AMA Style
Liankai Z, Hongbing J, Shijie W, Gang L, Xiuming L, Xiao W, QuocDinh N, DaiTrung N. Geochemical Implications of Rare Earth Elements in Terra Rossa in Tropical Karst Area: A Case Study in Northern Vietnam. Applied Sciences. 2020; 10(3):858. https://doi.org/10.3390/app10030858
Chicago/Turabian StyleLiankai, Zhang, Ji Hongbing, Wang Shijie, Luo Gang, Liu Xiuming, Wei Xiao, Nguyen QuocDinh, and Nguyen DaiTrung. 2020. "Geochemical Implications of Rare Earth Elements in Terra Rossa in Tropical Karst Area: A Case Study in Northern Vietnam" Applied Sciences 10, no. 3: 858. https://doi.org/10.3390/app10030858
APA StyleLiankai, Z., Hongbing, J., Shijie, W., Gang, L., Xiuming, L., Xiao, W., QuocDinh, N., & DaiTrung, N. (2020). Geochemical Implications of Rare Earth Elements in Terra Rossa in Tropical Karst Area: A Case Study in Northern Vietnam. Applied Sciences, 10(3), 858. https://doi.org/10.3390/app10030858
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