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The Formation and Transformation of Manganese Oxide Minerals on the Surface of Kaolinite

Published online by Cambridge University Press:  01 January 2024

Fan Zhao
Affiliation:
Anhui Province Key Lab of Farmland Ecological Conservation and Pollution Prevention, Key Laboratory of JiangHuai Arable Land Resources Protection and Eco-Restoration, College of Resources and Environment, Anhui Agricultural University, Hefei 230036, China
Guangyao Zhang
Affiliation:
Anhui Province Key Lab of Farmland Ecological Conservation and Pollution Prevention, Key Laboratory of JiangHuai Arable Land Resources Protection and Eco-Restoration, College of Resources and Environment, Anhui Agricultural University, Hefei 230036, China
Yong Jiang
Affiliation:
Anhui Province Key Lab of Farmland Ecological Conservation and Pollution Prevention, Key Laboratory of JiangHuai Arable Land Resources Protection and Eco-Restoration, College of Resources and Environment, Anhui Agricultural University, Hefei 230036, China
Hui Wang
Affiliation:
Soil and Fertilizer Institute, Anhui Academy of Agricultural Sciences, Hefei 230031, China
Chi Cao
Affiliation:
Anhui Province Key Lab of Farmland Ecological Conservation and Pollution Prevention, Key Laboratory of JiangHuai Arable Land Resources Protection and Eco-Restoration, College of Resources and Environment, Anhui Agricultural University, Hefei 230036, China
Yongbo Qi
Affiliation:
Anhui Province Key Lab of Farmland Ecological Conservation and Pollution Prevention, Key Laboratory of JiangHuai Arable Land Resources Protection and Eco-Restoration, College of Resources and Environment, Anhui Agricultural University, Hefei 230036, China
Qingyun Wang
Affiliation:
Anhui Province Key Lab of Farmland Ecological Conservation and Pollution Prevention, Key Laboratory of JiangHuai Arable Land Resources Protection and Eco-Restoration, College of Resources and Environment, Anhui Agricultural University, Hefei 230036, China
Huaiyan Zhao*
Affiliation:
Anhui Province Key Lab of Farmland Ecological Conservation and Pollution Prevention, Key Laboratory of JiangHuai Arable Land Resources Protection and Eco-Restoration, College of Resources and Environment, Anhui Agricultural University, Hefei 230036, China
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Abstract

The formation of manganese (Mn) oxides is influenced by environmental conditions and, in some red soils, Mn oxides occur as coatings on the surface of kaolinite particles in the form of colloidal films or fine particles. The present study aimed to explore the types of formation mechanisms of Mn oxide minerals on the surface of kaolinite. Mn oxide minerals synthesized by reducing the Mn in KMnO4 with a divalent Mn salt (MnSO4) were examined using X-ray diffraction (XRD) and scanning electron microscopy (SEM). The effects of various initial molar ratios of Mn2+/Mn7+ (R = 1:0.67, 1:1, 1:2, and 1:4), cationic species (Na+ or Mg2+), synthesis temperatures (30, 60, and 110°C), and amount of added kaolinite (0.25, 0.5, 1.0, 2.0, and 5.0 g) on the formation of Mn oxides were studied. The results showed that Mn oxide mineral types were affected by the initial R value and the background cation. With decreases in the initial R value, the synthesized minerals transformed from cryptomelane to birnessite. The relative mass ratios of kaolinite to Mn oxide were calculated as 1:0.92, 1:0.63, 1:1.15, and 1:1.63. The sodium cation (Na+) had a greater role than Mg2+ in promoting the dissolution–recrystallization of birnessite to cryptomelane. The synthesis temperature had no effect on mineral types, but Mn content increased as temperature increased. When the amount of added kaolinite was increased from 0.25 to 5.0 g, Mn oxide minerals formed gradually and transformed from birnessite to cryptomelane. This work revealed a possible formation process and reaction mechanism on the surface of kaolinite particles in some red soils.

Type
Original Paper
Copyright
Copyright © The Author(s), under exclusive licence to The Clay Minerals Society 2023

Introduction

Manganese is one of the major elements in the earth's crust and exists usually in the soil in the form of Mn oxide minerals due to weathering and pedogenesis (Hong et al., Reference Hong, Gu, Yin, Zhang and Li2010; Huang et al., Reference Huang, Zhao, Liu, Tan and Koopal2011; Namgung et al., Reference Namgung, Chon and Lee2018; Post, Reference Post1999). Mn oxide minerals are ubiquitous in natural environments and are important components of soil (Huang et al., Reference Huang, Zhao, Liu, Tan and Koopal2011). They are important sources of Mn for the nutrition of animals and plants, as well as one of the important adsorbents and carriers of environmental information (Huang et al., Reference Huang, Hong, Tan, Hu, Liu and Wang2008, Reference Huang, Tan, Liu, Hu and Wang2009; Villalobos et al., Reference Villalobos, Toner, Bargar and Sposito2003). The high redox potential of Mn oxide minerals makes them active in the environment, so that they are used commonly as an important redox agent in the soil (Learman et al., Reference Learman, Voelker, Rodriguez and Hansel2011; Liu et al., Reference Liu, Zhang, Gu, Sheng and Zhang2020).

The formation and transformation of Mn oxide minerals in soil are influenced substantially by environmental changes and climate (Feng et al., Reference Feng, Liu, Tan and Liu2004; Hong et al., Reference Hong, Gu, Yin, Zhang and Li2010; Huang et al., Reference Huang, Zhao, Liu, Tan and Koopal2011; Jung et al., Reference Jung, Taillefert, Sun, Wang, Borkiewicz, Liu, Yang, Chen, Chen and Tang2020; McKenzie, Reference McKenzie1971; Zhang et al., Reference Zhang, Chen, Qiu, Liu and Feng2016). The crystallinity of Mn oxides in soil is low, and they are difficult to analyze and identify directly. Therefore, artificial laboratory simulation synthesis methods by reducing potassium permanganate with a divalent Mn salt were utilized to examine indirectly the formation mechanism of Mn oxide minerals. The product is fine-needle spherical crystals, which are very close to natural birnessite (Feng et al., Reference Feng, Liu, Tan and Liu2004, Reference Feng, Tan, Liu, Huang and Liu2005; Handel et al., Reference Handel, Rennert and Totsche2013; Yang & Wang, Reference Yang and Wang2002). Various kinds of Mn oxide minerals have been reported to have formed under different environmental conditions, such as the ratio of Mn2+/MnO4, the concentration of Mn2+, temperature, background electrolyte, etc. (Cornell & Giovanoli, Reference Cornell and Giovanoli1988; Handel et al., Reference Handel, Rennert and Totsche2013; Hella et al., Reference Hella, Romain, Ghouti, Christian and Latifa2017; Kijima et al., Reference Kijima, Yasuda, Sato and Yoshimura2001; Liang et al., Reference Liang, Post, Lanson, Wang, Zhu, Liu, Tan, Feng, Zhu, Zhang and De Yoreo2020; Zhao et al., Reference Zhao, Zhu, Li, Elzinga, Villalobos, Liu, Zhang, Feng and Sparks2016; Zhu et al., Reference Zhu, Vogel, Parikh, Feng and Sparks2010). The average oxidation states of Mn in birnessite are affected by the Mn2+/MnO4 ratio and birnessite begins to form at low Mn2+/MnO4 ratios (Luo et al., Reference Luo, Steven and Suib1997). Furthermore, Ma et al. (Reference Ma, Liu, Huang and Sun2013) showed that synthetic Mn oxide minerals were transformed from cryptomelane to birnessite with a decrease in Mn2+/MnO4 from 1:1 to 1:4. Mn2+ induced the transformation of birnessite to other new phases such as cryptomelane at room temperature (Tu et al., Reference Tu, Racz and Goth1994). Background electrolytes affect the morphology, chemical composition, and crystal structure of birnessite (Zhang et al., Reference Zhang, Liu, Tan, Suib, Qiu and Liu2018; Zhu et al., Reference Zhu, Vogel, Parikh, Feng and Sparks2010). In the dissolution–recrystallization process of birnessite, todorokite was generated easily if the hydration ion radius of interlayer ions was large, such as Ca2+ and Mg2+, while Mn oxides with smaller tunnel sizes such as cryptomelane were formed if the hydration ion radius was small, such as Na+ and K+ (Hella et al., Reference Hella, Romain, Ghouti, Christian and Latifa2017; Zhao et al., Reference Zhao, Liang, Yin, Liu, Tan, Qiu and Feng2015). The dissolution-crystallization process was affected by temperature. Increasing the temperature shortened the induction period, increased the crystallization rate, and accelerated the phase transition from birnessite to other phases (Luo et al., Reference Luo, Steven and Suib1997; Portehault et al., Reference Portehault, Cassaignon, Baudrin and Jolivet2007).

The red soil region of southern China often undergoes periodic flooding in the rainy season due to high soil viscosity, poor drainage capacity, and mountainous and hilly landforms. With much rainfall and concomitant surface runoff in the rainy season, water accumulates and remains in low-lying areas, which leads to imperfect drainage and flooding. In the red soils of Guangxi, Guizhou, Fujian, etc., in particular, due to the geological and climatic factors listed above, the soils experience alternating oxidation/reduction conditions necessary for producing manganese oxide minerals. Therefore, the red soil of southern China is rich in Mn oxide minerals (Hong et al., Reference Hong, Gu, Yin, Zhang and Li2010; Huang et al., Reference Huang, Hong, Tan, Hu, Liu and Wang2008, Reference Huang, Tan, Liu, Hu and Wang2009, Reference Huang, Zhao, Liu, Tan and Koopal2011; Zhao et al., Reference Zhao, He, Wang, Tao and Li2022). The hydrothermal conditions and redox potential of the soil affect significantly the formation, transformation, and surface properties of these Mn oxide minerals (Huang et al., Reference Huang, Zhao, Liu, Tan and Koopal2011; Liang et al., Reference Liang, Post, Lanson, Wang, Zhu, Liu, Tan, Feng, Zhu, Zhang and De Yoreo2020). Mn and Fe oxide minerals are often present simultaneously in red soils, where they are highly active (Chen et al., Reference Chen, Koopal, Xu, Wang and Tan2019; Huang et al., Reference Huang, Zhao, Liu, Tan and Koopal2011; Krishnamurti & Huang, Reference Krishnamurti and Huang1988; Liu et al., Reference Liu, Sayako, Zhu, He and Hochella2021; Luo et al., Reference Luo, Ding, Shen, Tan, Qiu and Liu2018). Iron oxide mineral surfaces can accelerate the oxidation of Mn(II) to form Mn oxides to a certain degree (Davies & Morgan, Reference Davies and Morgan1989). Iron oxide promoted significantly the oxidation of Mn2+ and crystallization of Mn oxide (Liu et al., Reference Liu, Chen, Yang, Wei, Laipan, Zhu, He and Hochella2022), which can be attributed to the fact that Fe oxide can function as a catalyst by promoting electron transfer between Mn2+ and dissolved O2. The formation of manganite was catalyzed by the hematite surface which is explained by the electron transfer from adsorbed Mn(II) to another site with adsorbed O2 via the band structure of the semiconducting hematite (Inoue et al., Reference Inoue, Yasuhara, Ai, Hochella and Murayama2019). Semiconductor minerals (e.g. hematite, goethite, and ferrihydrite) show greater catalytic ability for Mn2+ oxidation than insulating minerals (e.g. albite, amorphous Al(OH)3, and montmorillonite) (Lan et al., Reference Lan, Wang, Xiang, Yin, Tan, Qiu, Zhang and Feng2017). Furthermore, Mn oxide minerals are often coated or stored on the surface of kaolinite in the form of a colloidal film or as fine particles to form complexes (Choi et al., Reference Choi, Komarneni and Park2009; Khan et al., Reference Khan, Khan and Shahjahan2015; Mckenzie, Reference McKenzie1972; Zhu et al., Reference Zhu, Qi, Zhang, Teresa, Xu, Fan and Sun2019). Kaolinite is also an insulating mineral, which may provide a surface to precipitate the Mn mineral via heterogeneous nucleation. The formation and transformation of Fe oxide is significantly inhibited by the presence of kaolinite, while the presence of Fe2+ in solution accelerated it (Chen et al., Reference Chen, Koopal, Xu, Wang and Tan2019; Wei et al., Reference Wei, Liu, Feng, Tan and Koopal2011). Do Mn oxide minerals also form and transform on the surface of kaolinite? The factors which influence their formation and transformation have yet to be discovered.

In view of the above, the present study was performed in order to explore the types and formation mechanisms of Mn oxides synthesized on the surface of kaolinite, a typical mineral in red soil, considering the influencing factors of different Mn2+/MnO4 molar ratios, cation types, synthesis temperature, and amount of kaolinite added. These results will provide a theoretical foundation for a better understanding of the formation process and reaction mechanism of Mn oxide in red soil and enrich the research of soil-interface chemistry.

Materials and Methods

Materials

Kaolinite was purchased from Sigma-Aldrich (Shanghai, China) Trading Co, Ltd (characterization of the kaolinite is described in the supplementary information), and KMnO4 was acquired from Xilong Science Co., Ltd (Chengdu, China). MnSO4·H2O, MgSO4, and Na2SO4 were provided by Sinopharm Chemical Reagent Co., Ltd (Shanghai, China). Hydroxylamine hydrochloride was purchased from Aladdin Chemical Reagent Co., Ltd (Shanghai, China). All reagents were used without further purification. The HK-UV-10 (Hongke Technology Co., Ltd, Hefei, China) pure water purification system provided the deionized water (DDW) for this study.

Synthesis of Mn oxide Minerals on Kaolinite Surfaces

1 g of kaolinite was placed in a reactor containing 30 mL of 0.067, 0.1, 0.2, or 0.4 M KMnO4 and 0.1 M Na2SO4 or MgSO4. The reactor was placed in an oil bath at a specific temperature (30, 60, or 110°C) and at a stirring speed of 300 r/min. Then, 30 mL of 0.1 M MnSO4 solution was added dropwise into the above-mixed solution using a peristaltic pump. This was followed by agitation of the mixtures for 30 min at constant temperature and aging for 24 h at 60°C after cooling (Frias et al., Reference Frias, Nousir, Barrio, Montes, Lopez, Centeno and Odriozola2007). The aged minerals were centrifuged and cleaned with deionized water until the conductivity was < 20 μS cm–1, then freeze-dried immediately, crushed, sieved with a 100-mesh sieve, and stored for further analysis. The synthesis conditions for all Mn oxides were the same.

Effect of the molar ratio of Mn2+ to Mn7+

The Mn oxide minerals were synthesized at various molar ratios (R) of Mn2+ to Mn7+ (R = 1:0.67, 1:1, 1:2, and 1:4). The pH of the mixture was measured and found to be ~1.4. The synthesis temperature was controlled at 30°C, with Na+ as the background cations. 1 g of kaolinite was added.

Effect of the background cations

The Mn oxide minerals were synthesized with the same concentrations of Na2SO4 or MgSO4 as different background cations. 1 g of kaolinite was added at a synthesis temperature of 30°C. Meanwhile, a control experiment was conducted without background cations, and the other treatments were the same as above.

Effect of the synthesis temperature

The Mn oxide minerals were synthesized at 30, 60, and 110°C. The value of R was 1:4, with Na+ as the background cation. 1 g of kaolinite was added.

Effect of the amount of kaolinite added

When the Mn oxide minerals were synthesized, the amount of kaolinite used was 0.25, 0.50, 1.0, 2.0, or 5.0 g. The value of R was 1:1, with a synthesis temperature of 30°C and Na+ as the background cation. The synthesis procedure of Mn oxide minerals with various values of R was the same as above except that no kaolinite was added.

Mn content in Mineral Determinations

The synthetic kaolinite-Mn oxide mineral complex samples were dissolved by 0.25 M hydroxylamine hydrochloride. The Mn contents of samples were measured using an A3AFG-13 (Purkinje General Instrument Co., Ltd, Beijing, China) flame atomic absorption spectrometer (Yan et al., Reference Yan, Liu, Min, Li, Zhu, Lu and Gao2020).

Relative Mass Ratio of Kaolinite to Mn oxide Determination

0.2 g of the sample was dissolved in 4 mL of 0.25 M hydroxylamine hydrochloride solution, which was placed in a 10 mL centrifuge tube, then centrifuged (8000 rpm, 10 min) and washed with deionized water. The supernatant was poured out and the residues of the samples after the dissolution were dried and weighed. This was the mass of kaolinite. The mass of Mn oxide was obtained from 0.2 g minus the mass of kaolinite. The relative mass ratio of kaolinite to Mn oxide in the final product was calculated (Neaman et al., Reference Neaman, Waller, Mouele, Trolard and Bourrie2004).

Characterization

X-ray diffraction (XRD)

The powder samples were characterized using an XD6 X-ray diffractometer (Purkinje General Instrument Co. Ltd., Beijing, China) using monochromatic CuKα radiation. The diffractometer was operated at a tube voltage of 36 kV and a tube current of 20 mA, and all of the XRD patterns of samples were scanned from 5 to 80°2θ at a scanning rate of 1°2θ per min.

Scanning electron microscopy (SEM)

The samples were mounted on sample holders with carbon glue and then gold coated. The samples were analyzed using the Zeiss Sigma 300 field emission scanning electron microscope (Oberkochen, Baden-Wurttemberg, Germany), with an accelerating voltage of 3 kV, and the microstructure and morphology of minerals were examined by SEM.

Results

Effect of the Molar Ratios of Mn2+ to Mn7+

The Mn oxide minerals were synthesized on the surface of kaolinite by reducing potassium permanganate with a divalent Mn salt, controlling the molar ratios of Mn2+ to Mn7+ at 1:0.67, 1:1, 1:2, and 1:4 (Frias et al., Reference Frias, Nousir, Barrio, Montes, Lopez, Centeno and Odriozola2007). In the system of adding kaolinite (Fig. 1), the synthesized kaolinite-Mn oxide complexes showed strong peaks of kaolinite (Choi et al., Reference Choi, Komarneni and Park2009). When R was 1:0.67, the complex also had characteristic diffraction peaks of cryptomelane and birnessite (Kijima et al., Reference Kijima, Yasuda, Sato and Yoshimura2001; Tu et al., Reference Tu, Racz and Goth1994; Zhao et al., Reference Zhao, Zhu, Li, Elzinga, Villalobos, Liu, Zhang, Feng and Sparks2016), indicating that the surface mineral of kaolinite was a mixture of cryptomelane and birnessite. However, when R was 1:1, the only Mn oxide on the surface of kaolinite was cryptomelane; when R was 1:2 and 1:4, Mn oxides formed were single-phase birnessite (Fig. 1a, b). The results showed, thus, that the types of Mn oxides formed on the surface of kaolinite were influenced by the value of R.

Fig. 1 XRD patterns of kaolinite-Mn oxide mineral complexes a with various molar ratios of Mn2+ to Mn7+ (R = 1:0.67, 1:1, 1:2, and 1:4); and b in the high-angle region. The synthesis temperature was controlled at 30°C, with Na+ as the background cation. 1 g of kaolinite was added. The labeled peaks are identified

Scanning electron microscopy images of the kaolinite-Mn oxide complexes with various R values and Na+ as the background cation (Fig. 2) showed that kaolinite had a stacked-plate structure (Zhu et al., Reference Zhu, Qi, Zhang, Teresa, Xu, Fan and Sun2019). When R was 1:0.67, nanowire structures (diameter 0.2–2 μm; height 1–10 nm) and flower-spherical aggregate structures (formed by the flaky crystals (diameter 200–300 nm)) were formed on the surface of kaolinite (Fig. 2a). The nanowires structures and flower-spherical aggregate structures were the crystal morphology of cryptomelane and birnessite, respectively (Mckenzie, Reference McKenzie1971; Portehault et al., Reference Portehault, Cassaignon, Baudrin and Jolivet2007; Yin et al., Reference Yin, Wang, Qin, Vogel, Zhang, Jiang, Liu, Li, Zhang and Wang2018). When R was 1:1, the surface mineral of kaolinite was cryptomelane with nanowire structures (Fig. 2b). When R was 1:2 and 1:4, the surface minerals of kaolinite showed uniform flower-spherical aggregate structures (Fig. 2c, d), which was the crystal morphology of birnessite. The morphology changes shown by the SEM images were consistent with the mineral phase transformation results of the XRD patterns.

Fig. 2 SEM images of kaolinite-Mn oxide mineral complexes with Na+ as the background cation; the R values were a 1:0.67, b 1:1, c 1:2, and d 1:4

When the R values were 1:0.67, 1:1, 1:2, and 1:4, with Na+ as the background cation, the Mn content in kaolinite-Mn oxide complexes was small, ~ 0.14, 0.10, 0.20, and 0.22 mg/g, respectively (Fig. 3). The Mn content among various treatments was significantly different (P < 0.05). In addition, the relative mass ratios of kaolinite to Mn oxide in the final product were calculated as 1:0.92, 1:0.63, 1:1.15, and 1:1.63. The mass percentage of Mn oxide in the final product increased when the R value decreased, except the sample with R = 1:1.

Fig. 3 Mn content in kaolinite-Mn oxide mineral complexes with Mn2+ to Mn7+ molar ratios of 1:0.67, 1:1, 1:2, and 1:4, with Na+ as the background cation

Effect of the Background Cation

The XRD pattern of kaolinite-Mn oxide complexes formed under the background cations of Na+, Mg2+, and without a background cation (Fig. 4) revealed that when R was 1:0.67, the characteristic peaks of cryptomelane and birnessite were both shown in complexes under different cation backgrounds, suggesting that the Mn oxide minerals synthesized on the surface of kaolinite were a mixture of cryptomelane and birnessite. When R was 1:2 and 1:4, the single-phase birnessite was synthesized under different cation backgrounds. However, when R was 1:1 with Na+ as the background cation (Fig. 1b), the complex had diffraction peaks characteristic of cryptomelane. Under Mg2+ as the background cation (Fig. 4a, c) and without a background cation (Fig. 4b, c), Mn oxides formed were composed of cryptomelane and birnessite. These results indicated that the presence of Na+ as the background cation promoted the transformation from birnessite to cryptomelane, while Mg2+ had no obvious effect.

Fig. 4 XRD patterns of products formed after treatment of kaolinite-Mn oxide complex a with background Mg2+cations; b without background cations; and c with background cations of Na+, Mg2+, and without background cations. The R value was 1:1. The labeled peaks are identified

When R was 1:0.67, 1:1, 1:2, and 1:4, the Mn contents of kaolinite-Mn oxide complexes with Na+ (Fig. 3) or Mg2+ (Fig. 5) as the background cation were 0.14, 0.10, 0.20, 0.22 mg/g and 0.14, 0.13, 0.18, 0.20 mg/g, respectively. The relative mass ratios of kaolinite to Mn oxides in the complexes were 1:0.92, 1:0.63, 1:1.15, 1:1.63 and 1:0.81, 1:0.67, 1:1.09, 1:1.53, respectively. This indicated that the Mn content of minerals on the surface of kaolinite was affected by the choice of background cation, although the difference was small. The Mn content and the mass percentage of Mn oxide in the final product with Na2+ as the background cation were generally larger than with Mg2+.

Fig. 5 Mn content in kaolinite-Mn oxide mineral complexes with Mn2+ to Mn7+ molar ratios of 1:0.67, 1:1, 1:2, and 1:4, with Mg2+ as the background cation

Effect of the Temperature of Synthesis

From the analysis above, the mineral on the surface of kaolinite under different background cations with an R value of 1:4 was pure phase birnessite (Fig. 4), which is the most abundant Mn oxide mineral in the soil (Feng et al., Reference Feng, Liu, Tan and Liu2004).

The effect of temperature on the formation of Mn oxides with an R value of 1:4 was studied. The kaolinite-Mn oxide complexes were synthesized at 30, 60, and 110°C. The XRD patterns (Fig. 6) revealed that, besides the characteristic diffraction peaks of kaolinite, there were very obvious peaks of birnessite at various temperatures (Fig. 6a, b), indicating that single-phase birnessite formed on the surface of kaolinite at various temperatures and temperature had no effect on the type of Mn oxide formed.

Fig. 6 XRD patterns of kaolinite-Mn oxide mineral complexes formed with R = 1:4 and with 1 g of added kaolinite; the synthesis temperatures were 30, 60, and 110°C, with background a Na+ and b Mg2+ cations. The labeled peaks are identified

The Mn contents of kaolinite-Mn oxide complexes synthesized at 30, 60, and 110°C in Na+ (Fig. 7a) and Mg2+ (Fig. 7b) were 0.22, 0.28, 0.29 mg/g and 0.20, 0.27, 0.28 mg/g, respectively. The relative mass ratios of kaolinite to Mn oxide were 1:1.63, 1:2.14, 1:2.46, and 1:1.53, 1:1.87, 1:2.20, respectively. The results showed that the Mn content and the mass percentage of Mn oxide in complexes increased gradually with increase in temperature. The amount of birnessite on the surface of kaolinite increased gradually with increasing temperature.

Fig. 7 Mn content in kaolinite-Mn oxide minerals under the background of a Na+, b Mg2+ at 30, 60, and 110°C, with the R value = 1:4 and the amount of kaolinite added was 1 g

Effect of Kaolinite Addition

Two different pretreatments were used, one without kaolinite (Fig. 8a) and the other with 0.25, 0.5, 1.0, 2.0, and 5.0 g of kaolinite added (Fig. 8b). With no added kaolinite the XRD pattern of Mn oxide showed that, when R was 1:0.67, only the characteristic diffraction peaks of cryptomelane were present. When R was 1:1, 1:2, and 1:4, the Mn oxide was birnessite (Fig. 8a). In the treatment with added kaolinite, when R was 1:1 and the amount of kaolinite was 0.25 or 0.50 g, the Mn oxide formed was birnessite. However, when 1.0, 2.0, or 5.0 g of kaolinite was added, the Mn oxide formed was cryptomelane (Fig. 8b). In addition, the relative mass ratio of kaolinite and Mn oxide in the end products was calculated as 1:4.67, 1:2.34, 1:0.63, 1:0.53, and 1:0.28, for 0.25, 0.5, 1.0, 2.0, and 5.0 g of added kaolinite, respectively. With the increase in kaolinite content, the mass percentage of Mn oxide in the complex decreased gradually, which is also the reason why the diffraction peak intensity of kaolinite gradually became strong and sharp with the addition of kaolinite from 0.25 g to 5 g. The results showed that the addition of kaolinite affected the Mn oxide mineral type of the complexes; with increase in kaolinite concentration, the conversion rate of birnessite increased gradually, indicating that kaolinite can promote the process of birnessite dissolution and recrystallization into cryptomelane.

Fig. 8 XRD patterns of a Mn oxide minerals and b kaolinite-Mn oxide mineral complexes formed when using the following amounts of kaolinite: 0.25, 0.5, 1.0, 2.0, and 5.0 g, with Na+ as the background cation; the value of R was 1:1; the synthesis temperature was 30°C

Discussion

The types of Mn oxide minerals were affected by various environmental conditions in the synthesis process. In the present study, birnessite and cryptomelane were synthesized under different molar ratios of Mn2+ to Mn7+ on the surface of kaolinite. The formation of birnessite on the surface of kaolinite followed one of two processes, and the chemical reaction stoichiometry of which was (Villalobos et al., Reference Villalobos, Toner, Bargar and Sposito2003):

(1) 2 Mn O 4 - + 3 M n 2 + + 2 H 2 O 5 Mn O 2 Birnessite + 4 H +
(2) 4 Mn O 4 - + 4 H + 4 Mn O 2 Birnessite + 2 H 2 O + 3 O 2

Studies have shown that the transformation of birnessite into cryptomelane is a process of dissolution–recrystallization (Lefkowitz et al., Reference Lefkowitz, Rouff and Elzinga2013; Zhang et al., Reference Zhang, Xiao, Feng, Tan, Qiu and Liu2011), and the interaction between birnessite and Mn2+ in solution promotes the transformation of birnessite (Morgan, Reference Morgan2005; Tu et al., Reference Tu, Racz and Goth1994; Zhang et al., Reference Zhang, Xiao, Feng, Tan, Qiu and Liu2011). When R was 1:0.67 or 1:1, with gradual dropwise addition of of Mn2+, the MnO4 in the system was exhausted gradually. With continuous dropwise addition of acidic Mn2+, the acidity in the system was relatively strong and promoted the dissolution process and accelerated recrystallization. The dissolution of birnessite and the recrystallization of Mn oxide octahedra continued in the system until birnessite was dissolved completely and transformed into cryptomelane (Zhang et al., Reference Zhang, Xiao, Feng, Tan, Qiu and Liu2011; Zhao et al., Reference Zhao, Liang, Yin, Liu, Tan, Qiu and Feng2015). When R was 1:0.67, the reaction was in the process of dissolution–recrystallization, a mixture of birnessite and cryptomelane was formed. When R was 1:1, and the reaction completed, birnessite was converted into cryptomelane completely. When R was 1:2 and 1:4, the concentration of MnO4 in the system was greater, and Mn2+ was consumed completely in the reaction system, and the product was single-phase birnessite (Tu et al., Reference Tu, Racz and Goth1994). The Mn oxide mineral types on the surface of kaolinite transformed from the mixture of birnessite and cryptomelane to birnessite as the R value decreased within a certain R value range, which was consistent with the results reported by Ma et al. (Reference Ma, Liu, Huang and Sun2013). The R value affects directly the type of Mn oxide synthesized. In addition, the coating amount of Mn oxide in the complexes was also affected by the R value. When the R value decreased, the amount of Mn in minerals increased, which may be related to the crystallinity of the Mn oxide minerals. When the crystallization of Mn oxide minerals was weaker, the mineral crystals formed were smaller and the effective area in contact with the kaolinite increased, thus more easily covering the kaolinite surface (Khan et al., Reference Khan, Khan and Shahjahan2015). Furthermore, as the R value decreased, the concentration of MnO4 in the system increased, the reaction between excess MnO4 in the solution and H+ formed more birnessite (chemical reaction process 2). The amount of Mn in minerals increased accordingly (Zhang et al., Reference Zhang, Xiao, Feng, Tan, Qiu and Liu2011). When the R value was 1:1, the amount of MnO4 in the system was insufficient (chemical reaction process 1). With continuous dropwise addition of Mn2+, the birnessite transformed into cryptomelane through dissolution-recrystallization (Tu et al., Reference Tu, Racz and Goth1994; Zhang et al., Reference Zhang, Xiao, Feng, Tan, Qiu and Liu2011). At this time, birnessite was in the stage of dissolution-recombination, and the Mn content in the complex was smaller than that in other conditions. This assumption was also confirmed by XRD studies. As seen in the XRD pattern (Fig. 1), when R was 1:1, the kaolinite peak was strongest, probably caused by the amount of Mn oxide synthesized on the kaolinite surface being least.

In addition, coexisting cations will also affect the type of Mn oxide. Studies have shown that coexisting cations can affect the layer structure, microstructure, and crystallinity of the Mn oxide, and a series of new minerals can be obtained from birnessite by ion exchange (Feng et al., Reference Feng, Liu, Tan and Liu2004; Hella et al., Reference Hella, Romain, Ghouti, Christian and Latifa2017; Luo et al., Reference Luo, Steven and Suib1997; Zhu et al., Reference Zhu, Vogel, Parikh, Feng and Sparks2010). The interlayer Na+ of birnessite has been shown (Zhao et al., Reference Zhao, Liang, Yin, Liu, Tan, Qiu and Feng2015) to exchange easily with Mg2+, which indicates that the structure of birnessite with Mg2+ as the interlayer ion is more stable. The hydrated ionic radius of Na+ (3.58 Å) is less than Mg2+ (4.28 Å) (Kuma et al., Reference Kuma, Usui, Paplawsky, Gedulin and Arrhenius1994; Zhang et al., Reference Zhang, Liu, Tan, Suib, Qiu and Liu2018), so Mg2+ with a larger radius (relative to Na+) prevents the structural layer of birnessite from collapsing (Feng et al., Reference Feng, Tan, Liu, Huang and Liu2005; Zhang et al., Reference Zhang, Chen, Qiu, Liu and Feng2016, Reference Zhang, Liu, Tan, Suib, Qiu and Liu2018). The hydrated ionic radius of Na+ was too small to support the layered structure of birnessite in the process of dissolution–recrystallization, and the interlayer space of 0.72 nm in birnessite collapses easily. Finally, the cryptomelane with a tunnel structure was formed (Zhang et al., Reference Zhang, Xiao, Feng, Tan, Qiu and Liu2011). Therefore, when the R value was 1:1, the single-phase cryptomelane was synthesized with Na+ as the background cation. However, with Mg2+ as the background cation, the surface mineral of kaolinite was a mixture of cryptomelane and birnessite. The amount of Mn oxide synthesized under various background cations differs slightly. The Mn content when Mg2+ was the background cation+ was generally smaller than in the background cations of Na+, which may be attributed to the delayed crystallization rate of the system with Mg2+. Birnessite crystallization occurs in three stages: an induction period, a fast crystallization period, and a steady-state period (Luo et al., Reference Luo, Steven and Suib1997). The induction period with Mg2+ was longer than that of the Mg2+ free synthesis; thus, the amount of Mn was smaller with the coexisting Mg2+.

Increasing the temperature can shorten the induction period and increase the crystallization rate (Luo et al., Reference Luo, Steven and Suib1997). In the present study, only birnessite formed on the surface of kaolinite over the temperature range 30 to 110°C. This suggested that increasing the temperature within a certain temperature range (30–110°C) was conducive to the formation of birnessite on the surface of kaolinite. The temperature affected the Mn content in minerals; the Mn content in complexes increased gradually with increasing temperature (Fig. 7).When the temperature was low, the crystallinity of birnessite was obviously impeded, while high temperature accelerated the crystallization rate (Luo et al., Reference Luo, Steven and Suib1997). As a result, birnessite formed quickly and had a larger Mn content at higher temperature.

Mn oxides in soil are not only observed commonly in nodules containing high concentrations of the oxides of Fe and Mn, but also often occur coated or stored on the surface of clay minerals such as kaolinite in the form of colloidal films or fine particles (Choi et al., Reference Choi, Komarneni and Park2009; Khan et al., Reference Khan, Khan and Shahjahan2015; Liu et al., Reference Liu, Sayako, Zhu, He and Hochella2021; McKenzie, Reference McKenzie1972). Studies have shown that mineral surfaces, such as Fe (oxyhydr)oxides, can accelerate the oxidation of Mn2+ to form Mn oxides to a certain degree (Jung et al., Reference Jung, Taillefert, Sun, Wang, Borkiewicz, Liu, Yang, Chen, Chen and Tang2020, Reference Jung, Xu, Wan, Wang, Borkiewicz, Li, Chen, Lu and Tang2021; Lan et al., Reference Lan, Wang, Xiang, Yin, Tan, Qiu, Zhang and Feng2017). Kaolinite is an insulating mineral, which may provide a surface on which to precipitate the Mn oxides via heterogeneous nucleation. SEM images (Fig. 2) demonstrated the uniform distribution of birnessite/cryptomelane on the surface of kaolinite. This is similar to a previous report (Won et al., Reference Won, Jeong, Lee, Dai and Burns2020) which showed that kaolinite particles may play a role as nucleation sites and promote the heterogeneous nucleation of calcite.

Conclusions

The Mn oxide minerals formed on the surface of kaolinite particles were affected by the initial molar ratio of Mn2+ to Mn7+ (R). When R was 1: 0.67, the product contained both birnessite and cryptomelane, while when R was 1:1, the product was single-phase cryptomelane, and single-phase birnessite was formed when R was 1:2 and 1:4. As the R value was decreased, the Mn content in the minerals increased. Background cations also affected the type of Mn oxide formed on the surface of kaolinite. The Na+ ion promoted birnessite transformation by dissolution/recrystallization to cryptomelane, while Mg2+ had no obvious effect. Furthermore, the Mn content in the background Mg2+ cation solution was generally less than in the Na+ solution. The synthesis temperature had no effect on the type of Mn oxide mineral formed, but Mn content increased as the temperature was increased. When the amount of kaolinite added was increased from 0.25 to 5.0 g, the Mn oxide minerals synthesized were transformed gradually from birnessite to cryptomelane. With an increase in kaolinite content, the relative mass ratios of kaolinite to Mn oxide in the end products was calculated as 1:4.67, 1:2.34, 1:0.63, 1:0.53, and 1:0.28.

Supplementary Information

The online version contains supplementary material available at https://doi.org/10.1007/s42860-023-00236-6.

Acknowledgements

The authors acknowledge the support of Anhui Province Key Lab of Farmland Ecological Conservation and Pollution Prevention, the Opening Fund Project of National Red Soil Improvement Engineering Technology Research Center (Grant No. 2020NETRCRSI-13). The authors are also grateful to the Editor-in-Chief and the anonymous reviewers for their very helpful comments and suggestions.

Authors' Contributions

Authors whose names appear on the submission were involved in the writing and revision of the manuscript. All authors have contributed equally to the work.

Funding

Sources are as stated in the Acknowledgments.

Data Availability

All data are contained within the article.

Code Availability

Not applicable.

Declarations

The manuscript has not been submitted to more than one journal for simultaneous consideration and has not been published in full or in part previously. Compliance with ethical statements and all authors consent to participate.

Consent for Publication

All authors give consent for publication.

Conflict of Interest

The authors declare that they have no conflict of interest.

Footnotes

Associate Editor: William F. Jaynes

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References

Chen, H. F., Koopal, L. K., Xu, J. L., Wang, M. X., Tan, W. F. Selective adsorption of soil humic acid on binary systems containing kaolinite and goethite: Assessment of sorbent interactions European Journal of Soil Science 2019 70 5 10981107CrossRefGoogle Scholar
Choi, J., Komarneni, S., Park, M. Mn-kaolinite synthesis under low-temperature hydrothermal conditions Applied Clay Science 2009 44 3–4 237241 10.1016/j.clay.2009.02.010CrossRefGoogle Scholar
Cornell, R. M., Giovanoli, R. Transformation of hausmannite into birnessite in alkaline media Clays and Clay Minerals 1988 36 249257 10.1346/CCMN.1988.0360306CrossRefGoogle Scholar
Davies, SHR, Morgan, J. J. Manganese(II) oxidation kinetics on metal oxide surfaces Journal of Colloid and Interface Science 1989 129 1 6377 10.1016/0021-9797(89)90416-5CrossRefGoogle Scholar
Feng, X. H., Liu, F., Tan, W. F., Liu, X. W. Synthesis of birnessite from the oxidation of Mn2+ by O2 in alkali medium: Effects of synthesis conditions Clays and Clay Minerals 2004 52 2 240250 10.1346/CCMN.2004.0520210CrossRefGoogle Scholar
Feng, X. H., Tan, W. F., Liu, F., Huang, Q. Y., Liu, X. W. Pathways of birnessite formation in alkali medium Science China Earth Sciences 2005 48 9 14381451Google Scholar
Frias, D., Nousir, S., Barrio, I., Montes, M., Lopez, T., Centeno, M. A., Odriozola, J. A. Synthesis and characterization of cryptomelane-type and birnessite-type oxides: Precursor effect Materials Characterization 2007 58 8–9 776781 10.1016/j.matchar.2006.11.005CrossRefGoogle Scholar
Handel, M., Rennert, T., Totsche, K. U. Synthesis of cryptomelane-type and birnessite-type manganese oxides at ambient pressure and temperature Journal of Colloid and Interface Science 2013 405 4450 10.1016/j.jcis.2013.05.041CrossRefGoogle ScholarPubMed
Hella, B., Romain, C., Ghouti, M., Christian, R., Latifa, B. Conditions for the formation of pure birnessite during the oxidation of Mn(II) cations in aqueous alkaline medium Journal of Solid State Chemistry 2017 248 1825 10.1016/j.jssc.2017.01.014Google Scholar
Hong, H. L., Gu, Y. S., Yin, K., Zhang, K. X., Li, Z. H. Red soils with white net-like veins and their climate significance in south China Geoderma 2010 160 2 197207 10.1016/j.geoderma.2010.09.019CrossRefGoogle Scholar
Huang, L., Hong, J., Tan, W. F., Hu, H. Q., Liu, F., Wang, M. K. Characteristics of micromorphology and element distribution of iron-manganese cutans in typical soils of subtropical China Geoderma 2008 146 1–2 4047 10.1016/j.geoderma.2008.05.007CrossRefGoogle Scholar
Huang, L., Tan, W. F., Liu, F., Hu, H. Q., Wang, M. K. Characteristics of iron-manganese cutans and matrices in Alfisols and Ultisols of subtropical China Soil Science 2009 174 238246 10.1097/SS.0b013e31819f5fffCrossRefGoogle Scholar
Huang, C. Q., Zhao, W., Liu, F., Tan, W. F., Koopal, L. K. Environmental significance of mineral weathering and pedogenesis of loess on the southernmost Loess Plateau China. Geoderma 2011 163 3–4 219226 10.1016/j.geoderma.2011.04.018CrossRefGoogle Scholar
Inoue, S., Yasuhara, A., Ai, H., Hochella, M. F., & Murayama, M. (2019). Mn(II) oxidation catalyzed by nanohematite surfaces and manganite/hausmannite core-shell nanowire formation by self-catalytic reaction. Geochimica et Cosmochimica Acta, 258, 7996.CrossRefGoogle Scholar
Jung, H., Taillefert, M., Sun, J., Wang, Q., Borkiewicz, O. J., Liu, P., Yang, L. F., Chen, S., Chen, H. L., Tang, Y. Z. Redox cycling driven transformation of layered manganese oxides to tunnel structures Journal of the American Chemical Society. 2020 142 25062513 10.1021/jacs.9b12266CrossRefGoogle ScholarPubMed
Jung, H., Xu, X. M., Wan, B., Wang, Q., Borkiewicz, O. J., Li, Y., Chen, H. L., Lu, A. H., & Tang, Y. Z. (2021). Photocatalytic oxidation of dissolved Mn(II) on natural iron oxide minerals. Geochimica et Cosmochimica Acta, 312, 343356.CrossRefGoogle Scholar
Khan, T. A., Khan, E. A., Shahjahan, Removal of basic dyes from aqueous solution by adsorption onto binary iron-manganese oxide coated kaolinite: Non-linear isotherm and kinetics modeling Applied Clay Science 2015 107 7077 10.1016/j.clay.2015.01.005CrossRefGoogle Scholar
Kijima, N., Yasuda, H., Sato, T., Yoshimura, Y. Preparation and characterization of open tunnel oxide α-MnO2 precipitated by ozone oxidation Journal of Solid State Chemistry 2001 159 94102 10.1006/jssc.2001.9136CrossRefGoogle Scholar
Krishnamurti, GSR, Huang, P. M. Influence of manganese oxide minerals on the formation of iron oxides Clays and Clay Minerals 1988 36 467475 10.1346/CCMN.1988.0360513CrossRefGoogle Scholar
Kuma, K., Usui, A., Paplawsky, W., Gedulin, B., Arrhenius, G. Crystal structures of synthetic 7 angstrom and 10 angstrom manganates substituted by mono- and divalent cations Mineralogical Magazine 1994 58 4 425447 10.1180/minmag.1994.058.392.08CrossRefGoogle ScholarPubMed
Lan, S., Wang, X. M., Xiang, Q. J., Yin, H., Tan, W. F., Qiu, G. H., Zhang, J., & Feng, X. H. (2017). Mechanisms of Mn(II) catalytic oxidation on ferrihydrite surfaces and the formation of manganese (oxyhydr)oxides. Geochimica et Cosmochimica Acta., 211, 7996.CrossRefGoogle Scholar
Learman, D. R., Voelker, B. M., Rodriguez, VAI, Hansel, C. M. Formation of manganese oxides by bacterially generated superoxide Nature Geoscience 2011 4 2 9598 10.1038/ngeo1055CrossRefGoogle Scholar
Lefkowitz, J. P., Rouff, A. A., Elzinga, J. E. Influence of pH on the reductive transformation of birnessite by aqueous Mn(II) Environmental Science & Technology 2013 47 18 1036410371 10.1021/es402108dCrossRefGoogle ScholarPubMed
Liang, X. R., Post, J. E., Lanson, B., Wang, X. M., Zhu, M. Q., Liu, F., Tan, W. F., Feng, X. H., Zhu, G. M., Zhang, X., De Yoreo, J. J. Coupled morphological and structural evolution of δ-MnO2 to α-MnO2 through multistage oriented assembly processes: The role of Mn(III) Environmental Science: Nano 2020 7 238249Google Scholar
Liu, J., Zhang, Y. X., Gu, Q., Sheng, A. X., Zhang, B. G. Tunable Mn oxidation state and redox potential of birnessite coexisting with aqueous Mn(II) in mildly acidic environments Minerals 2020 10 8 690 10.3390/min10080690CrossRefGoogle Scholar
Liu, J., Sayako, I., Zhu, R. L., He, H. P., Hochella, M. F. Jr Facet-specific oxidation of Mn (II) and heterogeneous growth of manganese (oxyhydr) oxides on hematite nanoparticles Geochimica Et Cosmochimica Acta 2021 307 151167 10.1016/j.gca.2021.05.043CrossRefGoogle Scholar
Liu, J., Chen, Q., Yang, Y., Wei, H., Laipan, M., Zhu, R., He, H. P., Hochella, M. F. Coupled redox cycling of Fe and Mn in the environment: The complex interplay of solution species with Fe- and Mn-(oxyhydr)oxide crystallization and transformation Earth-Science Reviews 2022 232 104105 10.1016/j.earscirev.2022.104105CrossRefGoogle Scholar
Luo, J., Steven, L., Suib, Preparative parameters, magnesium effects, and anion effects in the crystallization of birnessites Journal of Physical Chemistry B 1997 101 1040310413 10.1021/jp9720449CrossRefGoogle Scholar
Luo, Y., Ding, J., Shen, Y., Tan, W. F., Qiu, G., Liu, F. Symbiosis mechanism of iron and manganese oxides in oxic aqueous systems Chemical Geology 2018 488 162170 10.1016/j.chemgeo.2018.04.030CrossRefGoogle Scholar
Ma, G., Liu, F., Huang, L., Sun, M. M. The process and influence factors of the synthesis of manganese minerals by the reactions between KMnO4 and bivalent manganese salts Acta Petrologica Et Mineralogica 2013 32 03 393400 10.3969/j.issn.1000-6524.2013.03.011Google Scholar
McKenzie, R. M. The synthesis of birnessite, cryptomelane, and some other oxides and hydroxides of manganese Mineralogical Magazine 1971 38 493502 10.1180/minmag.1971.038.296.12CrossRefGoogle Scholar
McKenzie, R. M. The manganese oxides in soils—a review Journal of Plant Nutrition and Soil Science 1972 131 3 221242 10.1002/jpln.19721310302CrossRefGoogle Scholar
Morgan, J. J. (2005). Kinetics of reaction between O2 and Mn(II) species in aqueous solutions. Geochimica et Cosmochimica Acta, 69(1), 3548.CrossRefGoogle Scholar
Namgung, S., Chon, C. M., Lee, G. Formation of diverse Mn oxides: A review of bio-geochemical processes of Mn oxidation Geosciences Journal 2018 22 2 373381 10.1007/s12303-018-0002-7CrossRefGoogle Scholar
Neaman, A., Waller, B., Mouele, F., Trolard, F., Bourrie, G. Improved methods for selective dissolution of manganese oxides from soils and rocks European Journal of Soil Science 2004 55 1 4754 10.1046/j.1351-0754.2003.0545.xCrossRefGoogle Scholar
Portehault, D., Cassaignon, S., Baudrin, E., Jolivet, J. P. Morphology control of cryptomelane type MnO2 nanowires by soft chemistry, growth mechanisms in aqueous medium Chemistry of Materials 2007 19 22 54105417 10.1021/cm071654aCrossRefGoogle Scholar
Post, J. E. Manganese oxide minerals: Crystal structures and economic and environmental significance Proceedings of the National Academy of Sciences of the United States of America 1999 96 7 34473454 10.1073/pnas.96.7.3447CrossRefGoogle ScholarPubMed
Tu, S., Racz, G. J., Goth, T. B. Transformations of synthetic birnessite as affected by pH and manganese concentration Clays and Clay Minerals 1994 42 321330 10.1346/CCMN.1994.0420310CrossRefGoogle Scholar
Villalobos, M., Toner, B., Bargar, J., Sposito, G. Characterization of the manganese oxide produced by Pseudomonas putida strain MnB1 Geochimica Et Cosmochimica Acta 2003 67 14 26492662 10.1016/S0016-7037(03)00217-5CrossRefGoogle Scholar
Wei, S. Y., Liu, F., Feng, X. H., Tan, W. F., Koopal, L. K. Formation and transformation of iron oxide-kaolinite associations in the presence of iron(II) Soil Science Society of America Journal 2011 75 1 4555 10.2136/sssaj2010.0175CrossRefGoogle Scholar
Won, J., Jeong, B., Lee, J., Dai, S., Burns, S. E. Facilitation of microbially induced calcite precipitation with kaolinite nucleation Geotechnique 2020 71 8 728734 10.1680/jgeot.19.P.324CrossRefGoogle Scholar
Yan, C. L., Liu, S., Min, H., Li, C., Zhu, Z. X., Lu, C. S., Gao, Q. Optimization and evaluation of the method for the determination of the manganese content in manganese ores and concentrates as described in ISO 4298:1984 Analytical and Bioanalytical Chemistry 2020 412 25 68236831 10.1007/s00216-020-02805-3CrossRefGoogle ScholarPubMed
Yang, D. S., Wang, M. K. Syntheses and characterization of birnessite by oxidizing pyrochroite in alkaline conditions Clays and Clay Minerals 2002 50 1 6369 10.1346/000986002761002685CrossRefGoogle Scholar
Yin, H., Wang, X., Qin, Z., Vogel, M. G., Zhang, S., Jiang, S., Liu, F., Li, S., Zhang, J., Wang, Y. Coordination geometry of Zn2+ on hexagonal turbostratic birnessites with different Mn average oxidation states and its stability under acid dissolution Journal of Environmental Sciences 2018 65 282292 10.1016/j.jes.2017.02.017CrossRefGoogle ScholarPubMed
Zhang, Q., Xiao, Z. D., Feng, X. H., Tan, W. F., Qiu, G. H., Liu, F. Alpha-MnO2 nanowires transformed from precursor delta-MnO2 by refluxing under ambient pressure: The key role of pH and growth mechanism Materials Chemistry and Physics 2011 125 3 678685 10.1016/j.matchemphys.2010.09.073CrossRefGoogle Scholar
Zhang, Q., Chen, X. D., Qiu, G. H., Liu, F., Feng, X. H. Size-controlled synthesis and formation mechanism of manganese oxide OMS-2 nanowires under reflux conditions with KMnO4 and inorganic acids Solid State Sciences 2016 55 152158 10.1016/j.solidstatesciences.2016.03.003CrossRefGoogle Scholar
Zhang, T. F., Liu, L. H., Tan, W. F., Suib, S. L., Qiu, G. H., Liu, F. Photochemical formation and transformation of birnessite: Effects of cations on micromorphology and crystal structure Environmental Science & Technology 2018 52 12 68646871 10.1021/acs.est.7b06592CrossRefGoogle ScholarPubMed
Zhao, H. Y., Liang, X. R., Yin, H., Liu, F., Tan, W. F., Qiu, G. H., Feng, X. H. Formation of todorokite from “c-disordered” H+-birnessites: The roles of average manganese oxidation state and interlayer cations Geochemical Transactions 2015 16 8 10.1186/s12932-015-0023-3CrossRefGoogle ScholarPubMed
Zhao, H. Y., Zhu, M. Q., Li, W., Elzinga, E. J., Villalobos, M., Liu, F., Zhang, J., Feng, X. H., Sparks, D. L. Redox reactions between Mn(II) and hexagonal birnessite change its layer symmetry Environmental Science & Technology 2016 50 17501758 10.1021/acs.est.5b04436CrossRefGoogle ScholarPubMed
Zhao, F. F., He, M. C., Wang, Y. T., Tao, Z. G., Li, C. Eco-geological environment quality assessment based on multi-source data of the mining city in red soil hilly region China. Journal of Mountain Science 2022 19 1 253275 10.1007/s11629-021-6860-xCrossRefGoogle Scholar
Zhu, M. Q., Vogel, M. G., Parikh, S. J., Feng, X. H., Sparks, D. L. Cation effects on the layer structure of biogenic Mn-oxides Environmental Science & Technology 2010 44 44654471 10.1021/es1009955CrossRefGoogle ScholarPubMed
Zhu, B. L., Qi, C. L., Zhang, Y. H., Teresa, B., Xu, Z. H., Fan, Y. G., Sun, Z. X. Synthesis, characterization and acid-base properties of kaolinite and metal (Fe, Mn, Co) doped kaolinite Applied Clay Science 2019 179 105138 10.1016/j.clay.2019.105138CrossRefGoogle Scholar
Figure 0

Fig. 1 XRD patterns of kaolinite-Mn oxide mineral complexes a with various molar ratios of Mn2+ to Mn7+ (R = 1:0.67, 1:1, 1:2, and 1:4); and b in the high-angle region. The synthesis temperature was controlled at 30°C, with Na+ as the background cation. 1 g of kaolinite was added. The labeled peaks are identified

Figure 1

Fig. 2 SEM images of kaolinite-Mn oxide mineral complexes with Na+ as the background cation; the R values were a 1:0.67, b 1:1, c 1:2, and d 1:4

Figure 2

Fig. 3 Mn content in kaolinite-Mn oxide mineral complexes with Mn2+ to Mn7+ molar ratios of 1:0.67, 1:1, 1:2, and 1:4, with Na+ as the background cation

Figure 3

Fig. 4 XRD patterns of products formed after treatment of kaolinite-Mn oxide complex a with background Mg2+cations; b without background cations; and c with background cations of Na+, Mg2+, and without background cations. The R value was 1:1. The labeled peaks are identified

Figure 4

Fig. 5 Mn content in kaolinite-Mn oxide mineral complexes with Mn2+ to Mn7+ molar ratios of 1:0.67, 1:1, 1:2, and 1:4, with Mg2+ as the background cation

Figure 5

Fig. 6 XRD patterns of kaolinite-Mn oxide mineral complexes formed with R = 1:4 and with 1 g of added kaolinite; the synthesis temperatures were 30, 60, and 110°C, with background a Na+ and b Mg2+ cations. The labeled peaks are identified

Figure 6

Fig. 7 Mn content in kaolinite-Mn oxide minerals under the background of a Na+, b Mg2+ at 30, 60, and 110°C, with the R value = 1:4 and the amount of kaolinite added was 1 g

Figure 7

Fig. 8 XRD patterns of a Mn oxide minerals and b kaolinite-Mn oxide mineral complexes formed when using the following amounts of kaolinite: 0.25, 0.5, 1.0, 2.0, and 5.0 g, with Na+ as the background cation; the value of R was 1:1; the synthesis temperature was 30°C

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