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Article

Analysis of Strength and Microstructural Characteristics of Mine Backfills Containing Fly Ash and Desulfurized Gypsum

1
State Key Laboratory of High-Efficient Mining and Safety of Metal Mines of Ministry of Education, University of Science and Technology Beijing, Beijing 100083, China
2
School of Civil and Resources Engineering, University of Science and Technology Beijing, Beijing 100083, China
3
Geotechnical Division, Department of Civil Engineering, Recep Tayyip Erdogan University, Fener, Rize TR53100, Turkey
*
Author to whom correspondence should be addressed.
Submission received: 14 March 2021 / Revised: 6 April 2021 / Accepted: 8 April 2021 / Published: 13 April 2021

Abstract

:
The utilization of solid wastes (SWs) as a potential resource for backfilling is not only conducive to environmental protection but also reduces the surface storage of waste. Two types of SWs, including fly ash (FA) and desulfurized gypsum (DG), were used to prepare cementitious backfilling materials for underground mined-out areas. Ordinary Portland cement (OPC) was used as cement in mine backfill. To better investigate the feasibility of preparing backfill materials, some laboratory tests, such as uniaxial compressive strength (UCS), scanning electron microscopy (SEM), and energy dissipation theory, were conducted to explore both strength and microstructural properties of backfilling. Results have demonstrated that the main components of FA and DG in this study are oxides, with few toxic and heavy metal components. The ideal ratio of OPC:FA:DG is 1:6:2 and the corresponding UCS values are 2.5 and 4.2 MPa when the curing time are 7 days and 14 days, respectively. Moreover, the average UCS value of backfilling samples gradually decreased when the proportion of DG in the mixture increased. The main failure modes of various backfilling materials are tensile and shearing cracks. In addition, the corresponding relations among total input energy, dissipated energy and strain energy, and stress–strain curve were investigated. The spatial distribution of oxygen, aluminum, silicon, calcium, iron and magnesium elements, and hydration product are explored from the microstructure’s perspective. The findings of this study provide both invaluable information and industrial applications for the efficient management of solid waste, based on sustainable development and circular economy.

1. Introduction

The extraction of ore resources has promoted the progress of human civilization, providing critical raw materials for sustainable development and circular economy [1,2]. However, it is irrefutable that resource mining has also caused a series of complications, such as water and air pollution [3], geotechnical risks [4], environmental hazards [5], farmland occupation [6], and tailings dam failures [7]. Solid waste output is growing at an annual rate of over 1 billion tons [8]. With the environmental protection policies and sustainable development goals, the whole use of solid waste has become a key strategy to building a resource-saving and environment-friendly city worldwide [9]. Solid wastes may cause some geotechnical and chemical instabilities if they are not well managed.
Wastes like fly ash (FA) and desulfurization gypsum (DG) are two main industrial solid wastes in Baotou city in Inner Mongolia, China [10]. Improving the utilization rate of FA and DG is one of the important technical problems to be solved by the industry [11]. At the moment, FA is mainly used as an additive for cement and the preparation of cementitious materials, while DG is mainly used to prepare gypsum-based new building materials [12,13]. Numerous scholars and engineers have conducted the feasibility of the above two types of solid waste utilization [14,15]. It was found that the risk assessment codes in FA posed no or low risk [16], while the heavy metals in DG showed a medium risk to the ecosystem [17]. In addition, the lime, FA, and DG were chosen as additives for investigating the solidification and stabilization of swelling soils [18]. Wang et al. [19] found that proper dosage and mineral additions affect the mechanical strength of the flue gas DG and FA system. Moreover, it was found experimentally that gypsum-based composites’ properties improved due to the synergistic effect between industrial wastes and straw fibers [20].
The existence of underground mined-out areas seriously threatened workers and equipment; on the other hand, it severely restricts the reform of mining methods [21]. Especially for mines where there are toxic elements (e.g., cyanide, arsenic, and lead) in the ore itself, this effect is even more obvious [22]. Tailings are called solid waste or hazardous waste after ore processing [23,24]. They can also be prepared concrete additives, backfilling, and construction materials [25,26]. However, tailings containing toxic elements or heavy metal ions cannot be used for filling underground voids according to the related environmental protection standards [27,28,29]. Thus, exploring the feasibility of using FA and DG to prepare mine backfilling is the main purpose of this study. Scholars have so far used backfill samples with ecofriendly binders [30,31] and cement-based composites [32] on a single or combination of FA [33,34] and DG [35,36] as industrial waste.
In this study, cement, FA, and DG are utilized to prepare the backfill materials for underground voids. A series of laboratory tests, including uniaxial compressive strength, energy dissipation theory, and scanning electron microscopy, are conducted. The present study investigates the particle size distribution and chemical composition of FA and DG, strength and loading energy development, and cement-based backfills’ microstructural characteristics. This study’s main contribution is that it can provide a reliable reference for the feasibility of preparing mine backfills prepared with solid waste.

2. Materials and Methods

2.1. Materials

2.1.1. Characteristics of FA and DG

In this study, two solid wastes (e.g., FA and DG) obtained from Inner Mongolia were selected as additive materials for preparing the tested mine backfill specimens. Particle size distributions of these two materials were measured by the LSPOP (9) laser particle size analyzer (OMEC, Zhuhai, China). Figure 1 shows the particle size distributions of both FA and DG materials. Moreover, the physical properties of FA and DG materials were shown in Table 1.
The chemical composition of both FA and DG was tested by using the sequential X-ray fluorescence spectrometer from the University of Science and Technology Beijing, Beijing, China. The basic parameter including scanning velocity, voltage, and current were 300/min, 60 kV, and 140 mA, respectively. The X-ray fluorescence spectrometry was conducted to investigate the chemical composition of tested mine specimens in this study. The cement composition of FA and DG materials were listed in Figure 2.

2.1.2. Binder and Water

In this study, the ordinary Portland cement from Chengxin Cement Manufacturing Co., Ltd from Tanshan in China named OPC 42.5R was selected as a basic binder for preparing the mine fill samples. The chemical composition of the cement used was shown in Table 2. Tap water was used to mix the FA, DG, and cement.

2.2. Specimens Preparation and Curing Conditions

Firstly, an electronic scale named AUW120D 220D with an accuracy of 0.01 g from Japan was used to weigh the FA, cement, DG, and water. Secondly, dry cement, FA, and DG were mixed at least for 3 min. Tap water was poured into the stirring tank, and then the JJ-5 cement mortar mixer produced by Wuxi Jianyi Instrument Machinery Co., Ltd. was used to mix for 3 min again until the slurry was fully dispersed. The diameter and height of cylindrical molds were 50 and 100 mm, respectively. Note that a recent experimental work by Yilmaz et al. [37] has been checking specimen size effect on compressive strength of cemented tailings or paste backfills, showing that samples with a diameter of 5 and 10 cm in height always gave better strength performance than other sample sizes (D × H: 7.5 cm × 15 cm and 10 cm × 20 cm) for a given cemented tailings backfill recipe. The slurry was poured into the molds and then placed in a curing box named HSBY-40B. The temperature and humidity were set as 20 ± 1 °C and 90 ± 5%. The curing time were set as 7 and 14 days in this study. Figure 3 shows the entire process of the mine filling specimen preparation.
In this section, the cement-to-solid waste (FA and DG) ratio was set as 1:8. Table 3 shows the proportion of each component of each sample in each group. Among them, “F-8-D-0”, “F-6-D-2”, “F-4-D-4”, “F-2-D-6”, and “F-0-D-8” indicated the number of each tested specimens, the number after F indicated the proportion of FA for each tested specimen, and the number after D indicated the proportion of DG for each tested specimen. In the five groups, each group of six specimens, a total of 30 specimens were tested.

2.3. Uniaxial Compressive Tests

In this study, the both ends of the tested mine fill specimens’ sections were polished to ensure flatness. As shown in Figure 4, the uniaxial compressive tests were performed to obtain their uniaxial compressive strength (UCS). The wdwi-100 loading system of the Materials Center of the University of Science and Technology Beijing (Beijing) was used for UCS testing. The loading rate was set as a fixed speed of 1 mm/min. To reduce the test errors, each group of uniaxial compression tests contained three specimens to obtain the mean UCS values for the final evaluation. The experimental data could be recorded and stored in the computer during the whole loading process.

2.4. Principle of Energy Dissipation

It is known that the materials including rock, steel, and other cement-based materials deformed during the whole loading process [38] assuming that there was no heat exchanged between the physical process and the outside world. It was a closed system, and the total input energy generated by the external force was U. According to the first law of thermodynamics [39,40], we could obtain the below equations.
U = 0 ε σ d ε
U e = 1 2 E 0 σ 2
The U d was determined as:
U d = U U e
In Equations (1)–(3), U was the total input energy, MJ·m −3; U d was the dissipation energy, MJ·m −3; U e was the strain energy that the specimens can release, MJ·m −3; E was the unloaded elastic modulus of the samples, MPa, here was replaced by the initial elastic modulus E 0 ; ε was the strain of the samples; and σ was the sample’s stress. Figure 5 showed the relationship between the dissipation energy and the releasable strain energy.

2.5. Scanning Electron Microscopy Analysis

The microstructure characteristics of the mine backfill specimens were investigated using a scanning electron microscope (SEM: Zeiss EVO18, Carl Zeiss AG, Oberkochen, Germany) system. The basic parameters of the microscope used were as follows: the accelerating voltage was between 10 and 20 kV; the maximum magnification and resolution were 2000 times and 3 nm, respectively. Before the experiment, the observed samples were dried, and then mine filling samples were sprayed with diamond by vacuum coating [41,42]. The processed samples could be observed by SEM. Figure 6 shows the SEM observation process.

3. Results and Discussion

3.1. Effect of FA/DG Ratio on the UCS

Table 4 shows the UCS values of specimens prepared with different FA and DG proportions after curing times of 7 and 14 days. In Table 4, “1, 2, and 3” represented three specimens’ number with the same ratio. It should be emphasized that the “F-6-D-2-2” specimens in the 7 and 14 day curing time did not meet the test requirements; therefore, the data were deleted. The average UCS values of mine fill samples prepared with different solid-to-waste ratios after curing time of 7 and 14 days were shown in Figure 7.
It could be obtained that the average UCS values of the samples cured at 7 and 14 days varies with the solid-to-waste ratios. The ideal ratio was 1:6:2 (OPC:FA:DG), the average UCS values for 7 days of curing time has reached 2.49 MPa, and the average UCS value reached 4.20 MPa after curing time of 14 days. In addition, the average UCS values of the mine backfill specimens gradually decreased when the proportion of DG increased. However, the minimum average UCS value of the F-0-D-8 specimen was 0.43 MPa when the curing time was 7 days. The main reason behind this behavior was that much more DG content would affect more hydration products generated inside the tested specimens. Moreover, the UCS values of tested F-8-D-0 mine fill specimens were not so large because of the hydration reaction inside the specimens was not obvious. Accordingly, the average UCS values of tested F-6-D-2 specimens in this section could meet the UCS requirement of the cut and fill mining method.

3.2. Effect of FA/DG Ratio on Stress–Strain Relation

Figure 8a,b show the relationship between stress–strain of tested mine filling specimens when the curing time were 7 and 14 days, respectively.
In general, the stress–strain curves can divide into four stages: (1) Pore compaction stage: there would be lots of pores in the tested specimens due to FA and DG particles. These pores would be compacted when the pressure increased during this stage, resulting in a concave stress–strain curve. (2) Linear elastic stage: the strain also increased with the pressure increased. Thus, the curve became a straight line. (3) Unstable rupture stage: the elastic deformation turned into plastic deformation during this stage. The UCS values gradually reached their peak with cracks growth. (4) Crack propagation stage: after the samples reached their peak, as the pressure increased, the samples’ crack expanded until samples was failed. It was also found that the F-6-D-2 and F-4-D-4 tested specimens showed strong brittleness after UCS reached the peak values. However, the UCS values of F-8-D-0, F-2-D-6, and F-0-D-8 tested mine backfill specimens were not so large. The specimens showed a good ductility after reaching their UCS values.
The UCS values of the tested specimens increased with the curing time increased. The chemical hydration reaction became more adequate, and the hydration products were more produced with time. Moreover, the hydration products filled up the pores and cracks in the tested cement-based composites specimens, resulting in denser specimens. Therefore, the UCS values of tested filling specimens were improved accordingly.

3.3. Energy Dissipation Analysis

Figure 9 showed the stress–strain and energy evolution curves of the tested specimens. It was found that the input energy and the dissipation energy showed a nonlinear growth trend with the axial strain increased.
However, the elastic strain energy increased firstly and then decreased combining with the specimens’ failure process during the uniaxial compression tests. It was also obtained that the energy dissipation characteristics and energy distribution laws of the specimens were different in different deformation stages. The elastic strain energy in the samples occupied a dominant position before the peak failure.
Most of the input energy was converted into elastic strain energy and stored inside samples. Samples’ elastic energy slows down, while the dissipated energy increased after entering the plastic rupture stage. When the crack increased sharply, the crack accelerated and expanded. After reaching the UCS location, the cracks’ growth trend further increased. The elastic energy accumulated was suddenly released and converted into the dissipation energy. At last, the tested mine backfill specimens were failed eventually.

3.4. The Failure Modes of BMs

Figure 10 shows the failure modes of the tested mine backfill samples with different proportions in the UCS test. It was found that the main failure modes of the F-8-D-0 and F-4-D-4 specimens were tensile failure along the loading direction. However, shear cracks mainly appeared on the surface of the F-2-D-6 and F-0-D-8 specimens. Moreover, both the shear and tensile cracks appeared on the surface of the F-6-D-2 specimen. It was also obtained that each tested mine fill sample in this study showed obvious brittleness corresponding to the stress–strain curves. With the increase of the axial loading pressure, the cement-based composites specimens showed that the accelerated crack propagation and fragments fell off the surface of the specimen.

3.5. Microstructural Characteristics Analysis

Figure 11 shows that SEM images of tested mine backfill samples with five different solid waste ratios when the curing time was 7 days. The ImageJ software was used to explore the microstructure of the tested backfill samples. Figure 11a shows the microstructural diagram of the F-8-D-0 samples. It was found that there were many large-size particles of FA on the sample’s surface. There were also many pores on the tested specimen’s surface. Moreover, the maximum particle size of FA and the largest pore size were 29.06 μm and 24.62 μm, respectively. It was also found from Figure 11b that a large amount of hydration products including calcium silicate hydrate (C-S-H), and few pores appeared on the solid-phase particles’ surface. Moreover, the surface of the F-6-D-2 sample was much denser than other mine fill samples in this study. As shown in Figure 11c, lots of large-size pores existed on the F-4-D-4 sample’s surface, and the maximum size reached 40.94 μm. Moreover, there were still lots of large-particle DG pieces and pores on the surface of the F-2-D-6 and F-0-D-8 mine fill samples, as demonstrated in Figure 11d,e.
The element distribution mappings of the specimens’ SEM images were shown from Figure 12, Figure 13, Figure 14, Figure 15 and Figure 16. As shown in Figure 12, it was found that the Si, Al, and O elements were concentrated in the large amounts at the FA particles’ location, which were consistent with the XRF analysis results (Figure 2). In Figure 13, the hydration reaction proceeded sufficiently and produced a large amount of flocculating substances. According to the element distribution, it was speculated that these flocculating substances were C-S-H formed by the reaction of CaO, Al2O3, SiO2, and water. Moreover, the UCS values of the mine backfill specimens were strengthened because of the appearance of these C-S-H gels. Moreover, the elements including Ca, S, and O gathered in large amounts at the DG particles’ locations with the proportion of DG increased, which were shown in Figure 14, Figure 15 and Figure 16. The presence of these DG particles directly caused the UCS values of the mine backfill specimens to decrease.

4. Conclusions

To explore the mechanical and microstructural characteristics of cement-based solid waste composites, some lab experiments such as uniaxial compressive strength, energy dissipation, and scanning electron microscopy were conducted. From the performed tests, the following results can be drawn:
(1)
The UCS results shown that the ideal backfill mix (OPC:FA:DG/1:6:2) provided a strength gain of 2.49 and 4.20 MPa for a curing time of 7 and 14 days, respectively.
(2)
The mean strengths of mine fills steadily decreased with increasing DG content. The obtained strengths meet the criteria required for the cut and fill mining system.
(3)
The total input energy and elastic strain energy showed a nonlinear growth trend with increasing loads. The elastic strain energy increased first and then decreased.
(4)
The dissipative energy grew gradually before samples failed. The elastic energy values accumulated in samples were suddenly released and converted into dissipative energy when samples were closed to failure.
(5)
A typical backfill failure mode was tensile along the loading direction and shear cracks. Samples showed obvious brittleness corresponding to their stress–strain curves.
(6)
Hydration products including calcium silicate hydrate on the surface of the ideal backfill mix were denser and had less porosity, which verified the high UCS value.
As a result, the findings of this research work have proven the feasibility of using fly ash and desulfurized gypsum to prepare backfills for underground mines. It is also good to notice that further investigations on optimization of the dosages of solid wastes used within mine backfill samples are now in progress.

Author Contributions

Conceptualization, S.C.; methodology, Z.H.; writing—original draft preparation, Z.H.; writing—review and editing and supervision, E.Y. and S.C.; funding acquisition, S.C. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Natural Science Foundation of China (Grant numbers 51804017) and the Fundamental Research Funds for Central Universities (Grant number FRF-TP-20-001A2).

Data Availability Statement

No applicable.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Particle size distributions of fly ash (FA) and desulfurization gypsum (DG) materials.
Figure 1. Particle size distributions of fly ash (FA) and desulfurization gypsum (DG) materials.
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Figure 2. Chemical composition of FA and DG materials.
Figure 2. Chemical composition of FA and DG materials.
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Figure 3. The preparation process of tested specimens.
Figure 3. The preparation process of tested specimens.
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Figure 4. Photo of testing apparatus implemented in this study.
Figure 4. Photo of testing apparatus implemented in this study.
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Figure 5. The relationship between U d and U e .
Figure 5. The relationship between U d and U e .
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Figure 6. Photos of the used ZEISS EVO18 SEM system for microstructural investigations.
Figure 6. Photos of the used ZEISS EVO18 SEM system for microstructural investigations.
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Figure 7. Average compressive strength of 7 day and 14 day cured backfill specimens.
Figure 7. Average compressive strength of 7 day and 14 day cured backfill specimens.
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Figure 8. Stress–strain curves of the tested backfill specimens: a curing time of 7 days (a) and 14 days (b).
Figure 8. Stress–strain curves of the tested backfill specimens: a curing time of 7 days (a) and 14 days (b).
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Figure 9. Samples’ stress–strain and energy evolution curves: (a) F-8-D-0; (b) F-6-D-2; (c) F-4-D-4; (d) F-2-D-6; and (e) F-0-D-8.
Figure 9. Samples’ stress–strain and energy evolution curves: (a) F-8-D-0; (b) F-6-D-2; (c) F-4-D-4; (d) F-2-D-6; and (e) F-0-D-8.
Minerals 11 00409 g009aMinerals 11 00409 g009b
Figure 10. Failure modes of mine backfill specimens with different proportions under uniaxial compression.
Figure 10. Failure modes of mine backfill specimens with different proportions under uniaxial compression.
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Figure 11. SEM image of 7 day cured specimens: (a) F-8-D-0; (b) F-6-D-2; (c) F-4-D-4; (d) F-2-D-6; and (e) F-0-D-8.
Figure 11. SEM image of 7 day cured specimens: (a) F-8-D-0; (b) F-6-D-2; (c) F-4-D-4; (d) F-2-D-6; and (e) F-0-D-8.
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Figure 12. SEM elemental mapping of the F-8-D-0 specimen.
Figure 12. SEM elemental mapping of the F-8-D-0 specimen.
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Figure 13. SEM elemental mapping of the F-6-D-2 specimen.
Figure 13. SEM elemental mapping of the F-6-D-2 specimen.
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Figure 14. SEM elemental mapping of the F-4-D-4 specimen.
Figure 14. SEM elemental mapping of the F-4-D-4 specimen.
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Figure 15. SEM elemental mapping of the F-2-D-6 specimen.
Figure 15. SEM elemental mapping of the F-2-D-6 specimen.
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Figure 16. SEM elemental mapping of the F-0-D-8 specimen.
Figure 16. SEM elemental mapping of the F-0-D-8 specimen.
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Table 1. Physical parameters of FA and DG materials.
Table 1. Physical parameters of FA and DG materials.
MaterialsD10 (μm)D25 (μm)D50 (μm)D75 (μm)D90 (μm)Specific Surface Area (m2/kg)
FA2.7668.06746.324163.687499.833737.135
DG7.43124.24144.355127.431417.263353.377
Table 2. Chemical composition of ordinary Portland cement (OPC) 42.5R.
Table 2. Chemical composition of ordinary Portland cement (OPC) 42.5R.
Chemical CompositionSiO2Fe2O3Al2O3MgOCaOSO3K2O
content (%)20.12.915.111.5761.81.980.37
Table 3. The proportions of each component of each specimen.
Table 3. The proportions of each component of each specimen.
No.OPC (wt. %)FA (wt. %)DG (wt. %)Water (wt. %)
F-8-D-07.862.20.0030
F-6-D-27.846.715.530
F-4-D-47.831.131.130
F-2-D-67.815.546.730
F-0-D-87.80.0062.230
Table 4. The uniaxial compressive strength (UCS) results of the tested mine backfill specimens.
Table 4. The uniaxial compressive strength (UCS) results of the tested mine backfill specimens.
Test
No.
UCS
(MPa)
Test
No.
UCS
(MPa)
Test
No.
UCS
(MPa)
Curing Times: 7 days
F-8-D-0-10.50F-6-D-2-12.52F-4-D-4-11.03
F-8-D-0-20.55F-6-D-2-2/F-4-D-4-21.00
F-8-D-0-30.54F-6-D-2-32.45F-4-D-4-31.02
Average:0.53Average:2.49Average:1.02
F-2-D-6-10.53F-0-D-8-10.47
F-2-D-6-20.60F-0-D-8-20.38
F-2-D-6-30.50F-0-D-8-30.44
Average:0.54Average:0.43
Curing Times: 14 days
F-8-D-0-10.96F-6-D-2-14.35F-4-D-4-13.34
F-8-D-0-20.83F-6-D-2-2/F-4-D-4-23.04
F-8-D-0-31.00F-6-D-2-34.06F-4-D-4-32.91
Average:0.93Average:4.20Average:3.10
F-2-D-6-12.23F-0-D-8-11.07
F-2-D-6-22.18F-0-D-8-21.11
F-2-D-6-32.34F-0-D-8-30.91
Average:2.25Average:1.03
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Huang, Z.; Yilmaz, E.; Cao, S. Analysis of Strength and Microstructural Characteristics of Mine Backfills Containing Fly Ash and Desulfurized Gypsum. Minerals 2021, 11, 409. https://0-doi-org.brum.beds.ac.uk/10.3390/min11040409

AMA Style

Huang Z, Yilmaz E, Cao S. Analysis of Strength and Microstructural Characteristics of Mine Backfills Containing Fly Ash and Desulfurized Gypsum. Minerals. 2021; 11(4):409. https://0-doi-org.brum.beds.ac.uk/10.3390/min11040409

Chicago/Turabian Style

Huang, Zhiqiang, Erol Yilmaz, and Shuai Cao. 2021. "Analysis of Strength and Microstructural Characteristics of Mine Backfills Containing Fly Ash and Desulfurized Gypsum" Minerals 11, no. 4: 409. https://0-doi-org.brum.beds.ac.uk/10.3390/min11040409

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