Preparation of Black Ceramic Tiles Using Waste Copper Slag and Stainless Steel Slag of Electric Arc Furnace

Copper slag and stainless steel slag of Electric Arc Furnace (EAF) are two typical metallurgical solid wastes, which contain a large number of valuables, such as Fe, Cr, and Cu. The transition metal elements in the waste slags, such as Cr and Fe, can be recycled as the coloring ions in the black ceramic tile. In this study, the Fe/Cr molar ratio in the raw materials of copper slag and stainless steel slag was adjusted, and the black ceramic tile was subsequently prepared by sintering. The results show that the optimum process parameters for the preparation of black ceramic tiles are the Fe/Cr molar ratio of 2.0, the sintering temperature of 1150 °C, and the sintering time of 30 min. The compressive strength of the black ceramic tile at optimum sintering conditions exceeds the minimum compressive strength of the Chinese national standard for standard polished tiles, and the concentrations of harmful elements, for example, Cr, Cu, Ni, As, Zn, Pb, and Cr(VI) are within the regulation thresholds specified by the Chinese national standard.


Introduction
According to the U.S. Geological Survey (USGS), the total global mine production of copper in 2018 was 21,000 thousand metric tons [1]. The International Copper Study Group (ICSG) predicted the growth of 2.8% in 2019 and 1.2% in 2020 as for global refined copper production [2], and China will continue to be the world's top contributor to world refined copper growth in 2020 [3].
Copper slag is an industrial by-product of copper smelting and refining from copper ores [4]. Typically, approximately 2.2-3.0 tons of copper slag can be obtained by producing one ton of copper [5], and it is estimated that~24.6 million tons of copper slag is produced annually [6]. There are 30-50 wt% Fe, 0.5-2.1 wt% Cu, 25-35 wt% SiO 2 and~1 wt% Zn in the copper slag [7][8][9][10]. Therefore, the recovery of valuable components in copper slag is of great significance.
In recent years, the output of the stainless steel of Electric Arc Furnace (EAF) has also increased continuously. According to the statistical reports of the International Stainless Steel Forum (ISSF), the global stainless steel melts shop production increased 5.5 % amount to 50.7 million tons in 2018, of which the Chinese stainless steel melt shop contributed about 52.7 % [11].
The stainless steel slag of EAF is a by-product of the stainless steel smelting process in EAF [12]. Generally, the stainless steel slag of EAF contains 40-50 % CaO, 5-10 % Fe 2 O 3 , <10 % Cr 2 O 3 , and <2 % in order to provide theoretical and experimental basis for the harmless and value-added application of copper slag and stainless steel slag of EAF.

Raw Materials
The waste copper slag was collected from a copper smelting plant in central China where the copper slag was impoverished and floated for copper recovery. The stainless steel slag of EAF was sampled in a domestic stainless steel mill.

Chemical Composition, Crystalline Phase, and Microstructure
The chemical compositions of copper slag and stainless steel slag were analyzed by inductively coupled plasma emission spectrometer (ThemoElemental IRIS Advantage Radial, America). The crystalline phases were identified using an X-ray powder diffractometer (PANalytical X'Pert PRO MPD, Netherlands) with Cu Kα radiation at a tube voltage of 40 kV, current of 40 mA and 2 theta scanning ranging from 15 • to 80 • . The microstructures of the waste slags were examined with a field emission scanning electron microscope (FEI Nova NanoSEM400, FEI, Hillsboro, Oregon, America).

Thermogravimetric Test
Approximately 10 mg copper slag and 10 mg stainless steel slag were, respectively, weighed and heated to 1200 • C at the heating speed of 10 • C /min in the air atmosphere using a thermogravimetric analyzer (NETZSCH STA 449F3, Selb, Germany) to monitor the relationship between the gravity and temperature of copper slag and EAF stainless steel slag.

Preparation of Black Ceramic Tile
The copper slag and the EAF stainless steel slag were ground to a particle size of 200 mesh or less using a planetary ball mill (QM-3SP4, Nanjing Chi Shun Technology Development Co., Ltd, Nanjing, China) and dried in an oven at 100 • C for 24 hours. It was subsequently mixed in a certain ratio (Fe/Cr molar ratio is 0.5-2.5), and pressed into cylindrical specimens with a diameter of~2 cm using a conventional press at a pressure of 25 MPa. Then, the samples were placed in a muffle furnace (SX2-10-13, Shanghai Shi Yan Electric Furnace Co., Ltd, Shanghai, China) and sintered in an air atmosphere at ambient pressure to obtain black ceramic tile samples. The experimental process parameters are shown in Table 1. The heating speed of the furnace was about 10 • C/min and the samples were cooled down to room temperature in the muffle furnace. Subsequently, the long-term leaching behavior and physical properties of ceramic cylinders were tested.

Coloration Performance of Black Ceramic Tiles
The L*, a*, and b* color space developed by the International Commission on Illumination (CIE) is a device-independent color model. In this system, L* is the degree of lightness and darkness of the color in relation to the scale extending from white (L* = 100) to black (L* = 0). a* is the degree of green (−a*) and red (+a*), b* is the degree of blue (−b*) and yellow (+b*) [25]. In this work, the color of the ceramic tile was characterized by L*, a*, and b* color space, and the L*, a*, and b* values of the tile were measured using a portable chromatic aberration meter (SC10 NR10QC). For black ceramic titles, the closer L*, a*, and b* are to 0, the better the coloration performance.

Leaching Test and Compression Resistance of Black Ceramic Tiles
In this study, the environmental protection industry standard of China HJ/T299-2007 [30] was adopted to carry out the leaching test of toxic substances in ceramic tiles. In this test, concentrated nitric acid and concentrated sulfuric acid with the mass ratio of 1:2 were firstly added to deionized water to prepare the leaching agent with the pH of 3.2 ± 0.05. The powder sample and the leaching agent were added to a 100 ml glass bottle and sealed to ensure the solid and liquid ratio of 1:10 (g/mL). At 23 ± 2 • C, the mixture was shaken by an end-over-end homogenizer with the rotation speed of 30 ± 2 r/min for 18 ± 2 h. After filtration, the contents of Cr, Cu, Ni, As, Zn, Pb, and Cr(VI) in the leachate were measured. The concentration of Cr(VI) was determined by spectrophotometry (Model 722 spectrophotometer, Beijing Century Science Instrument Co., Ltd, Beijing, China), whereas the concentration of other leachable toxic elements was determined by the ICP-AES. The ceramic tile was also subjected to a compression test using a hydraulic universal test machine (WE-30, Tai Tian machinery Jiangsu Co., Ltd, Jiangsu, China).

Chemical Composition and Crystalline Phases
The chemical compositions of EAF stainless steel slag and copper slag are shown in Table 2. The main chemical constituents of copper slag used in this study are Fe 2 O 3 and SiO 2 , the content of them are 52.69% and 33.44%, respectively, whereas the main chemical constituents of stainless steel slag are SiO 2 , CaO, and Cr 2 O 3 , which account for about 70 % of the total content.  [7,9,[13][14][15]. In this study, the environmental protection industry standard of China HJ/T299-2007 [30] was adopted to carry out the leaching test of toxic substances in ceramic tiles. In this test, concentrated nitric acid and concentrated sulfuric acid with the mass ratio of 1:2 were firstly added to deionized water to prepare the leaching agent with the pH of 3.2 ± 0.05. The powder sample and the leaching agent were added to a 100 ml glass bottle and sealed to ensure the solid and liquid ratio of 1:10 (g/mL). At 23 ± 2 °C, the mixture was shaken by an end-over-end homogenizer with the rotation speed of 30 ± 2 r/min for 18 ± 2 h. After filtration, the contents of Cr, Cu, Ni, As, Zn, Pb, and Cr(VI) in the leachate were measured. The concentration of Cr(VI) was determined by spectrophotometry (Model 722 spectrophotometer, Beijing Century Science Instrument Co., Ltd, Beijing, China), whereas the concentration of other leachable toxic elements was determined by the ICP-AES. The ceramic tile was also subjected to a compression test using a hydraulic universal test machine (WE-30, Tai Tian machinery Jiangsu Co., Ltd, Jiangsu, China).

Chemical Composition and Crystalline Phases
The chemical compositions of EAF stainless steel slag and copper slag are shown in Table 2. The main chemical constituents of copper slag used in this study are Fe2O3 and SiO2, the content of them are 52.69% and 33.44%, respectively, whereas the main chemical constituents of stainless steel slag are SiO2, CaO, and Cr2O3, which account for about 70 % of the total content.  Figure 1 shows the XRD patterns of copper slag and stainless steel slag of EAF, respectively. It indicates that the main crystalline phases of copper slag are Fe2SiO4 and Fe3O4. The stainless steel slag mainly consists of spinels, such as FeCr2O4, MgCr2O4, NiCr2O4, and Fe3O4, which is consistent with previous studies [7,9,[13][14][15].

Thermogravimetric Analysis
Thermogravimetric curves of copper slag and stainless steel slag are shown in Figure 2. The results show that the mass of copper slag decreases with increasing temperature below 310 °C, mainly

Thermogravimetric Analysis
Thermogravimetric curves of copper slag and stainless steel slag are shown in Figure 2. The results show that the mass of copper slag decreases with increasing temperature below 310 • C, mainly due to the presence of moisture in the slag and the dehydration reaction of the crystalline hydrate in the copper slag. The mass of the copper slag increases with the temperature above 310 • C, which is mainly due to the oxidation of Fe 2 SiO 4 and Fe 3 O 4 in the slag and the chemical reaction are as shown in the Equations (1) and (2) [6,7,9]. The mass of the stainless steel slag of EAF increases with temperature after 500 • C possibly due to the oxidation of Fe 3 O 4 in the slag.
Materials 2020, 13, x FOR PEER REVIEW 5 of 13 due to the presence of moisture in the slag and the dehydration reaction of the crystalline hydrate in the copper slag. The mass of the copper slag increases with the temperature above 310 °C, which is mainly due to the oxidation of Fe2SiO4 and Fe3O4 in the slag and the chemical reaction are as shown in the Equations (1) and (2) [6,7,9]. The mass of the stainless steel slag of EAF increases with temperature after 500 °C possibly due to the oxidation of Fe3O4 in the slag. 2Fe2SiO4 + O2→2Fe2O3 + 2SiO2

Effect of Fe/Cr Molar Ratio on the Coloration Performance of Ceramic Tiles
Figures 3 and 4 show the photograph of the ceramic tile samples sintered at different Fe/Cr molar ratios and the XRD patterns of ceramic tiles prepared under different Fe/Cr molar ratios, respectively. It can be found in Figure 3 that the color of ceramic tiles become darker as the Fe/Cr molar ratios increased from 0.5 to 2.0. Moreover, there are no cracks or defects on the surface of ceramic tiles. However, when the Fe/Cr =2.5, the tile surface is slightly expanded. As shown in Figure 4, the chromite spinel (FeCr2O4) is the main crystalline phase of black ceramic tile samples prepared at 1150 °C. Moreover, Cr1.3Fe0.7O3 also present in the ceramic tile samples, which is formed by the reaction of Fe2O3 and Cr2O3. Meanwhile, CaMgSi2O6 exists as a minor component. With the increase of Fe/Cr molar ratio, the contents of Cr1.3Fe0.7O3 and FeCr2O4 increase, whereas the content of Fe2O3 decreases, possibly due to the further reaction of Fe2O3 and Cr2O3 in the mixture to form Cr1.3Fe0.7O3 and FeCr2O4.  Figure 5 shows the effects of the Fe/Cr molar ratio on the coloration of ceramic tiles. As the Fe/Cr molar ratio increases, the L* value decreases firstly. This is because the increased Fe2O3 content in the material reacts with Cr2O3 to generate large amounts of Cr1.3Fe0.7O3 and FeCr2O4. Therefore, it enhances the black chromaticity value of the ceramic tile. Moreover, note that when the Fe/Cr molar ratio is higher than 1.0, L* value increases gradually. This is possibly due to that the increased Fe2O3 and Cr2O3 reaction at this time mainly generate Cr1.3Fe0.7O3, while FeCr2O4 content is relatively less than that in Fe/Cr = 1.0, and weakens the black chromaticity value of the ceramic tile.  It can be found in Figure 3 that the color of ceramic tiles become darker as the Fe/Cr molar ratios increased from 0.5 to 2.0. Moreover, there are no cracks or defects on the surface of ceramic tiles. However, when the Fe/Cr =2.5, the tile surface is slightly expanded. As shown in Figure  due to the presence of moisture in the slag and the dehydration reaction of the crystalline hydrate in the copper slag. The mass of the copper slag increases with the temperature above 310 °C, which is mainly due to the oxidation of Fe2SiO4 and Fe3O4 in the slag and the chemical reaction are as shown in the Equations (1) and (2) [6,7,9]. The mass of the stainless steel slag of EAF increases with temperature after 500 °C possibly due to the oxidation of Fe3O4 in the slag. 2Fe2SiO4 + O2→2Fe2O3 + 2SiO2

Effect of Fe/Cr Molar Ratio on the Coloration Performance of Ceramic Tiles
Figures 3 and 4 show the photograph of the ceramic tile samples sintered at different Fe/Cr molar ratios and the XRD patterns of ceramic tiles prepared under different Fe/Cr molar ratios, respectively. It can be found in Figure 3 that the color of ceramic tiles become darker as the Fe/Cr molar ratios increased from 0.5 to 2.0. Moreover, there are no cracks or defects on the surface of ceramic tiles. However, when the Fe/Cr =2.5, the tile surface is slightly expanded. As shown in Figure 4, the chromite spinel (FeCr2O4) is the main crystalline phase of black ceramic tile samples prepared at 1150 °C. Moreover, Cr1.3Fe0.7O3 also present in the ceramic tile samples, which is formed by the reaction of Fe2O3 and Cr2O3. Meanwhile, CaMgSi2O6 exists as a minor component. With the increase of Fe/Cr molar ratio, the contents of Cr1.3Fe0.7O3 and FeCr2O4 increase, whereas the content of Fe2O3 decreases, possibly due to the further reaction of Fe2O3 and Cr2O3 in the mixture to form Cr1.3Fe0.7O3 and FeCr2O4.  Figure 5 shows the effects of the Fe/Cr molar ratio on the coloration of ceramic tiles. As the Fe/Cr molar ratio increases, the L* value decreases firstly. This is because the increased Fe2O3 content in the material reacts with Cr2O3 to generate large amounts of Cr1.3Fe0.7O3 and FeCr2O4. Therefore, it enhances the black chromaticity value of the ceramic tile. Moreover, note that when the Fe/Cr molar ratio is higher than 1.0, L* value increases gradually. This is possibly due to that the increased Fe2O3 and Cr2O3 reaction at this time mainly generate Cr1.3Fe0.7O3, while FeCr2O4 content is relatively less than that in Fe/Cr = 1.0, and weakens the black chromaticity value of the ceramic tile.  Figure 5 shows the effects of the Fe/Cr molar ratio on the coloration of ceramic tiles. As the Fe/Cr molar ratio increases, the L* value decreases firstly. This is because the increased Fe 2 O 3 content in the material reacts with Cr 2 O 3 to generate large amounts of Cr 1.3 Fe 0.7 O 3 and FeCr 2 O 4 . Therefore, it enhances the black chromaticity value of the ceramic tile. Moreover, note that when the Fe/Cr molar ratio is higher than 1.0, L* value increases gradually. This is possibly due to that the increased Fe 2 O 3 and Cr 2 O 3 reaction at this time mainly generate Cr 1.3 Fe 0.7 O 3 , while FeCr 2 O 4 content is relatively less than that in Fe/Cr = 1.0, and weakens the black chromaticity value of the ceramic tile.  As the Fe/Cr molar ratio increase in the materials, the values of +a* and +b* gradually decrease. The ceramic tile sample becomes reddish with the increasing of +a* value. This may be due to the presence of small amounts of unreacted Fe2O3 in the ceramic tile. A larger value of +b* indicates that the sample is yellowish and certain amounts of Ca are contained in ceramic tiles, which may influence the coloration of Fe 3+ to make it brownish [29].
Therefore, the optimum Fe/Cr molar ratio of the mixed slag material for better coloration performance is 2.0, after considering the changes in the values of L*, a*, and b* of black ceramic tile and the contents of Cr1.3Fe0.7O3 and FeCr2O4.   As the Fe/Cr molar ratio increase in the materials, the values of +a* and +b* gradually decrease. The ceramic tile sample becomes reddish with the increasing of +a* value. This may be due to the presence of small amounts of unreacted Fe2O3 in the ceramic tile. A larger value of +b* indicates that the sample is yellowish and certain amounts of Ca are contained in ceramic tiles, which may influence the coloration of Fe 3+ to make it brownish [29].

Effect of Sintering Temperature on the Coloration Performance of Ceramic Tiles
Therefore, the optimum Fe/Cr molar ratio of the mixed slag material for better coloration performance is 2.0, after considering the changes in the values of L*, a*, and b* of black ceramic tile and the contents of Cr1.3Fe0.7O3 and FeCr2O4. As the Fe/Cr molar ratio increase in the materials, the values of +a* and +b* gradually decrease. The ceramic tile sample becomes reddish with the increasing of +a* value. This may be due to the presence of small amounts of unreacted Fe 2 O 3 in the ceramic tile. A larger value of +b* indicates that the sample is yellowish and certain amounts of Ca are contained in ceramic tiles, which may influence the coloration of Fe 3+ to make it brownish [29].

Effect of Sintering Temperature on the Coloration Performance of Ceramic Tiles
Therefore, the optimum Fe/Cr molar ratio of the mixed slag material for better coloration performance is 2.0, after considering the changes in the values of L*, a*, and b* of black ceramic tile and the contents of Cr 1.3 Fe 0.7 O 3 and FeCr 2 O 4 . Figures 6 and 7 show the photograph of ceramic tile samples sintered at different sintering temperatures and the XRD patterns of ceramic tiles prepared under different sintering temperatures, respectively. It was found in Figure 6 that as the sintering temperature increases from 1100 • C to 1150 • C, the color of ceramic tile becomes become darker. The ceramic tile is black and smooth after being sintered at 1125 • C, 1150 • C, and 1175 • C. However, when the sintering temperature increases to 1200 • C, the ceramic tiles become bulging deformation. As shown in Figure 7, the main phases of ceramic tiles are FeCr 2 O 4 , CaMgSi 2 O 6 , and Cr 1.3 Fe 0.7 O 3 . As the sintering temperature increases, the contents of Cr 1.3 Fe 0.7 O 3 and CaMgSi 2 O 6 firstly increase and then decrease, while the FeCr 2 O 4 firstly decreases and then increases. Meanwhile, when the sintering temperature rises to 1200 • C or even higher, more liquid phases will be formed in the ceramic tile and could dramatically lead to the dissolution of the Cr 1.3 Fe 0.7 O 3 [29], which is not conducive to ceramic tile production.

Effect of Sintering Temperature on the Coloration Performance of Ceramic Tiles
Materials 2020, 13, x FOR PEER REVIEW 7 of 13 Figures 6 and 7 show the photograph of ceramic tile samples sintered at different sintering temperatures and the XRD patterns of ceramic tiles prepared under different sintering temperatures, respectively. It was found in Figure 6 that as the sintering temperature increases from 1100 °C to 1150 °C, the color of ceramic tile becomes become darker. The ceramic tile is black and smooth after being sintered at 1125 °C, 1150 °C, and 1175 °C. However, when the sintering temperature increases to 1200 °C, the ceramic tiles become bulging deformation. As shown in Figure 7, the main phases of ceramic tiles are FeCr2O4, CaMgSi2O6, and Cr1.3Fe0.7O3. As the sintering temperature increases, the contents of Cr1.3Fe0.7O3 and CaMgSi2O6 firstly increase and then decrease, while the FeCr2O4 firstly decreases and then increases. Meanwhile, when the sintering temperature rises to 1200 °C or even higher, more liquid phases will be formed in the ceramic tile and could dramatically lead to the dissolution of the Cr1.3Fe0.7O3 [29], which is not conducive to ceramic tile production.   Figure 8 shows the effects of sintering temperature on the coloration performance of ceramic tiles. As the sintering temperature increases, the L* value decreases firstly and then increases. At 1150 °C, the L* value of ceramic tile is the smallest. With the increase of sintering temperature, the values of a* and b* decrease. Moreover, the value of a* attains the minimum at 1175 °C and keeps stable, and when the sintering temperature is higher than 1125 °C, the b* value remains low with the further   7 show the photograph of ceramic tile samples sintered at different sintering temperatures and the XRD patterns of ceramic tiles prepared under different sintering temperatures, respectively. It was found in Figure 6 that as the sintering temperature increases from 1100 °C to 1150 °C, the color of ceramic tile becomes become darker. The ceramic tile is black and smooth after being sintered at 1125 °C, 1150 °C, and 1175 °C. However, when the sintering temperature increases to 1200 °C, the ceramic tiles become bulging deformation. As shown in Figure 7, the main phases of ceramic tiles are FeCr2O4, CaMgSi2O6, and Cr1.3Fe0.7O3. As the sintering temperature increases, the contents of Cr1.3Fe0.7O3 and CaMgSi2O6 firstly increase and then decrease, while the FeCr2O4 firstly decreases and then increases. Meanwhile, when the sintering temperature rises to 1200 °C or even higher, more liquid phases will be formed in the ceramic tile and could dramatically lead to the dissolution of the Cr1.3Fe0.7O3 [29], which is not conducive to ceramic tile production.   Figure 8 shows the effects of sintering temperature on the coloration performance of ceramic tiles. As the sintering temperature increases, the L* value decreases firstly and then increases. At 1150 °C, the L* value of ceramic tile is the smallest. With the increase of sintering temperature, the values of a* and b* decrease. Moreover, the value of a* attains the minimum at 1175 °C and keeps stable, and when the sintering temperature is higher than 1125 °C, the b* value remains low with the further  Figure 8 shows the effects of sintering temperature on the coloration performance of ceramic tiles. As the sintering temperature increases, the L* value decreases firstly and then increases. At 1150 • C, the L* value of ceramic tile is the smallest. With the increase of sintering temperature, the values of a* and b* decrease. Moreover, the value of a* attains the minimum at 1175 • C and keeps stable, and when the sintering temperature is higher than 1125 • C, the b* value remains low with the further increase of sintering temperature. It is mainly due to the fact that the increase of temperature increases the chemical reaction ability and diffusion ability of solid particles, the increase of sintering temperature. It is mainly due to the fact that the increase of temperature increases the chemical reaction ability and diffusion ability of solid particles, the Fe2O3, and Cr2O3 in the mixture react to form a large amount of FeCr2O4 and Cr1.3Fe0.7O3, which enhances the black chromaticity value of the ceramic tile. In addition, as the sintering temperature further increases, the reaction of Fe2O3 and Cr2O3 in the mixture mainly generates FeCr2O4, while the content of Cr1.3Fe0.7O3 is relatively low, which weakens the black chromaticity value of the black ceramic tile.  Figure 9 shows the microstructure of black ceramic tiles sintered at 1100 °C and 1150 °C. It can be seen from Figure 9 that there are a lot of micropores in the ceramic tile fired at 1100 °C. When fired at 1150 °C, the number of micropores decreases and the oxide phases of iron and chromium are evenly distributed. The results show that increasing sintering temperature can promote the sintering reaction of the black ceramic tile, in particular, an appropriate amount of liquid phase can be generated to reduce the porosity, thereby improving the surface quality and coloration performance of the black ceramic tile. Therefore, the optimum sintering temperature is 1150 °C, after considering the changes in the values of L*, a*, and b*, the contents of Cr1.3Fe0.7O3 and FeCr2O4 and the microstructure of black ceramic tile. Figure 10 and Figure 11 show the photograph of ceramic tile samples sintered at different sintering time and the XRD diagrams of black ceramic tiles prepared under different sintering times,  Figure 9 shows the microstructure of black ceramic tiles sintered at 1100 • C and 1150 • C. It can be seen from Figure 9 that there are a lot of micropores in the ceramic tile fired at 1100 • C. When fired at 1150 • C, the number of micropores decreases and the oxide phases of iron and chromium are evenly distributed. The results show that increasing sintering temperature can promote the sintering reaction of the black ceramic tile, in particular, an appropriate amount of liquid phase can be generated to reduce the porosity, thereby improving the surface quality and coloration performance of the black ceramic tile. increase of sintering temperature. It is mainly due to the fact that the increase of temperature increases the chemical reaction ability and diffusion ability of solid particles, the Fe2O3, and Cr2O3 in the mixture react to form a large amount of FeCr2O4 and Cr1.3Fe0.7O3, which enhances the black chromaticity value of the ceramic tile. In addition, as the sintering temperature further increases, the reaction of Fe2O3 and Cr2O3 in the mixture mainly generates FeCr2O4, while the content of Cr1.3Fe0.7O3 is relatively low, which weakens the black chromaticity value of the black ceramic tile.  Figure 9 shows the microstructure of black ceramic tiles sintered at 1100 °C and 1150 °C. It can be seen from Figure 9 that there are a lot of micropores in the ceramic tile fired at 1100 °C. When fired at 1150 °C, the number of micropores decreases and the oxide phases of iron and chromium are evenly distributed. The results show that increasing sintering temperature can promote the sintering reaction of the black ceramic tile, in particular, an appropriate amount of liquid phase can be generated to reduce the porosity, thereby improving the surface quality and coloration performance of the black ceramic tile. Therefore, the optimum sintering temperature is 1150 °C, after considering the changes in the values of L*, a*, and b*, the contents of Cr1.3Fe0.7O3 and FeCr2O4 and the microstructure of black ceramic tile. Figure 10 and Figure 11 show the photograph of ceramic tile samples sintered at different sintering time and the XRD diagrams of black ceramic tiles prepared under different sintering times,  Figures 10 and 11 show the photograph of ceramic tile samples sintered at different sintering time and the XRD diagrams of black ceramic tiles prepared under different sintering times, respectively. It was found in Figure 10 that the color of ceramic tiles is dark as the sintering temperature increases from 15 min to 90 min. The surface of ceramic tiles is smooth and black with uniform coloration. As shown in Figure 10 respectively. It was found in Figure 10 that the color of ceramic tiles is dark as the sintering temperature increases from 15 min to 90 min. The surface of ceramic tiles is smooth and black with uniform coloration. As shown in Figure 10, at the sintering temperature of 1150 °C for sintering time ranged from 15 to 90 min, the main phases of ceramic tile are FeCr2O4, CaMgSi2O6 and Cr1.3Fe0.7O3.

Effects of Sintering Time on the Coloration Performance of Ceramic Tiles
The results show that under the sintering temperature of 1150 °C, the chemical reaction of the ceramic tile reacts completely within a short time.  The effects of sintering time on the ceramic tile color are related to the reaction of the coloring ions with the ceramic matrix. Figure 12 shows the effects of sintering time on the coloration performance of black ceramic tiles. As shown in Figure 12, when the sintering temperature is 1150 °C, the L*, a*, and b* of the black ceramic tile generally decrease with the increase of the sintering time. The b* of the black ceramic tile is slightly increased, i.e., the tile surface is yellowish-brown, possibly due to the oxidation of iron oxides [31].
Therefore, the optimum sintering time is 30 min, after considering the changes in the values of L*, a* and b* and the phase compositions of black ceramic tile.  respectively. It was found in Figure 10 that the color of ceramic tiles is dark as the sintering temperature increases from 15 min to 90 min. The surface of ceramic tiles is smooth and black with uniform coloration. As shown in Figure 10, at the sintering temperature of 1150 °C for sintering time ranged from 15 to 90 min, the main phases of ceramic tile are FeCr2O4, CaMgSi2O6 and Cr1.3Fe0.7O3.
The results show that under the sintering temperature of 1150 °C, the chemical reaction of the ceramic tile reacts completely within a short time.  The effects of sintering time on the ceramic tile color are related to the reaction of the coloring ions with the ceramic matrix. Figure 12 shows the effects of sintering time on the coloration performance of black ceramic tiles. As shown in Figure 12, when the sintering temperature is 1150 °C, the L*, a*, and b* of the black ceramic tile generally decrease with the increase of the sintering time. The b* of the black ceramic tile is slightly increased, i.e., the tile surface is yellowish-brown, possibly due to the oxidation of iron oxides [31]. Therefore, the optimum sintering time is 30 min, after considering the changes in the values of L*, a* and b* and the phase compositions of black ceramic tile. The effects of sintering time on the ceramic tile color are related to the reaction of the coloring ions with the ceramic matrix. Figure 12 shows the effects of sintering time on the coloration performance of black ceramic tiles. As shown in Figure 12, when the sintering temperature is 1150 • C, the L*, a*, and b* of the black ceramic tile generally decrease with the increase of the sintering time. The b* of the black ceramic tile is slightly increased, i.e., the tile surface is yellowish-brown, possibly due to the oxidation of iron oxides [31]. Therefore, the optimum sintering time is 30 min, after considering the changes in the values of L*, a* and b* and the phase compositions of black ceramic tile.  Table 3 shows the compression test results of black ceramic tiles. The results show that as the Fe/Cr increases, the compressive strength of the black ceramic tile increases gradually sintering at 1150 °C for 30 min. At the sintering temperature range from 1100 °C to 1200 °C, the compressive strength increases firstly and then decreases. This is due to the fact that when the sintering temperature rises to 1200 °C or even higher, it can lead to overburning of the ceramic tile, resulting in cracks on the ceramic tile surface and reduction of compressive strength. In addition, it attains a maximum value of 50.58 MPa at 1150 °C. Moreover, as the sintering time increases, the compressive strength of black ceramic tiles decreases. Note that when the Fe/Cr molar ratio of 2.0, sintering temperature of 1150 °C, and sintering time of 30 min, the compressive strength of black ceramic tile is 50.58 MPa, which exceeds the minimum compressive strength of 27 MPa of the Chinese national standard (GB/T4100-2006) [32] for standard polished tiles.

Compression and Leaching Tests of Ceramic Tiles
The leaching toxicity results of the ceramic tile with Fe/Cr = 2.0 sintered at 1150 °C for 30 min are shown in Table 4. The results show that the concentrations of harmful elements such as Cr, As, Zn, Pb, and Cr(VI), can meet the regulation thresholds specified by the national standard (GB 5085.   [33]. Therefore, the use of copper slag and stainless steel slag of EAF to prepare black ceramic tile is a safe and value-added process that can harmlessly recycle waste slag.   Table 3 shows the compression test results of black ceramic tiles. The results show that as the Fe/Cr increases, the compressive strength of the black ceramic tile increases gradually sintering at 1150 • C for 30 min. At the sintering temperature range from 1100 • C to 1200 • C, the compressive strength increases firstly and then decreases. This is due to the fact that when the sintering temperature rises to 1200 • C or even higher, it can lead to overburning of the ceramic tile, resulting in cracks on the ceramic tile surface and reduction of compressive strength. In addition, it attains a maximum value of 50.58 MPa at 1150 • C. Moreover, as the sintering time increases, the compressive strength of black ceramic tiles decreases. Note that when the Fe/Cr molar ratio of 2.0, sintering temperature of 1150 • C, and sintering time of 30 min, the compressive strength of black ceramic tile is 50.58 MPa, which exceeds the minimum compressive strength of 27 MPa of the Chinese national standard (GB/T4100-2006) [32] for standard polished tiles.

Compression and Leaching Tests of Ceramic Tiles
The leaching toxicity results of the ceramic tile with Fe/Cr = 2.0 sintered at 1150 • C for 30 min are shown in Table 4. The results show that the concentrations of harmful elements such as Cr, As, Zn, Pb, and Cr(VI), can meet the regulation thresholds specified by the national standard (GB 5085.   [33]. Therefore, the use of copper slag and stainless steel slag of EAF to prepare black ceramic tile is a safe and value-added process that can harmlessly recycle waste slag.

Conclusions
This study provides a new way to develop low-cost, high-quality, environmentally friendly black ceramic tile, and achieves the harmless and value-added utilization of copper slag and stainless steel slag of EAF. The black ceramic tiles can be used in the building and decoration industries. Its application prospect is relatively broad.
(1) The optimum process parameters for the preparation of black ceramic tile from copper slag and EAF stainless steel slag are Fe/Cr = 2.0, the sintering temperature of 1150 • C, and sintering time of 30 min.
(2) The main crystalline phases of the black ceramic tile prepared under the optimum process parameters are chromite spinel (FeCr 2 O 4 ) and solid solution oxide (Cr 1.3 Fe 0.7 O 3 ), with fewer micropores and more uniform distribution of iron and chromium oxide phase.
(3) Under the optimum technological parameters, the surface of ceramic tiles is smooth and black with uniform coloration (L* = +28.19, a* = +1.71 and b*= +3.52). The compressive strength of the black ceramic tiles exceeds the minimum compressive strength of the Chinese national standard for standard polished tiles, and the concentrations of harmful elements such as Cr, Cu, Ni, As, Zn, Pb, and Cr(VI) are within the regulation thresholds specified by the national standard.