Preparation and Coloration of Colored Ceramics Derived from the Vanadium-Titanium

Vanadium-titanium slag is a type of industrial solid waste from vanadium-titanium magnetite, and the resource utilization of vanadium-titanium slag is of great significance. (e chemical composition of vanadium-titanium slag is similar to ceramic raw materials. Besides, the Fe, Ti, and Mn elements in vanadium-titanium slags possess strong color rendering ability. In the present study, we explored the influence of Fe, Ti, and Mn in vanadium-titanium slags on the coloration of ceramics. Besides, the crystal structures and chemical constituents of the sintered ceramics were studied by XRD, SEM, EDS, XPS, and ultraviolet-visible nearinfrared spectrophotometer, and the color-rendering ability (L∗a∗b∗ values) of the ceramics was investigated. (e results showed that the main crystal phases of the ceramics were quartz and anorthite. In addition, the color of the ceramics with the addition of vanadium-titanium slags was significantly affected by Fe and Mn ions, which decreased their L∗ and a∗ values. Meanwhile, Ti ion alone had no apparent coloring effect but strengthened the coloring effects of Fe and Mn ions. (is work could provide the feasibility for preparation of colored ceramics based on vanadium-titanium slag, which could be used in the fields of high-value added building decoration, infrared-emission ceramic, and artwork.


Introduction
With the development of industrial technology and population growth, industrial wastes have become a serious social and environmental problem.ese wastes cause many serious problems associated with transportation, storage, and air and environmental pollutions.us, recycling waste materials is urgently necessary.Some waste materials are adopted to make concrete, cement, and other building materials, and this approach reduces environmental pollution, sustainable consumption and production, and energy efficiency.Previously, numerous researchers have used industrial waste materials to produce new products.For instance, Lu et al. mixed fly ash and blast furnace slag and fluxed with borax and potash feldspar to prepare glass-ceramic glazes with low water absorption, proper stain resistance, and alkali and acid resistance [1].Jonker and Potgieter reported that Fe-rich wastes could be used as a good flux for ceramic production and increase the strength of ceramics [2].Sarkar et al. investigated the possibility of fabrication of vitreous ceramics in a steel-melting electric arc furnace slag [3].ey found that a certain amount of slag with other conventional raw materials could be used for sintering at a range of 1100-1150 °C.Furthermore, other researchers used industrial waste materials, such as sewage sludge, fly ash, and steel slags, to produce ceramics, cement, and various building materials [4][5][6][7][8].Simultaneously, vanadium-titanium slags are industrial wastes mainly concentrated in the Panxi area in south-western China.High titanium slag emissions amount to 3.6 million tons annually in the Panzhihua area and have reached nearly 70 million tons nationwide, thereby causing severe pollution.Vanadium-titanium slags are mainly composed of Fe 2 O 3 , TiO 2 , CaO, SiO 2 , and trace amounts of Al 2 O 3 , K 2 O, and Na 2 O. Chinese scholars have started studying the comprehensive use of vanadium-titanium slags since the early 1960s and have made some promising achievements.For example, Wang used titanium slags to fabricate concretes with other raw materials [9], and Sun et al. produced building bricks with titanium slags from Pangang factory and clays [10].Besides, for the purpose of vanadium-titanium slag recycling, building bricks were prepared using vanadium-titanium slags or by extracting titanium from vanadium-titanium slags [11,12].
Ceramic bodies are heterogeneous materials, and they mainly consist of a mixture of natural raw materials with various compositions.Currently, many previous studies mostly focus on the harmless treatment of wastes, preparation of the basic formula, and characterization of sample performances.ere are few reports regarding the mechanism of ceramic coloring.Because the main ions in vanadium-titanium industrial waste slags are Fe, Mn, and Ti, vanadium-titanium industrial waste slags can replace a certain amount of clays and quartz, which are widely used to prepare ceramics.Herein, the aims of the present work are to explore the impact of Fe 2 O 3 , MnO 2 , and TiO 2 on ceramic color performance, to study the color mechanism of ceramics after adding vanadium-titanium, and to assess the feasibility for preparation of colored ceramics, which could be used in the high-value-added building decoration field, infrared-emission field [13], and artwork.

Materials and Method
e basic materials were vanadium-titanium slags collected from PanGang Iron and Steel Group Co.
e chemical composition of these slags is listed in Table 1.Other raw materials used to formulate the ceramic body were provided by Baita Ceramic Group Co. e mixtures were subjected to wet ball milling for 20 min and sieves using 140 mesh with a sieve margin of less than 3%.
e mixture was then filtrated, dried at 80 °C for 2 h, ground, and humidified with 7.0 wt.% water.e humidified mixtures were then mold-shaped to the wafer samples with a diameter of 50 mm under 20 MPa pressure.Finally, the samples were dried at 100 °C for 30 min and sintered in muffle furnace at 1100 °C for 10 min.
e ceramic material colorant was characterized through the CIE1976 L * a * b * color system, which was established by the International Commission on Illumination in 1976.In the L * a * b * color system, the color is represented by three parameters, namely, L * (lightness), a * (color), and b * (color).L * shows lightness, and the L * value ranges from 0 to 100 (blackwhite).a * indicates the range from red to green, and its value ranges from +127 to −128 (red-green).b * indicates the range from yellow to blue, and its value ranges from +127 to −128 (yellow-blue).
e phase composition of sintered ceramics was studied by X-ray diffraction (XRD, DX-1000X, Japan).e samples were scanned from 10 °to 80 °at a scanning speed of 2 °/min.e microstructure of the samples was observed by the scanning electron microscopy (SEM, S-3400N, Japan) equipped with an energy dispersive X-ray spectrometer for elemental analysis.All samples were coated by gold for 1 min before SEM observation.e L * a * b * value was measured by WR-10 colorimeter.e reflectance spectrum was observed by UV-visible near-infrared spectrophotometer (UV-3600, USA) at a wavelength range of 250-1500 nm.

Phase Composition.
From previous researches, we can find that vanadium and titanium industrial waste slags were employed to partly replace ceramic raw materials for the preparation of ceramic bodies.Vanadium and titanium industrial waste slags exhibited the following favorable conditions: the addition amount was 15%, and the sintering temperature was 1100 °C.us, the flexural strength of the ceramics was 31.28MPa, and the water absorption was 7.07%.e ceramics were prepared with different amounts of vanadium-titanium slags and then sintered at 1100 °C.e XRD analysis results are shown in Figure 1.
Figure 1 shows that the main crystalline phases of the sintered ceramics were quartz, anorthite, and iron oxide.Anorthite has been used in ceramics because of its high mechanical strength, dilatability, and low sintering temperature [14,15].e crystallization of anorthite increases the chemical stability and strength of the material and improves its physical properties including high thermal shock resistance and low thermal expansion coefficient [16][17][18][19].e increased 2 Advances in Materials Science and Engineering amount of the vanadium-titanium industrial waste slag resulted in the decrease of SiO 2 content and the increase of Fe 2 O 3 content.e calculated area of the XRD spectra peaks indicated that when the amount of vanadium-titanium industrial waste slag increased to 15% and 25%, the iron oxide crystal phase ratios were 5.76% and 9.41%, respectively, and the composition of the raw materials decreased by 7.69% and 12.82%, respectively.e iron oxide in the ceramics was not entirely crystal and was partly in the glass phase.Similar to the network effect, the Fe 3+ with eight ligands can damage the ceramic glass network structure by reducing the viscosity of the ceramic glass phase [20]. is effect contributes to the diffusion of atoms and ions during the sintering process and can reduce the sintering temperature, densify the ceramics, and increase the flexural strength.
As shown in Figure 2(a), the lightness of the ceramics gradually decreased with the increase of the Fe 2 O 3 content.When the amount of Fe 2 O 3 reached 8%, the L * value decreased gradually and then remained generally stable, whereas the a * value increased gradually.e value of b * decreased initially and then remained unchanged at the end.
ese results indicated that Fe 2 O 3 could effectively reduce the lightness of materials and provide red coloring to the materials, thereby producing red ceramics.As shown in    us, the ions exhibit selective absorption in the visible region and thus render the ceramics colorful.e Fe ion has two valence states, namely, Fe 3+ and Fe 2+ .Fe 2+ is easily oxidized and rare, whereas Fe 3+ is extremely unstable at high temperatures and easily decomposes into Fe 2+ .e coexistence of two valence states of iron oxides produces ferrous ferrite (Fe 3+ -O-Fe 2+ ).Ferrous ferrite is a kind of Fe 3 O 4 structure that renders ceramics colorful.At sintering temperature of 1100 °C, the ceramics were slight red because the trivalent iron dominated.
In silicate ceramics, Ti is generally in the form of Ti 4+ .e valence state of Ti 4+ means that the 3d 2 4s 2 of the outermost electrons of Ti is lost completely, and 3d orbital is completely empty.e "d-d" transition between the electrons in the d orbitals cannot occur.us, the valence state of Ti 4+ should be colorless.However, Ti 4+ ions strongly absorb ultraviolet light, and the absorption band can cross into the purple and blue part of visible light, subsequently rendering the materials pale brown.Ti 4+ alone does not cause a darker color, but it can affect other transition elements and thus may strengthen and intensify the effect of the other ion colorants.In ceramic materials, Mn usually exists in the form of MnO 2 , which reduces the lightness of materials.
e ceramics were prepared with colorants at varying contents and then sintered at 1100 °C.e reflectance spectra of the ceramics are shown in Figure 3. e ceramics rarely  absorb light without colorants (Figure 3), and the ceramics were slightly yellow.No evident absorption peak was observed in the wavelength range of a single colorant, and the reflectivity increased gradually with increased wavelength.e reflectivity of ceramics with TiO 2 was higher than those of ceramics without colorants.However, the reflectivity of ceramics with Fe 2 O 3 or MnO 2 decreased.

Effect of Vanadium-Titanium Slags on Color of Ceramics.
e ceramics were prepared with different additions of vanadium-titanium slags and then sintered at 1100 °C.e results of L * a * b * analysis on the ceramics are shown in Figure 4.It was found that the L * , a * , and b * values all decreased with the addition of vanadium-titanium slags, in contrast to those of ceramics with different colorants, where the L * value considerably decreased.e ceramics were purple black, which darkened gradually after the addition of vanadium-titanium slags.e color parameters of the ceramics with titanium-vanadium slags or single colorant are listed in Table 2. e color parameters of the ceramics with vanadiumtitanium slags were different from those of the ceramics with a single colorant, and the L * , a * , and b * values decreased.e alteration of the ceramics color with vanadium-titanium slags was attributed to the combined colors of various ions.Fe ions mainly reduced the L * value of the material, and Mn ions mainly reduced the a * value of the material.Ti ion alone had no evident coloring effect but strengthened the coloring effects of the Mn and Fe ions.e ion content, valence state, and sintering atmosphere cocontributed to the final color formation.
Figure 5 presents the reflectance spectra of ceramics with different amount of vanadium-titanium slags.e reflectivity of ceramics gradually decreased with the increase of vanadium-titanium slags.Moreover, the reflectivity of ceramics gradually increased with the increase of the wavelength of light, and there was no obvious absorption peak in all wavelength area, which corresponded to the color of ceramics.

Phase Composition and Microstructure.
e XRD analysis of ceramics is shown in Figure 6. e main crystal phases of ceramics with different additions were quartz and anorthite and that of ceramics with vanadium-titanium slags or Fe 2 O 3 was iron oxide.e microstructures of ceramics with different additions at sintering temperature of 1100 °C are also depicted in Figure 7. ese ceramics all displayed porous structures, and the numbers and sizes of the pores of the ceramics varied at different additions.
e content of SiO 2 in vanadium and titanium industrial waste slags was small, and the contents of Fe 2 O 3 and Na 2 O were relatively higher when vanadium-titanium slags or single oxide (such as MnO 2 , Fe 2 O 3 , and TiO 2 ) were added to the ceramics.e addition reduced the content of SiO 2 in the body.Similarly, the content of SiO 2 /R 2 O decreased.In the sintering process, the skeleton effect of SiO 2 was partially destroyed.e aluminosilicates in clay and calcium oxide derived from the decomposition of raw materials to form anorthite.Simultaneously, iron oxide, sodium oxide, calcium oxide, and silicon dioxide formed a eutectic mixture, which produced a large number of liquid phases that promoted the sintering process.6 Advances in Materials Science and Engineering 3.5.Element Distribution.Figure 8 shows the element distribution of ceramics with 15% vanadium-titanium slags.
From Figure 8, it could be seen that the elements of Fe, Ti, and Mn were distributed in the ceramics evenly, and the content of Fe was more than that of Ti and Mn.erefore, this distribution can well describe the color of ceramics.
3.6.XPS Analysis.In order to confirm the content of Fe 3+ and Fe 2+ , the high-resolution XPS spectra of Fe 2p for ceramics are presented in Figure 9.And the calculated peak area ratio (Fe 3+ area/Fe 2+ area) of the sample has been marked in the spectra.It could be found that the content of Fe 3+ /Fe 2+ was 0.56.Under this condition, the valence of Mn was +4, and the valence of Ti was also +4, which was in accordance with the color of ceramics.

Conclusions
e vanadium-titanium industrial waste slags can partly replace ceramic raw materials for the preparation of ceramic bodies.
e XRD results showed that the main crystalline phases of the ceramics with vanadium-titanium slags or single colorant were quartz and anorthite.e color of the ceramics with the addition of vanadiumtitanium slags was significantly affected by various ions.
e Fe and Mn ions mainly decreased the L * and a * values of the materials; however, Ti ions had a minimal coloring effect but affected the coloring effects of the Fe and Mn ions.e experimental results indicated that the ceramics with 15% vanadium-titanium slags could be fabricated to colored ceramics, and the color parameters were as follows: L * � 49.08, a * � 4.15, and b * � 13.03.Our work could provide the feasibility for the preparation of colored ceramics.

Figure 6 :
Figure 6: XRD spectra of ceramics with different additions at sintering temperature of 1100 °C.

4
Advances in Materials Science and Engineering 10 electrons in 3d orbit, 1-9 electron transitions, and valence electrons jump between different energy levels (called d-d transition).

Figure 8 :Figure 9 :
Figure 8: Element distribution of ceramics with 15% vanadium-titanium slags at the sintering temperature of 1100 °C.

Table 1 :
Main chemical composition of vanadium and titanium slags.
Figure 1: XRD spectra of ceramics with different amounts of vanadium and titanium industrial slags at sintering temperature of 1100 °C.

Table 2 :
Color parameters of ceramics with different components.