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Article

Fabrication of Dy2O3 Transparent Ceramics by Vacuum Sintering Using Precipitated Powders

1
Key Laboratory of Transparent Opto-functional Inorganic Materials, Shanghai Institute of Ceramics, Chinese Academy of Sciences, Shanghai 201899, China
2
Center of Materials Science and Optoelectronics Engineering, University of Chinese Academy of Sciences, Beijing 100049, China
*
Author to whom correspondence should be addressed.
Submission received: 1 December 2020 / Revised: 18 December 2020 / Accepted: 19 December 2020 / Published: 28 December 2020
(This article belongs to the Special Issue Magneto-Optical Ceramics)

Abstract

:
As a kind of promising material for a Faraday isolator used in the visible and near infrared range, Dy2O3 transparent ceramics were prepared by vacuum sintering from the nano-powders synthesized by the liquid precipitation method using ammonium hydrogen carbonate as precipitant with no sintering aids. The synthesized precursor was calcinated at 950 °C–1150 °C for 4 h in air. The influences of the calcination temperature on the morphologies and phase composition of Dy2O3 powders were characterized. It is found that the Dy2O3 powder calcinated at 1000 °C for 4 h is superior for the fabrication of Dy2O3 ceramics. The Dy2O3 transparent ceramic sample prepared by vacuum sintering at 1850 °C for 10 h, and subsequently with air annealing at 1400 °C for 10 h, from the 1000 °C-calcined Dy2O3 powders, presents the best optical quality. The values of in-line transmittance of the optimal ceramic specimen with the thickness of 1.0 mm are 75.3% at 2000 nm and 67.9% at 633 nm. The Verdet constant of Dy2O3 ceramics was measured to be −325.3 ± 1.9 rad/(T·m) at 633 nm, about 2.4 times larger than that of TGG (Tb3Ga5O12) single crystals.

1. Introduction

Along with the propelling of magneto-optical devices, it becomes gradually essential to investigate the state-of-the art technology to obtain magneto-optical materials due to their irreplaceable roles in laser [1], optical communication [2], optical fiber sensing [3], and other fields. The most widely studied and applied magneto-optical device is the magneto-optical isolator. The magneto-optical isolator is also known as an optical unidirectional passive device with the nonreciprocal optical transmission. Its main function is to prevent the beam reflecting from the optical fiber and components of the optical path from reentering the lasers, and avoid causing damage to its components or interference with the incident light [4,5]. The additional optical reflection will make the optical communication system unstable and thus limits the transmission of the long-distance optical signal. Therefore, the optical isolator, which only allows the optical signal to transmit in one direction along the optical path, is necessary to solve this problem.
Figure 1 shows the graphic representation of the Faraday effect; it shows that when a beam of polarized light passes through the magneto-optical materials (located in the magnetic field), along the direction of the magnetic field, the polarization plane of the transmitted light will deflect at a certain angle compared to the incident one. The deflection of the polarization plane caused by the Faraday effect has nothing to do with the direction of light propagation, only with the direction of magnetic field [6,7]. This nonreciprocity of magneto-optical materials can effectively realize the isolation and modulation of optical signals, making them receive great attention and development [8]. The magneto-optical medium plays a key role in the isolator, so a suitable magneto-optical material is an important factor to promote the development of a Faraday isolator. At present, a lot of widely used magneto-optical materials have been reported, such as YIG (Y3Fe5O12) [9,10,11], TGG (Tb3Ga5O12) [12,13,14], and TAG (Tb3Al5O12) [15,16,17,18,19]. It is known that Ce3+, Pr3+, Dy3+, Ho3+, and Tb3+ ions have excellent magneto-optical properties [20] due to their 4f–5d transition. Rare earth sesquioxides, Tb2O3 [21,22,23,24], Dy2O3 [25,26,27,28], and Ho2O3 [29,30,31,32], with a high concentration of rare earth ions, have a better prospect in the application of optical isolators, as their Verdet constant values are 3.8, 2.2, and 1.3 times higher than that of TGG single crystals, respectively [33]. Among these materials, Dy2O3 has several transparency windows in the visible 500–730 nm, near-IR (infrared) 1900–2300 nm, and mid-IR 3500–7500 nm ranges [27], making it promising for Faraday devices used in the visible range and near 2 μm.
Dy2O3 undergoes phase transitions at high temperatures below the melting point [34], which makes the preparation of a Dy2O3 single crystal troublesome, whereas Dy2O3 polycrystalline ceramics can be synthesized at relatively low temperatures, at which Dy2O3 keeps a cubic C-type structure. Extensive efforts have been made to fabricate Dy2O3 ceramics. Dy2O3 transparent ceramics were firstly reported in a patent in 2002 [26]. Then in 2011, Morale et al. [25] processed nanocrystalline Dy2O3 ceramics using current activated pressure assisted densification (CAPAD), and the measured Verdet constant was above 300 rad/(T·m) at 632.8 nm. A series of optical ceramics based on (DyxY0.95−xLa0.05)2O3 (x = 0.7, 0.85 and 0.9) were prepared by vacuum sintering with self-propagating high-temperature synthesis of submicron powders, and the dependence of the Verdet constant on the wavelength in the 400 nm–1940 nm range was measured in the report [27]. Additionally, the temperature dependences of the Verdet constant, and their approximations in the temperature range of 80 to 294 K and in the wavelength range of 405 to 1064 nm, with the <10% deviation from the experimental data, were reported in [35]. Slezák et al. [28] also measured the temperature and wavelength dependence of the Verdet constant of Dy2O3 transparent ceramics for the temperature ranging from cryogenic 20 K up to room temperature, 297 K, in the wavelength range starting from visible 0.6 µm up to mid-infrared 2.3 µm. Aung et al. [36] obtained optical grade Dy2O3 ceramics, with an optical loss less than 0.1%/cm, by a pre-sintering and hot isostatic pressing treatment using ZrO2 as a sintering aid.
High-quality powder is the key to obtain high performance transparent ceramics. The particle size, shape, and agglomeration state of powder will directly affect the densification behavior and microstructure of ceramics. A good powder combined with a proper sintering schedule is conducive for the elimination of pores and the densification of ceramics. The liquid precipitation method has been explored as a method to effectively control the morphology of the powder. It can realize the synthesis of fine powders with uniform size distribution and has been used for the preparation of various transparent ceramics, such as YAG(Y3Al5O12) [37], Lu2O3 [38], MgAl2O4 [39], and so on. However, to date, most of the efforts focused on Dy2O3 powders and ceramics have not been addressed using the liquid precipitation method.
In this paper, Dy2O3 transparent ceramics were fabricated by vacuum sintering from the precipitated nano-powders for the first time. Using NH4HCO3 (AHC) as precipitant and (NH4)2SO4 as dispersant, the obtained precursor was calcinated at 950–1150 °C for 4 h in air. The influences of the calcination temperature on the morphologies, phase composition and the particle sizes of Dy2O3 powders were characterized. The microstructures of the Dy2O3 ceramics were identified. The optical and magneto-optical properties were also analyzed.

2. Materials and Methods

2.1. Materials

Dy2O3 (99.99%, Golden Dragon Rare-Earth Co., Ltd., Changting, China), HNO3 (G3, Shanghai Aoban Technology Co., Ltd., Shanghai, China), NH4HCO3 (Analytical grade, Aladdin, Shanghai, China) and (NH4)2SO4 (Analytical grade, Sinopharm Chemical Reagent Co., Ltd., Shanghai, China) were used as raw materials.

2.2. Methods

The positive strike precipitation method was utilized to synthesize the Dy2O3 nano-powders. Dy(NO3)3 solution was obtained by adding the Dy2O3 powder into a concentrated nitric acid with stirring and heating. After the powder was completely dissolved, the solution was diluted and then filtered to remove the insoluble impurities. The concentration of the Dy(NO3)3 solution determined by chemical analysis was 1.5076 mol/L. (NH4)2SO4 was dissolved in deionized water as the dispersant with the concentration of 2.0 mol/L. AHC was dissolved in deionized water with a concentration of 2.0 mol/L as precipitant. Firstly, (NH4)2SO4 solution was added to the metal ion solution with the molar ratio of Dy3+ to (NH4)2SO4 being 1:1. Then the mixed solution was diluted with deionized water until 500 mL with the concentration of Dy3+ being 0.4 mol/L. Subsequently, the AHC solution was added into the mixed solution at a speed of 3 mL/min under fast-speed stirring at room temperature. In the process of precipitation, the pH of the metal ion solution increased from 1.3 to 6.7. After 400 mL of AHC solution was added, the precipitated products were aging for 4 h and then the precipitation was washed with deionized water and anhydrous ethanol several times. After drying at 70 °C for 36 h and sieving with a 200screen mesh, the precursor was obtained. Then the precursors were calcined at 950–1150 °C for 4 h in air, respectively. The obtained Dy2O3 powders were dry pressed and cold isostatic pressed to get green bodies. The pellets were then vacuum sintered at 1675, 1780, and 1850 °C for 10 h, and air annealed at 1400 °C for 10 h. Finally, the Dy2O3 ceramics were mirror polished on both sides with a thickness of 1.0 mm.

2.3. Characterization

The compositions of the precursor and the calcined Dy2O3 powders were investigated by the Fourier transform infrared spectrometer (FTIR, Bruker VERTEX 70 spectrophotometer, Ettlingen, Germany). The thermogravimetry and differential thermal analysis (TG-DTA) of the precursor were measured by the thermal analyzer (Thermoplus EVO II, Rigaku, Tokyo, Japan). The phases of the precursor and the calcined powders were identified by the X-ray diffraction (XRD, D8 ADVANCE, Bruker AXS GMBH, Karlsruhe, Germany) using Cu Kα radiation in the range of 2θ = 20°–80°. The specific surface area of the calcined Dy2O3 powders was performed by the Quadrasorb SI (Quantachrome Instruments, Boynton Beach, FL, USA) with N2 as the absorption gas at 77 K. The morphology of the Dy2O3 powders was observed by the field emission scanning electron microscopy (FE-SEM, SU9000, Hitachi, Tokyo, Japan). The microstructures of the Dy2O3 ceramic specimens were investigated by a field emission scanning electron microscopy (FE-SEM, SU8220, Hitachi, Tokyo, Japan) and the optical microscopy (U-CMAD3, Olympus, Tokyo, Japan). The in-line transmittance curves of the Dy2O3 ceramics with the thickness of 1.0 mm were measured by a UV-VIS-NIR (ultraviolet-visible-near infrared) spectrophotometer (Model Cray-5000, Varian, Palo Alto, CA, USA) in the wavelength range of 300 to 2200 nm. The Verdet constant was measured by the extinction method with an instrument consisting of a He-Ne laser (wavelength = 632.8 nm), an electromagnet and two polarizers at room temperature, as shown in Figure 2. Firstly, the magnetic field is not applied to the sample, and the position of the light transmission axis of the output polarizer is adjusted to make the transmission axis of the two polarizers in orthogonal, and the detected intensity of the transmitted light reaches the minimum, that is, extinction occurs. Then, after applying a certain magnetic field to the measured sample, the detected intensity of the transmitted light changes, indicating that the polarization plane of the light rotates when passing through the sample in the magnetic field. In order to reproduce the extinction phenomenon, the output polarizer needs to rotate a certain angle θ to make the detected intensity reach the minimum again, and the θ is the Faraday angle to be measured. The Verdet constant (V) can be calculated by the formula [40]:
θ = VBd
where d is the thickness of the sample (d = 1.0 mm), B is the magnetic field strength, θ is the Faraday angle.

3. Results and Discussion

The Dy2O3 precursor prepared by liquid precipitation method needs to be calcined at a certain temperature to become Dy2O3 powder. The selection of the calcination temperature is extremely important for the preparation of high-quality nano-powder and transparent ceramics. Figure 3 shows the TG-DTA-DTG curves of the Dy2O3 precursor obtained from liquid precipitation method. The DTG curve results from the first derivative of the TG curve, from which the temperature range of each stage can be got clearly. There are four stages in the thermal decomposition of the precursor during the heating process, with a total weight loss of 41.9%. The first stage is from room temperature to about 155 °C, and the weight loss is 13.6%, which is mainly caused by the evaporation of absorbed water and residual ethanol, and the decomposition of partial crystallized water, and the endothermic peak located at about 73 °C is due to the release of ethanol. The weight loss of the second stage from 155 to 290 °C is 8.3%, which is attributed to the removal of ammonium radical, OH, and residual crystal water. The endothermic peak centered at about 253 °C is related to the removal of residual crystal water and the dehydration of OH. The weight loss of the third stage from 290 °C to 683 °C is 18.4%, which is attributed to the decomposition of carbonate and OH. The endothermic peak centered at about 486 °C is mainly ascribed to the decomposition of carbonate. The wide exothermic peak in the temperature range of 580 to 650 °C, with the center at 610 °C, is related to the formation of the Dy2O3. The 1.6% weight loss above 683 °C is related to the decomposition of the residual carbonates and sulfates.
The thermal analysis of the precursor shows that the formation of Dy2O3 appeared at around 610 °C. In order to verify this conjecture, we calcined the Dy2O3 precursor at 600 and 650 °C for 1 h, respectively. Figure 4 shows the FTIR spectra of the Dy2O3 precursor and the powders calcined at different temperatures. The wide absorption band centered at about 3400 cm−1 and the 1635 cm−1 shoulder are corresponding to the bending and stretching vibrations of the O-H bond and the H-O-H bending mode of crystalline water, respectively [41,42]. These peaks at 1520, 1405, 1088, 844, 762, and 685 cm−1 are all ascribed to the existence of the CO32−. Two absorption peaks at 1520 and 1405 cm−1 are attributed to ν3 stretching mode of the C-O bond in CO32− group [38]. These peaks at 1088, 844, 762, and 685 cm−1 are ascribed to the ν1 symmetric stretch, δ out of plane bending vibration, ν3 and ν6 vibration of CO32−, respectively [43]. Therefore, the precursor may be the dysprosium hydroxycarbonate with crystal water. For the powder calcined at 600 °C, the absorption peaks of O-H and CO32− become weaker, and a new absorption peak of cubic Dy2O3 located at 555 cm−1 [44,45] appears, meaning that Dy2O3 has been generated at 600 °C. The absorption peaks of O-H and CO32− still exist when the calcination temperature increases to 650 °C, indicating that the decomposition of the precursor is incomplete. Therefore, in order to obtain the pure Dy2O3 powders, the synthesized precursor was calcined above 650 °C. Figure 4 also presents the FTIR spectra of the Dy2O3 powders calcined at 950–1150 °C for 4 h, as can be seen that there are no obvious absorption peaks except that of the Dy2O3. Therefore, these Dy2O3 powders calcined at 950–1150 °C were chosen as raw materials for the fabrication of Dy2O3 transparent ceramics.
The XRD patterns of the Dy2O3 powders calcined at 600, 650, and 950–1150 °C are shown in Figure 5. All the characteristic diffraction peaks of the powders calcined at 600 and 650 °C correspond to the cubic dysprosium oxide phase (PDF#43-1006), meaning that the Dy2O3 phase has been generated at 600 °C, which is consistent with the result of FTIR, but slightly lower than the result of 610 °C in Figure 3 due to the hysteresis in the measurement of TG-DTA. Figure 5 also presents the XRD patterns of the precursor and the Dy2O3 powders calcined at 950–1150 °C for 4 h. It is noted that the crystallinity of the synthesized precursor is low. After calcination at 950–1150 °C, the diffraction peaks of obtained powders are consistent with the standard card of Dy2O3 (PDF#43-1006). These sharp diffraction peaks indicate the enhanced crystallinity of the powders. The average crystallite sizes (DXRD) of the Dy2O3 powders are calculated by the Scherrer formula. The formula is as follows [46]:
DXRD = 0.89λ/(β·cosθ)
where λ is the wavelength of Cu Kα radiation, β is the full width at half maximum (FWHM) of a diffraction peak at Bragg angle θ. The calculated results of DXRD are shown in Table 1. With the increase in the calcination temperature from 950 to 1150 °C, the DXRD gradually increases from 79.6 to above 100 nm. The average particle size (DBET) of Dy2O3 powder after calcination can be calculated by the following formula [47]:
DBET = 6/(ρ·SBET)
where ρ is the density of Dy2O3 (8.168 g/cm3), SBET is the specific surface area measured by the BET method. The SBET and the calculated results of DBET of Dy2O3 powders are also present in Table 1, and the values of DBET are larger than those of DXRD, indicating that these powders may be slightly agglomerated. The agglomeration degree of Dy2O3 nano-powder can be presented by the ratio of DBET to DXRD, the smaller value of ratio indicates the better dispersity [48]. For the Dy2O3 nano-powders calcined at different temperatures, the values of DBET/DXRD decrease firstly when the calcination temperature increases from 950 to 1000 °C. With the further increase in calcination temperature, the values increase gradually. The Dy2O3 nano-powder calcined at 1000 °C shows the smallest DBET/DXRD, indicating that the 1000 °C-calcined Dy2O3 nano-powder shows a good dispersion with a low agglomeration degree, which is conducive to the preparation of Dy2O3 transparent ceramics.
Figure 6 shows the FE-SEM photographs of precursor and Dy2O3 powders calcined at 950–1150 °C for 4 h. The precursor shows a needle or flake shape with a loose structure. After calcining the precursor at 950–1150 °C for 4 h, the morphology of the powder changes greatly, forming clear and spherical like nanoparticles. It can be seen from Figure 6 that the calcination temperature has a significant effect on the particle size, morphology and agglomeration of the powder. When the calcination temperatures are orderly 1050, 1100, and 1150 °C, the powders have similar morphologies, and are composed of small near-spherical particles with weak agglomeration.
Using Dy2O3 powders calcined at 950–1150 °C for 4 h, Dy2O3 transparent ceramics were fabricated by vacuum sintering and then air annealing. The photograph of the Dy2O3 ceramics vacuum sintered at 1675, 1780, and 1850 °C for 10 h and air annealed at 1400 °C for 10 h is shown in Figure 7. The optical quality of Dy2O3 ceramics obtained from the powders calcined at different temperatures is obviously different at the same sintering temperature. The Dy2O3 ceramic samples fabricated from 950 °C-calcined powder appear translucent. It is noted that the Dy2O3 ceramic samples using the powders calcined at 1000 and 1050 °C exhibit relatively good transparency and the letters under them can be seen clearly. When the calcination temperature increases to 1100 and 1150 °C, the optical quality of the ceramics decreases obviously. The variation of optical quality for the Dy2O3 ceramic samples from powders calcined at different temperatures displays no significant difference under three different sintering schedules.
Figure 8a–c show the in-line transmittance curves of the corresponding Dy2O3 ceramic samples. With the increase in calcination temperature, the in-line transmittance of Dy2O3 ceramics firstly increases and then decreases. The Dy2O3 ceramic samples fabricated from 950 °C-calcined powder show low in-line transmittance, which is due to the incomplete grain growth observed from Figure 6b and weak agglomeration (DBET/DXRD = 1.65) of Dy2O3 powder, and the weak agglomeration caused by the high specific surface energy (SBET = 5.596 m2/g) will lead to different grain boundary migration rate in the sintering process, being not conducive to densification. The ceramic samples with 1.0 mm thickness from 1000 °C-calcined Dy2O3 powder show the best transparency, and their in-line transmittances reach 69.2, 70.0, and 75.3% at 2000 nm, and 44.2, 56.8, and 67.9% at 633 nm, corresponding to the sintering temperature of 1675, 1780, and 1850 °C, respectively. The in-line transmittances of the samples decrease when the calcination temperature of Dy2O3 powder is further enhanced to 1050 °C. The slight decrease in the in-line transmittance is attributed to the increased agglomeration degree among primary particles (DBET/DXRD = 1.70), which reduces the sinterability of Dy2O3 powders. When the calcination temperature further increases to 1100 and 1150 °C, the in-line transmittance decreases greatly. For the powder calcined at high temperatures, there are sintering necks between particles (Figure 6e,f), increasing agglomeration degree and leaving poor sintering activity [13,49]. Therefore, the Dy2O3 powder calcined at 1000 °C is the most suitable for the fabrication of Dy2O3 transparent ceramics.
Figure 9 shows the optical microscopy and FE-SEM pictures of the thermally-etched and the fracture surfaces of the Dy2O3 ceramics after vacuum sintering at different temperatures and air annealing at 1400 °C for 10 h from the 1000 °C-calcined Dy2O3 powder. Figure 9a,b present the surface and fracture microstructure of 1675 °C sintered Dy2O3 ceramics. The 1675 °C sintered specimen consists of uniform grains and has a nearly pore-free microstructure, and the statistical value of average grain size measured by the linear intercept method is about 25.6 μm. Figure 9b shows the transgranular fracture of Dy2O3 ceramics. With the temperature of vacuum sintering increasing, to 1780 and 1850 °C, the grain size increases obviously, as shown in Figure 9c,e, respectively. From Figure 9d,f, it is known that the Dy2O3 ceramic samples are all transgranular fractures.
The Verdet constant is a key parameter for magneto-materials and it can reflect the deflection ability of the magneto-optical medium to polarized beam. The Verdet constant of 1675, 1780, and 1850 °C sintered Dy2O3 ceramics from 1000 °C calcined powders at 633 nm was measured to be about −324.8 ± 1.4 rad/(T·m), −325.3 ± 3.5 rad/(T·m) and −325.3 ± 1.9 rad/(T·m), respectively, about 2.4 times larger than that of the commercial TGG single crystal (VTGG = −135.8 rad/(T·m) from [50]). Additionally, the measured results also show that the Verdet constants of Dy2O3 ceramic samples are almost independent of their optical quality. Considering that Dy2O3 ceramics have high transmission and large Verdet constant at visible range and near 2 μm, this material is an important candidate for a Faraday isolator used in visible or 2 μm lasers.

4. Conclusions

Dy2O3 nano-powders were synthesized by the liquid precipitation method using AHC as precipitant. Dy2O3 phase appears at 600 °C during the decomposition period of precursor. The near-spherical nano-powder calcined at 1000 °C shows the best sintering activity, and has the average particle size of 143.2 nm. With the calcination temperature of the powder increasing from 950 °C to 1150 °C, the optical quality of Dy2O3 ceramics increases firstly and then decreases. The Dy2O3 ceramics from 1000 °C calcined powder shows the best optical quality. The optimal Dy2O3 ceramics were fabricated by vacuum sintering at 1800 °C for 10 h and air annealing at 1400 °C for 10 h. The in-line transmittance values of the optimal ceramic sample with 1.0 mm thickness are 75.3% at 2000 nm and 67.9% at 633 nm. The Verdet constant of Dy2O3 ceramics was measured to be about −325.3 ± 1.9 rad/(T·m) at 633 nm, 2.4 times larger than that of the commercial TGG single crystal. The large Verdet constant and high optical quality make Dy2O3 transparent ceramics promising for a Faraday isolator used in visible and 2 μm range.

Author Contributions

Conceptualization, methodology and software, D.H.; validation, X.L. (Xiaoying Li); formal analysis, Z.L.; investigation, D.H. and F.T.; resources, J.L. and L.W.; data curation, D.H. and X.L. (Xin Liu); writing—original draft preparation and writing—review and editing, D.H. and D.Z.; visualization, Z.Y. and L.W.; supervision, project administration and funding acquisition, J.L. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

The data presented in this study are available in this article.

Acknowledgments

This research was funded by National Key R and D Program of China (Grant No. 2017YFB0310500), the Special Exchange Program of Chinese Academy of Sciences (Plan B), the key research project of the frontier science of the Chinese Academy of Sciences (No. QYZDB-SSW-JSC022).

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. The graphic representation of the Faraday effect.
Figure 1. The graphic representation of the Faraday effect.
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Figure 2. The schematic diagram for measuring the Verdet constant.
Figure 2. The schematic diagram for measuring the Verdet constant.
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Figure 3. TG-DTA-DTG curves of the Dy2O3 precursor.
Figure 3. TG-DTA-DTG curves of the Dy2O3 precursor.
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Figure 4. FTIR spectra of the Dy2O3 precursor and the powders calcined at 600, 650, and 950–1150 °C.
Figure 4. FTIR spectra of the Dy2O3 precursor and the powders calcined at 600, 650, and 950–1150 °C.
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Figure 5. XRD patterns of the precursor and the Dy2O3 powders calcined at 600, 650, and 950–1150 °C.
Figure 5. XRD patterns of the precursor and the Dy2O3 powders calcined at 600, 650, and 950–1150 °C.
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Figure 6. Field emission scanning electron microscopy (FE-SEM) pictures of the precursor (a) and the Dy2O3 powders calcined at different temperatures: (b) 950 °C, (c) 1000 °C, (d) 1050 °C, (e) 1100 °C, (f) 1150 °C.
Figure 6. Field emission scanning electron microscopy (FE-SEM) pictures of the precursor (a) and the Dy2O3 powders calcined at different temperatures: (b) 950 °C, (c) 1000 °C, (d) 1050 °C, (e) 1100 °C, (f) 1150 °C.
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Figure 7. Photograph of the Dy2O3 ceramics vacuum sintered at 1675, 1780, and 1850 °C for 10 h and air annealed at 1400 °C for 10 h using Dy2O3 powders calcined 950–1150 °C for 4 h.
Figure 7. Photograph of the Dy2O3 ceramics vacuum sintered at 1675, 1780, and 1850 °C for 10 h and air annealed at 1400 °C for 10 h using Dy2O3 powders calcined 950–1150 °C for 4 h.
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Figure 8. In-line transmittance curves of the Dy2O3 ceramics sintered at 1675 °C (a), 1780 °C (b) and 1850 °C (c) for 10 h followed by air annealing at 1400 °C for 10 h using the powders calcined at 950–1150 °C for 4 h and (d) the values of in-line transmittance at 633 nm versus calcination temperature for Dy2O3 powders (thickness = 1.0 mm).
Figure 8. In-line transmittance curves of the Dy2O3 ceramics sintered at 1675 °C (a), 1780 °C (b) and 1850 °C (c) for 10 h followed by air annealing at 1400 °C for 10 h using the powders calcined at 950–1150 °C for 4 h and (d) the values of in-line transmittance at 633 nm versus calcination temperature for Dy2O3 powders (thickness = 1.0 mm).
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Figure 9. Optical microscopy (a,c,e) and FE-SEM pictures (b,d,f) of Dy2O3 ceramics sintered at different temperatures for 10 h and air annealed at 1400 °C for 10 h: (a) 1675 °C etching surface, (b)1675 °C fracture surface, (c) 1780 °C etching surface; (d) 1780 °C fracture surface, (e) 1850 °C etching surface; (f) 1850 °C fracture surface.
Figure 9. Optical microscopy (a,c,e) and FE-SEM pictures (b,d,f) of Dy2O3 ceramics sintered at different temperatures for 10 h and air annealed at 1400 °C for 10 h: (a) 1675 °C etching surface, (b)1675 °C fracture surface, (c) 1780 °C etching surface; (d) 1780 °C fracture surface, (e) 1850 °C etching surface; (f) 1850 °C fracture surface.
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Table 1. The specific surface areas (SBET), average particle sizes (DBET) and average crystallite sizes (DXRD) of the Dy2O3 powders calcined at 950–1150 °C for 4 h.
Table 1. The specific surface areas (SBET), average particle sizes (DBET) and average crystallite sizes (DXRD) of the Dy2O3 powders calcined at 950–1150 °C for 4 h.
Temperature (°C)SBET (m2/g)DBET (nm)DXRD (nm)DBET/DXRD
9505.596131.379.6 ± 1.21.65
10005.131143.288.7 ± 2.21.61
10504.675157.192.6 ± 1.51.70
11003.044241.394.7 ± 1.42.55
11502.591283.5>100-
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Hu, D.; Liu, X.; Liu, Z.; Li, X.; Tian, F.; Zhu, D.; Yang, Z.; Wu, L.; Li, J. Fabrication of Dy2O3 Transparent Ceramics by Vacuum Sintering Using Precipitated Powders. Magnetochemistry 2021, 7, 6. https://0-doi-org.brum.beds.ac.uk/10.3390/magnetochemistry7010006

AMA Style

Hu D, Liu X, Liu Z, Li X, Tian F, Zhu D, Yang Z, Wu L, Li J. Fabrication of Dy2O3 Transparent Ceramics by Vacuum Sintering Using Precipitated Powders. Magnetochemistry. 2021; 7(1):6. https://0-doi-org.brum.beds.ac.uk/10.3390/magnetochemistry7010006

Chicago/Turabian Style

Hu, Dianjun, Xin Liu, Ziyu Liu, Xiaoying Li, Feng Tian, Danyang Zhu, Zhaoxiang Yang, Lexiang Wu, and Jiang Li. 2021. "Fabrication of Dy2O3 Transparent Ceramics by Vacuum Sintering Using Precipitated Powders" Magnetochemistry 7, no. 1: 6. https://0-doi-org.brum.beds.ac.uk/10.3390/magnetochemistry7010006

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