Synthesis of nano-BaWO4 by a modified combustion technique and its suitability for various applications are reported. The structure and phase purity of the sample analyzed by X-ray diffraction, Fourier transform Raman, and infrared spectroscopy show that the sample is phase pure with tetragonal structure. The particle size from the transmission electron microscopy is 22 nm. The basic optical properties and optical constants of the nano BaWO4 are studied using UV-visible absorption spectroscopy which showed that the material is a wide band gap semiconductor with band gap of 4.1 eV. The sample shows poor transmittance in ultraviolet region while maximum in visible-near infrared regions. The photoluminescence spectra show intense emission in blue region. The sample is sintered at low temperature of 810°C, without any sintering aid. Surface morphology of the sample is analyzed by scanning electron microscopy. The dielectric constant and loss factor measured at 5 MHz are 9 and 1.56×10-3. The temperature coefficient of dielectric constant is −22 ppm/°C. The experimental results obtained in the present work claim the potential use of nano BaWO4 as UV filters, transparent films for window layers on solar cells, antireflection coatings, scintillators, detectors, and for LTCC applications.
1. Introduction
The ever increasing scientific and technological demand for novel materials with unique properties poses challenges to scientific research. Nanomaterials have caught the interest of researchers because of its exceptional properties which are completely different from its bulk material. Synthesis of advanced functional materials in nanoscale is one of the prime fields of interest.
Generally, AWO4 (A = Ba, Sr, Ca, Pb) tetragonal scheelite-type crystals of divalent metal ion tungstate have been of immense interest because of their remarkable properties such as luminescence, nonlinear optical activity, photocatalysis, and scintillation [1–7]. Among them, BaWO4 is a significant material due to its excellent PL emission and stimulated Raman scattering active crystal. The reasons for blue and green PL emissions of BaWO4 are discussed in many different aspects ranging from defect centers by interstitial oxygen atoms to structural disorder in the crystal lattice [8–11]. BaWO4 also serves as a potential material for designing all solid-state lasers, especially that it has been considered as a unique Raman crystal for a wide variety of pump pulse durations in Raman laser pulses [12–17]. Its other applications include nuclear spin optical hole burning hosts [6], radiation detection [1], scintillating devices [4], and other electro-optic applications [1]. Since the properties of materials can be tuned by its microstructure, different morphological BaWO4 such as nanowires, spheres, cylinders, whiskers, penniform BaWO4 nanostructures, and flower-like structures were prepared [18–23] and methods like solid-state reaction [24–26], hydrothermal-method [9, 27–29], Czochralski [30–33], high temperature flux crystallization [34], polymeric precursor chemical route [35], microwave-assisted synthesis [36, 37], and micro emulsions-based routes [19, 38] were employed for the synthesis.
However, even though the luminescent behavior of scheelite BaWO4 remains much investigated, its other optical constants and dielectric applications are not much explored. Hence, in the present work we have specifically concentrated on the studies of the suitability of nano-BaWO4 powders, synthesized through a single step modified combustion technique, for their various optical as well as electrical applications. In addition, we report the results of structural characterization, photo luminescence, sintering behavior, and dielectric performance. Prime novelty of our study is the sintering of nano-BaWO4 at a very low temperature of 810°C for the first time without any sintering aid, which points out its use as a low temperature cofired ceramic (LTCC). We have also investigated detailed optical studies of the compound owing to its tremendous potential for application as UV filters, sensors, and transparent conducting oxide films for solar windows.
2. Experimental
Even though there are various methods reported for the synthesis of BaWO4, many of them need high processing temperatures, long reaction time, postcalcinations, and sophisticated equipments as well. In the following years, the scientific community is in search of the development of easy, economical, and nonhazardous preparation techniques with which we can control the size and shape of the particles in order to tune their properties. In this context, a widely used combustion technique is very relevant that it is cost effective and time saving and provides high quality phase pure nanoproduct [39].
For the preparation of nano-BaWO4, we opted a modified combustion process using ammonia and citric acid which were used as fuel and complexing agent, respectively. Aqueous solutions containing Ba and W ions were prepared by dissolving stoichiometric amounts of Ba(NO3)2 and ammonium paratungstate in double distilled water. Citric acid was then added to the solution as complexing agent. Oxidant to fuel ratio of the system was adjusted by adding concentrated nitric acid and ammonium hydroxide solution and the ratio was kept at unity. The precursor solution of pH ~7.0 was then heated using a hot plate at ~250°C in a ventilated fume hood. The solution boils on heating, and undergoes dehydration accompanied by foam. On persistent heating the foam gets autoignited giving a voluminous fluffy nanopowder of BaWO4.
Structure of the as-prepared powder was examined by powder X-ray diffraction (XRD) technique using a Bruker D-8 X-ray diffractometer with nickel filtered Cu Kα radiation. Particulate properties of the combustion product were examined using transmission electron microscopy (TEM, Model-Hitachi H-600 Japan) operating at 200 kV. The Infrared (IR) spectra of the samples were recorded in the range 400–4000 cm−1 on a Thermo-Nicolet Avatar 370 Fourier transform infrared (FT-IR) spectrometer using KBr pellet method. The Fourier transform-Raman spectrum of the nanocrystalline BaWO4 was carried out at room temperature in the wave number range 50–1200 cm−1 using Bruker RFS/100S Spectrometer at a power level of 150 mW and at a resolution of 4 cm−1. The samples were excited with an Nd:YAG laser lasing at 1064 nm, and the scattered radiations were detected using Ge detector. The photoluminescence (PL) spectra of the samples were measured using FluoroLog-3 Spectrofluorometer. The photons from the source were filtered by an excitation spectrometer. The monochromatic radiation was then allowed to fall on the disc samples, and the resulting radiation was filtered by an emission spectrometer and then fed to a photomultiplier detector. The variation of intensity was recorded as a function of wavelength. The optical measurements of the nanopowder were carried out at room temperature using a Cary 100 BIO UV-VIS spectrophotometer in the wavelength range from 200–700 nm. The sample for the analysis was a 2 mM solution of BaWO4 prepared by dispersing the nanopowder in ethanol taken in 1 : 20 volume ratio. The same solvent was used as the blank for the analysis in order to calibrate the spectrophotometer.
To study the sinterability of the nanoparticles obtained by the present combustion method, the as-prepared BaWO4 nanoparticles were mixed with 5% polyvinyl alcohol and pressed in the form of cylindrical pellet of 12 mm diameter and ~2 mm thickness at a pressure about 350 MPa using a hydraulic press. The sintering temperature pellet was optimized at 810°C for 3 h after conducting many trials. The surface morphology of the sintered sample was examined using scanning electron microscopy (SEM, Model-JEOL JSM 5610 LV). For low frequency dielectric studies, the pellets were made in the form of a disc capacitor with the specimen as the dielectric medium. Both the flat surfaces of the sintered pellet were polished and then electroded by applying silver paste. The capacitance of the sample was measured using an LCR meter (Hioki-3532-50 LCR HiTester) in the frequency range 100 Hz–5 MHz at different temperatures from 30 to 250°C.
3. Results and Discussion
The XRD pattern of the as-prepared BaWO4 nanopowder is shown in Figure 1. All the peaks including the minor ones are indexed for a perfect tetragonal scheelite with space group 141/a. This clearly shows that the BaWO4 phase formation was complete during the combustion process itself without the need for any postcalcinations step. In the case of solid state synthesis of BaWO4 [23], the mixture is ball milled for 24 h and calcined at 800°C in order to obtain the required phase. Thus, modified combustion method offers an economic and time saving technique since the as-prepared powder itself is phase pure without any calcination at high temperature.
XRD pattern of as-prepared BaWO4 nanopowder.
The lattice constants calculated from the XRD are a=b=5.5609 and c=12.7123 Å. The calculated values of lattice constants are consistent with that reported in JCPDS NO 72-0746. The small variations in the values could be due to the quantum size effect of nanoparticles and the rapid formation kinetic energy of BaWO4 during the combustion process, resulting in a small distortion of the lattice. The crystallite size calculated from full width at half maximum (FWHM) using Scherrer formula is ~20 nm.
Figure 2 shows the TEM image and selected area electron diffraction (SAED) pattern of as-prepared nano-BaWO4 nanoparticles. The average particle size calculated from the TEM micrograph is 22 nm. The particles in the TEM image are not agglomerated which points to the excellent crystalline nature of the nanopowder. SAED pattern have a number of bright polycrystalline concentric diffraction rings. The rings are diffused and hollow showing that the products are composed of nanocrystals with different orientations. The electrons reflected and diffracted from the different crystallographic planes of the unit cells of BaWO4 produce these bright spots. These well distinguished rings are a clear evidence of the high crystalline nature of the sample.
TEM micrograph and SAED pattern of nano-BaWO4.
Vibrational spectroscopy is a fine method for investigating the structural details of a compound. In order to understand the degree of structural disorder of the scheelite BaWO4 nanopowder, FT-Raman and FT-IR spectra of the sample are recorded and are given in Figures 3 and 4, respectively.
Raman spectrum of as-prepared nano-BaWO4 prepared by combustion technique.
FT-IR spectrum of as-prepared nano-BaWO4 prepared by combustion technique.
In tetragonal scheelite phase, Ba atoms are surrounded by eight oxygen atoms, and tungsten atoms are surrounded by four oxygen atoms in tetrahedral configuration to form [WO4]2−. It is reported by Basiev et al. [40] that the primitive cell of the tungstate crystal includes two formula units, and the Raman spectra of scheelite crystals can be divided into two groups, internal and external. The first is called lattice phonon mode which corresponds to the motion of Ba2+ cation and the rigid molecular unit. The second belongs to the vibration of inside [WO4]2− molecular units with the centers of mass stationary.
Raman-active phonon modes can be employed to estimate the structural order at a short range of a material. The group theory calculation presents 26 different vibrations for the BaWO4, which is represented by [40, 41]
(1)Γ=3Ag+5Au+5Bg+3Bu+5Eg+5Eu,
where all Ag, Bg, and Eg modes are Raman-active in which Eg modes are doubly degenerate, Ag and Bg modes are nondegenerate and the odd modes 4Au and 4Eu can be registered only in FT-IR spectra. The three Bu modes are silent ones, whereas one Au and Eu modes are acoustic vibrations. Thus, we expect 13 Raman-active modes in BaWO4.
All the observed Raman modes are the characteristics of a scheelite tetragonal [9, 40–42]. The internal modes ν1(Ag), ν2(Eg), ν3(Eg), and ν4(Bg) were observed at 924, 842, 790, 361, 345, and 326 cm−1. The free rotation mode was detected at 190 cm−1, and the external modes were localized at range 141–78 cm−1.
The FT-IR spectra of the BaWO4 were carried out in transmittance mode. Since BaWO4 has tetrahedral symmetry (Td), only F2(ν3,ν4) modes are infrared active. A strong absorption peak at 410 cm−1 can be assigned to F2(ν4) vibration mode which represents the bending vibration of W–O. The antisymmetric stretching vibration F2(ν3) originating from the W–O in WO42- tetrahedron corresponds to the broad intense peak at 823 cm−1. Besides this strong band, a medium intense band can be seen in the region 632 cm−1 which can be attributed to W–O antisymmetric stretching vibrations. Our results match well with the early reported literatures [37, 42].
The absence of two Bg modes and small discrepancy observed in the Raman-active modes when compared to early reports [37–40] may be due to the different preparation method, average crystal size, and structural disorder degree in the lattice. The absence of certain modes and activeness of modes at same regions of IR and Raman spectra points to the lowering of symmetry of crystal structure leading to short range distortion of crystal lattice which exactly corroborates with the XRD results.
The UV-Visible absorption, reflectance, and transmission spectra of nano-BaWO4 are shown in the Figures 5(a), 5(b), and 5(c), respectively. Sample shows maximum absorption in the UV region with a steep absorption edge centered at 254 nm. At the visible region, the sample is nearly 63% transparent while its reflectance is almost 18%. Maximum absorption in the UV region along with uniform transparency in the visible region makes the sample ideal for UV sensors, filters, and screening applications. Also, the property of high transmittance and low reflectance in the visible region makes the material a good candidate for transparent windows in solar cells.
(a) Absorbance, (b) reflectance, and (c) transmittance spectra of nano-BaWO4.
The Wood and Tauc [43] equation was used to estimate the optical band gap of nano-BaWO4 nanopowder. According to this equation, the optical band gap energy is related with absorbance and photon energy by the following equation:
(2)αhϑ=(βhϑ-Eg)m,
where β is an energy independent constant, α is the optical absorption coefficient, h is the Planck constant, ν is the frequency of incident photon, Eg is the optical band gap, and m is a constant which characterizes the nature of band transition. m=1/2 and 3/2 corresponds to direct allowed and direct forbidden transitions, and m=2 and 3 corresponds to indirect allowed and indirect forbidden transitions, respectively. The optical band gap can be obtained from the extrapolation of the straight-line portion of the (αhν)1/m versus hν plot to hν=0.
The optical absorption coefficient α is determined using the relation
(3)α=-lnTd,
where T is the optical transmittance and d is the optical path length through the cuvette.
The variation of α with photon energy is established in Figure 6. The absorption coefficient shows a maximum in the UV region and falls off to NIR region. It shows a maximum at 4.5 eV around 1.23 cm−1. The existence of sharp absorption band is an indication of excellent crystalline nature of the nanosample. The calculated optical band gap is also illustrated in Figure 6. The band gap of the sample is found to be 4.1 ev, which is exactly matching with the value reported by Cavalcante et al. [9], Anicete-Santos et al. [42], and Tyagi et al. [44] for BaWO4. The present obtained value is lower than that reported by Lima et al. [11] which is 5.67 eV. The lowering of band gap can be due to several factors such as changes in local atomic structure, lowering of symmetry of lattice, electro negativity of transition metal ions, connectivity of the polyhedrons, deviation in the O–X–O bonds, oxygen vacancies, distortion of the [XO4]2− tetrahedrons, and intrinsic surface states [45–47]. From the Raman spectra, it is confirmed that the sample possess certain degree of structural disorder which would have resulted in the formation of intermediate energy levels between the valance and conduction band. As the band gap is the energy difference between valance and conduction band, the presence of these intermediate levels resulted in the reduction of optical band gap energy. AS BaWO4 prepared by the present method possess wide band gap along with good transmittance in the visible region is suitable for transparent conducting oxide films for window layers on solar cells.
(a) Variation of alpha with photon energy and (b) Tauc’s plot of nano-BaWO4.
The complex refractive index (n=n+ik) and dielectric function (ε=ε1+iε2) also characterize the optical properties of any solid material. The normal incidence reflectivity R can be given by [48]
(4)R=(n-1)2+k2(n+1)2+k2,
where k is extinction coefficient and n is the refractive index of the sample. The extinction coefficient k indicates the amount of absorption loss when the electromagnetic wave was propagated through the material and can be calculated using the relation [49]
(5)k=αλ4π.
The variation of n and k with photon energy observed for the samples is demonstrated in Figure 7. The refractive index n and extinction coefficient k increase with increasing frequency. The variation of n and k values shows that some interactions took place between photons and electrons in the frequency range studied. It is found that the maximum values of n and k from the graph are at 2.8 and 3.2 × 10−6, respectively, which occur at the same photon energy 4.75 eV. The peak values of n and k observed in the UV region indicate that the material can be considered as a good inorganic UV absorber. As BaWO4 has a high refractive index (n>1.8), it causes a large proportion of photons to be trapped by total internal reflections which is the reason for its use as scintillators and as detectors in CRESST for dark matter research [50].
Variation of n and k with photon energy.
The fundamental electron excitation spectrum of the nanopowder has been described by means of frequency dependence of the complex electronic dielectric constant. The complex dielectric constant is an intrinsic and fundamental property of a material. The real part of the term is associated with how much it will slow down the speed of light in the material, and the imaginary part of the term shows how the dielectric absorbs energy from the electric field due to dipole motion. The real and imaginary parts of the dielectric constant were determined using the relation [51]
(6)ε=ε1+iε2=(n+ik),
where ε1 and ε2 are the real and imaginary parts of the dielectric constant, respectively, and are given by
(7)ε1=(n2-k2),ε2=2nk.
The dependence of ε1 and ε2 on photon energy is illustrated in Figure 8. Both ε1 and ε2 increase with photon energy and show maximum peaks around 9.25 and 1.28 × 10−5, respectively, at 4.5 eV.
Variation of complex dielectric constants ε1 and ε2 with photon energy.
A material is optically conductive when it shows conductivity on exposure to electromagnetic radiation. The optical conductivity of the sample is determined using the relation [52]
(8)σ=αnc4π,
where c is the velocity of light.
Figure 9 demonstrates the variation of optical conductivity with incident photon energy. It is seen from the figure that the optical conductivity increases with increasing energy. The reason for the increase in optical conductivity is due to the fact that the electrons are excited by photon energy and possess more kinectic energy than that in its ground state. Optical conductivity shows a value of 6.9 × 109 Sm−1 at 4.5 eV and a minimum value of 2.72 × 109 Sm−1 at 1.5 eV. The high value of optical conductivity in the visible region indicates that nano-BaWO4 could be ideal for the fabrication of solar cell panels.
Variation of optical conductivity σ with photon energy.
The scheelite tungstate compounds are well known for their luminescence activity. The PL emission spectra of as-prepared BaWO4 nanopowder is shown in Figure 10(a). The sample exhibited a broad blue emission peak as expected and a medium intense peak in the green region of the visible spectra. There are several reports which explain the mechanisms responsible by the PL emission in scheelite tungstates. The luminescent properties of BaWO4 are mainly determined by two reasons; the first one is the charge-transfer transitions between the O2p orbits and the empty d orbits of the central W6+ ions in [WO4]2− tetrahedron, [53] and the second one is due to the structural distortions in the crystal lattice. The tungsten cation ideally tends to bond with four oxygen ions (WO4), and the barium cation tends ideally to bond with eight oxygen ions (BaO8 pseudocubic configuration). In the structure, just before the complete ordering at short range, there exist various coordination environments for the W such as WO3 and WO4. The existence of WO3 and distorted WO4 clusters in the lattice are able to induce the formation of intermediary energy levels within band gap. These energy levels are composed of oxygen 2p states (near the valence band) and tungsten 5d states (below the conduction band). In this case, the polarization induced by the symmetry break and the existence of these localized energy levels are favorable conditions for the formation of trapped holes and trapped electrons. It is generally accepted that the higher energy blue emission of tungstates with scheelite structure is due to the radiative decay of self-trapped excitons localized at the regular [WO4]2− complexes, and the low energy green emission is associated with structural defects [9–11, 42, 44, 47]. The presence of defective state levels was also confirmed from the UV-Vis analyses.
PL spectra of (a) as-prepared and (b) 700°C heated nano-BaWO4.
In order to reduce the structural disorder, the sample was annealed at 700°C for 1 hour, and again the PL spectrum was recorded as the fact that highly disordered and highly ordered structures at short range are not favorable to intense PL emission [42]. The emission spectrum of annealed sample is as in Figure 10(b). Annealing had resulted in an increased intensity of the emission. The blue emission gets intensified while the green emission decreases considerably. The main reason for the diminishing of emission in green region may be due to the fact that high ordering is achieved by the WO4 and BaO8 molecular groups due to annealing.
The sintering behavior of the nanocrystals of BaWO4 powder synthesized through the present combustion route was studied. The relative green density of the specimen used for the sintering study was 55%. A sintered density of ~95% of the theoretical value was obtained upon sintering the compacted specimen at 810°C for 3 h. It may be noted that the BaWO4 powder prepared through solid state method by earlier Yoon et al. [23] obtained a well sintered pellet at higher temperature of 1150°C. In the present work, the sintering temperature is nearly 340°C lesser than the early reports, and this optimum sintering temperature is achieved without adding any sintering agents. The reduction of sintering temperatures for the nanomaterials when compared to its conventional micro ceramics is mainly due to its higher surface area than the bulk materials. Since sintering start at the surface, availability of large surface area amount to lowering the corresponding temperatures. Thus, we could sinter BaWO4 at a lower temperature of 810°C without any sintering aid, for the first time.
The SEM image of the sintered sample is shown in Figure 11. The surface morphology of sintered sample shows maximum densification. It is observed from the micrograph that the size of the grains has increased from 500 nm to about 2 μm due to sintering, with no cracks and very little porosity.
SEM image of sintered BaWO4 pellet.
The dielectric constant εr and the loss factor tanδ values of the sintered pellets were studied in the frequency range 100 Hz to 5 MHz at room temperature with silver electrodes on both sides of the circular disc and are given in Figure 12(a). It can be clearly noted that the loss factor decreases as frequency increases, while the dielectric constant remains almost unaltered in high frequency region. The dielectric constant εr and loss factor tanδ values of the BaWO4 pellets at 5 MHz in room temperature were ~9 and 1.56 × 10−3, respectively. The value of dielectric constant is well agreeing with that reported in the literature [23, 54].
(a) Variation of dielectric constant εr and loss factor tanδ with respect to frequencies and (b) with respect to temperature.
The variation of εr and tanδ at different temperature ranging from 30–250°C is shown in Figure 12(b). It is clear from the graph that the temperature dependence of dielectric constant is very minimal in the measured temperature range. The loss factor further lowers with increase of temperature and is of order 10−3 at temperature above 100°C. At 250°C, the value of εr is 8.5 and that of tanδ is 4.5 × 10−4.
The temperature coefficient of dielectric constant (TCK) is determined using the equation given below between temperatures 250°C and 30°C at 5 MHz,
(9)TCK=K250-K30220*1K30*106,
where K30 and K250 are the dielectric constants at 30°C and 250°C, respectively, and 220 is the temperature difference. The obtained TCK is −22 ppm/°C. Thus, nano-BaWO4 possess negative temperature coefficient of dielectric constant.
The significance of the present work is the development of nanostructured scheelite tetragonal BaWO4, a potential wide band gap semiconductor and transparent conduction oxide material, for optical applications through a modified combustion method. The powder was sintered at a very low temperature of 810°C without any sintering aid for the first time to examine its application as LTCC material. The accomplishment of this type sintering is that we could get the well densified sample without compromising its properties. Already a few studies on the low temperature sintering of scheelite ceramics using various sintering aid, its dielectric properties, and their suitability as LTCC materials were reported [54–58]. Zhuang et al. [55–57] sintered Ba5Nb4O15-BaWO4 and Ba3(VO4)2-BaWO4 composites at a low temperature of ~900°C and studied its dielectric properties for LTCC application, while the effect of BaWO4 ceramic filler content on the dielectric properties of the BaWO4-poly-tetrafluoroethylene laminates composites for microwave substrate application was investigated by James et al. [58]. Usually, glass and polymer composite materials are used for LTCC applications. But their high values of dielectric loss, thermal mismatch, and high sintering temperature impose restrictions on their effective use as LTCC materials. The doping of sintering aid would result in poor dielectric response such as high loss and low quality factor. BaWO4, in this case, possess a very low tanδ value and low temperature coefficient of dielectric constant. The novelty of our technique is that we could get a glass free as well as dopant free pure ceramic nano material for LTCC applications. The low sintering temperature, dielectric constant, and loss factor make nano structured BaWO4 prepared by the combustion method confirm its suitability as a promising candidate for its application as LTCC, substrate, and electronic packing materials. The negative temperature coefficient values of this compound also ensure the stability of the dielectric permittivity with temperature when it is used as LTCC material in multilayer circuits.
4. Conclusions
Nanocrystalline semiconducting BaWO4 was synthesized through a modified combustion process. The X-ray diffraction studies showed that the nanopowder was single phased with tetragonal structure. The FT-IR and Raman spectral analysis confirm that the as-prepared powder itself is phase pure with a short range distortion. TEM analysis confirms that the nanocrystalline nature of the sample has a mean size of 22 nm. The UV-VIS spectra analysis revealed that the material is a wide band semiconductor of band gap 4.1 eV along with good transmittance in the visible region which makes it suitable for transparent conducting oxide films for window layers on solar cells, warming coatings, solar control, and antireflection coatings. Because of the high refractive index of 2.5, it could be used as scintillators and as detectors in CRESST for dark matter research. The high value of optical conductivity in the visible region indicates that nano-BaWO4 could be ideal for the fabrication of solar cell panels. The nanocyrstalline BaWO4 is found to be a photoluminescent material with emissions in blue and green regions. On annealing green emission intensity decreases which is attributed to the perfect ordering of the crystal. These nanocrystals could be sintered at a relatively low temperature of 810°C to a high density without any sintering aid. The SEM image of the sintered sample indicates that the material achieved high densification. The room temperature dielectric constant (εr) and the loss factor tanδ of the sintered pellet at 5 MHz were ~9 and 1.56 × 10−3, respectively. The temperature coefficient of dielectric constant is −22 ppm/°C. The decrease in sintering temperature, low dielectric constant, and low loss factor indicates that nano-BaWO4 are excellent low temperature cofired ceramics, substrate material, and electronic packing materials.
Conflict of Interests
The authors declare that they have no conflict of interests.
Acknowledgment
The authors acknowledge the Council of Scientific and Industrial Research (CSIR), New Delhi Council, for the financial assistance.
NiklM.BohacekP.MihokovaE.KobayashiM.IshiiM.UsukiY.BabinV.StolovichA.ZazubovichS.BacciM.Excitonic emission of scheelite tungstates AWO4 (A = Pb, Ca, Ba, Sr)200087113611392-s2.0-003373706610.1016/S0022-2313(99)00569-4LeeA. J.PaskH. M.PiperJ. A.ZhangH.WangJ.An intracavity, frequency-doubled BaWO4 Raman laser generating multi-watt continuous-wave, yellow emission2010186598459922-s2.0-7794964636810.1364/OE.18.005984CernýP.JelínkováH.ZverevP. G.BasievT. T.Solid state lasers with Raman frequency conversion20042821131432-s2.0-084233010510.1016/j.pquantelec.2003.09.003BasievT. T.OsikoV.ProkhorovA. M.DianovE. M.Crystalline and fiber raman lasers200389359408NinkovicaJ.AngloherG.BucciC.CozziniC.FrankT.HauffD.KrausH.MajorovitsB.MikhailikV.PetriccaF.ProbstF.RamachersY.RauW.SeidelW.UchaikinS.CaWO4 crystals as scintillators for cryogenic dark matter search20055371-2339343CaprezA.MeyerP.MikhailP.HulligerJ.New host-lattices for hyperfine optical hole burning: materials of low nuclear spin moment1997328104510542-s2.0-0031209911AfanasievP.Molten salt synthesis of barium molybdate and tungstate microcrystals20076123-24462246262-s2.0-3454804349710.1016/j.matlet.2007.02.061BasievT. T.DanileikoY. K.DoroshenkoM. E.FedinA. V.GavrilovA. V.OsikoV. V.SmetaninS. N.High-energy BaWO4 Raman laser pumped by a self-phase-conjugate Nd:GGG laser20041479179212-s2.0-4444245103CavalcanteL. S.SczancoskiJ. C.EspinosaJ. W. M.VarelaJ. A.PizaniP. S.LongoE.Photoluminescent behavior of BaWO4 powders processed in microwave-hydrothermal20094741-21952002-s2.0-6164911077210.1016/j.jallcom.2008.06.049YinY.GanZ.SunY.ZhouB.ZhangX.ZhangD.GaoP.Controlled synthesis and photoluminescence properties of BaXO4 (X = W, Mo) hierarchical nanostructures via a facile solution route20106467897922-s2.0-7574913568810.1016/j.matlet.2010.01.024LimaR. C.Anicete-SantosM.OrhanE.MaureraM. A. M. A.SouzaA. G.PizaniP. S.LeiteE. R.VarelaJ. A.LongoE.Photoluminescent property of mechanically milled BaWO4 powder200712627417462-s2.0-3424859034810.1016/j.jlumin.2006.11.005DuS.ShiY.ZhangD.LiQ.FengB.ZhangJ.-Y.ZangJ.-C.High-peak power multi-wavelength picosecond pulses generated from a BaWO4 Raman-seeded optical parametric amplifier200928214296029632-s2.0-6624911634310.1016/j.optcom.2009.03.056ČernýP.ZverevP. G.JelínkováH.BasievT. T.Efficient Raman shifting of picosecond pulses using BaWO4 crystal200017713974042-s2.0-003390266210.1016/S0030-4018(00)00575-7ŠulcJ.JelínkováH.BasievT. T.DoroschenkoM. E.IvlevaL. I.OsikoV. V.ZverevP. G.Nd:SrWO4 and Nd:BaWO4 Raman lasers20073011951972-s2.0-3444762085210.1016/j.optmat.2006.10.019LiL.ZhangX.LiuZ.WangQ.CongZ.ZhangY.WangW.WuZ.ZhangH.A high power diode-side-pumped Nd:YAG/BaWO4 Raman laser at 1103 nm20132304540210.1088/1054-660X/23/4/045402ZhaoJ.ZhangX.GuoX.BaoX.LiL.CuiJ.Diode-pumped actively Q-switched Tm, Ho:GdVO4/BaWO4 intracavity Raman laser at 2533 nm20133812061208GaoL.WangQ. P.ZhangX. Y.LiuZ. J.BaiF.ChenX. H.ShenH. B.High-power Nd:YVO4/BaWO4 intracavity Raman laser emitting at 1103 nm2012109913ShiH.QiL.MaJ.ChengH.Synthesis of single crystal BaWO4 nanowires in catanionic reverse micelles200216170417052-s2.0-0036056121LiD.WuH.LiZ.CongX.SunJ.RenZ.LiuL.LiY.FanD.HaoJ.Multi-phase equilibrium microemulsions-based routes to synthesize nanoscale BaWO4 spheres, cylinders and rods20062741–318232-s2.0-3114446164010.1016/j.colsurfa.2005.08.033XieB.WuY.JiangY.LiF.WuJ.YuanS.YuW.QianY.Shape-controlled synthesis of BaWO4 crystals under different surfactants20022351–42832862-s2.0-003646727310.1016/S0022-0248(01)01800-0ShiH.QiL.MaJ.ChengH.Polymer-directed synthesis of penniform BaWO4 nanostructures in reverse micelles200312512345034512-s2.0-003746741810.1021/ja029958fLiuJ.WuQ.DingY.Controlled synthesis of different morphologies of BaWO4 crystals through biomembrane/organic-addition supramolecule templates2005524454492-s2.0-1644437941610.1021/cg0498002KwanS.KimF.AkanaJ.YangP.Synthesis and assembly of BaWO4 nanorods200154474482-s2.0-0035820020FujitaT.YamaokaS.FukunagaO.Pressure induced phase transformation in BaWO41974921411462-s2.0-0016026436YoonS. H.KimD.-W.ChoS.-Y.HongK. S.Investigation of the relations between structure and microwave dielectric properties of divalent metal tungstate compounds20062610-11205120542-s2.0-3364554153510.1016/j.jeurceramsoc.2005.09.058ParhiP.KarthikT. N.ManivannanV.Synthesis and characterization of metal tungstates by novel solid-state metathetic approach20084651-23803862-s2.0-5014909514810.1016/j.jallcom.2007.10.089ZhangF.YangS.-P.ChenH.-M.WangZ.-H.YuX.-B.The effect of an anionic starburst dendrimer on the crystallization of BaWO4 under hydrothermal reaction conditions20042673-45695732-s2.0-294252098910.1016/j.jcrysgro.2004.03.076ChoW.-S.YoshimuraM.Hydrothermal, hydrothermal-electrochemical and electrochemical synthesis of highly crystallized barium tungstate films1997363121612222-s2.0-0031100509ZhangL.DaiJ.-S.LianL.LiuY.Dumbbell-like BaWO4 microstructures: surfactant-free hydrothermal synthesis, growth mechanism and photoluminescence property2013548795IvlevaL. I.VoroninaI. S.LykovP. A.BerezovskayaL. Y.OsikoV. V.Growth of optically homogeneous BaWO4 single crystals for Raman lasers200730411081132-s2.0-3424757091310.1016/j.jcrysgro.2007.02.020RanD.XiaH.SunS.LingZ.GeW.ZhangH.Thermal conductivity of BaWO4 single crystal20061301–32062092-s2.0-3384620130110.1016/j.mseb.2006.03.018ChauhanA. K.Czochralski growth and radiation hardness of BaWO4 crystals20032543-44184222-s2.0-003882377910.1016/S0022-0248(03)01193-XGeW.ZhangH.WangJ.LiuJ.LiH.ChengX.XuH.XuX.HuX.JiangM.The thermal and optical properties of BaWO4 single crystal20052761-22082142-s2.0-2034439662910.1016/j.jcrysgro.2004.11.385RoyB. N.RoyM. R.Estimation of activation parameters for diffusion-controlled crystallization of barium tungstate from sodium tungstate melts by differential thermal analysis19811612671271PontesF. M.MaureraM. A. M. A.SouzaA. G.LongoE.LeiteE. R.MagnaniR.MachadoM. A. C.PizaniP. S.VarelaJ. A.Preparation, structural and optical characterization of BaWO4 and PbWO4 thin films prepared by a chemical route20032316300130072-s2.0-014146177110.1016/S0955-2219(03)00099-2ShenY.LiW.LiT.Microwave-assisted synthesis of BaWO4 nanoparticles and its photoluminescence properties20116519-20295629582-s2.0-7995992260810.1016/j.matlet.2011.06.033LimC. S.Solid-state metathetic synthesis of BaMO4 (M = W, Mo) assisted by microwave irradiation20111255445482-s2.0-83455201714KimK.HuhY. -D.Facile synthesis of BaWO4 sub-micron sized octahedron via a microemulsion method2012331034893492PatilK. C.Advanced ceramics: combustion synthesis and properties19931665335412-s2.0-002778653910.1007/BF02757654BasievT. T.SobolA. A.VoronkoY. K.ZverevP. G.Spontaneous Raman spectroscopy of tungstate and molybdate crystals for Raman lasers20001532052162-s2.0-003450207810.1016/S0925-3467(00)00037-9DesgreniersS.JandlS.CarloneC.Temperature dependence of the Raman active phonons in CaWO4, SrWO4 and BaWO419844511-12110511092-s2.0-0021629977Anicete-SantosM.PiconF. C.AlvesC. N.PizaniP. S.VarelaJ. A.LongoE.The role of short-range disorder in BaWO4 crystals in the intense green photoluminescence20111152412180121862-s2.0-7995925600310.1021/jp2009622WoodD. L.TaucJ.Weak absorption tails in amorphous semiconductors197258314431512-s2.0-000113459010.1103/PhysRevB.5.3144TyagiM.SinghS. G.ChauhanA. K.GadkariS. C.First principles calculation of optical properties of BaWO4: a study by full potential method201040521453045352-s2.0-7795710356810.1016/j.physb.2010.08.032ZhangW. F.YinZ.ZhangM. S.Study of photoluminescence and electronic states in nanophase strontium titanate200070193962-s2.0-003368426310.1007/s003390050018EngH. W.BarnesP. W.AuerB. M.WoodwardP. M.Investigations of the electronic structure of d0 transition metal oxides belonging to the perovskite family20031751941092-s2.0-004182703910.1016/S0022-4596(03)00289-5CavalcanteL. S.SczancoskiJ. C.TranquilinR. L.JoyaM. R.PizaniP. S.VarelaJ. A.LongoE.BaMoO4 powders processed in domestic microwave-hydrothermal: synthesis, characterization and photoluminescence at room temperature20086911267426802-s2.0-5534908888910.1016/j.jpcs.2008.06.107HeavensO. S.1965New York, NY, USADoverMarquezE.Ramirez-MaloJ.VillaresP.Jimenez-GarayR.EwenP. J. S.OwenA. E.Calculation of the thickness and optical constants of amorphous arsenic sulphide films from their transmission spectra19922535355412-s2.0-002683752410.1088/0022-3727/25/3/031WahlD.MikhailikV. B.KrausH.The Monte-Carlo refractive index matching technique for determining the input parameters for simulation of the light collection in scintillating crystals200757035295352-s2.0-3384612258310.1016/j.nima.2006.10.099MárquezE.Bernal-OlivaA. M.González-LealJ. M.Prieto-AlcónR.LedesmaA.Jiménez-GarayR.MártilI.Optical-constant calculation of non-uniform thickness thin films of the Ge10As15Se75 chalcogenide glassy alloy in the sub-band-gap region (0.1-1.8 eV)19996032312392-s2.0-003259215410.1016/S0254-0584(99)00078-4TepehanF.ÖzerN.A simple method for the determination of the optical constants, n and k of cadmium sulfide films from transmittance measurements19933043533652-s2.0-0027659424RyuJ. H.YoonJ.-W.LimC. S.OhW.-C.ShimK. B.Microwave-assisted synthesis of CaMoO4 nano-powders by a citrate complex method and its photoluminescence property20053901-22452492-s2.0-1344427884110.1016/j.jallcom.2004.07.064KimE. S.KimS. H.LeeB. I.Low-temperature sintering and microwave dielectric properties of CaWO4 ceramics for LTCC applications20062610-11210121042-s2.0-3364554783010.1016/j.jeurceramsoc.2005.09.064ZhuangH.YueZ.ZhaoF.LiL.Low-temperature sintering and microwave dielectric properties of Ba5Nb4O15-BaWO4 composite ceramics for LTCC applications20089110327532792-s2.0-5334910917110.1111/j.1551-2916.2008.02670.xZhuangH.YueZ.ZhaoF.PeiJ.LiL.Microstructure and microwave dielectric properties of Ba5Nb4O15-BaWO4 composite ceramics20094721-24114152-s2.0-6134912734510.1016/j.jallcom.2008.04.073ZhuangH.YueZ.MengS.ZhaoF.LiL.Low-temperature sintering and microwave dielectric properties of Ba3(VO4)2-BaWO4 ceramic composites20089111373837412-s2.0-5674913274910.1111/j.1551-2916.2008.02672.xJamesN. K.RajeshS.MuraliK. P.Stanly JacobK.RatheeshR.Preparation and microwave characterization of BaWO4 filled polytetrafluoroethylene laminates for microwave substrate applications20102112125512612-s2.0-7865069832310.1007/s10854-010-0058-2