https://doi.org/10.52131/jmps.2021.0201.0013 22 Journal of Materials and Physical Sciences Volume 2, Number 1, 2021, Pages 22 - 32 Journal Homepage: https://journals.internationalrasd.org/index.php/jmps Impact of Lanthanum Doping on the Structural, Electrical, and Magnetic Properties of BaFe12O19 Nano Particles Zaheer Abbas Gilani1, Siraj Ul Islam1, H. M. Noor ul Huda Khan Asghar1*, Rafaqat Husssain1, Furhaj Ahmad Shaikh1 1 Department of Physics, Balochistan University of Information Technology, Engineering & Management Sciences, Quetta 87300, Pakistan ARTICLE INFO ABSTRACT Article History: Received: March 23, 2021 Revised: May 07, 2021 Accepted: June 28, 2021 Available Online: June 30, 2021 These ferrites had been considered very highly valuable electronic materials for many decades. The ferrite compounds have a hexagonal structure. Nano structural and dielectric features for BaFe12-xLaxO19 (0.00, 0.25.0.50, 0.75, 1.00) nano Hexaferrite (NHFs) was studied present research. The Ba NHF prepared via sol-gel technique. The single phase of barium Nano Hexaferrites of various sample was confirmed by XRD, the average crystalline size calculated in the range of 5 to 13nm. The lattice parameter lattice constant, X-ray density, bulk density, micro strain and lattice strain are the parameters of XRD which are also calculated. The different parameters of XRD also show the decreasing and increasing trend which is totally depend on the concentration. The hexagonal structure also confirmed by FTIR. There are two frequency band are investigated which are υ1 and υ2 which are associated with tetrahedral stretching band and octahedral stretching band respectively. The different frequency band are calculated at different frequency like υ1= 500 to 540 and υ2= 413. The dielectric properties also measured in the frequency range from 1 MHz to 3 GHz. There are many others parameters are calculated in dielectric properties such as real and imaginary electric modulus, real and imaginary impedance, dielectric constant, dielectric loss and tangent loss. The parameters of dielectric also showing decreasing and increasing in trend. The real and imaginary impedance plot changes as when the frequency increases, the all the specimens converge on one another, and at a higher frequency, the impedance exhibits coherent nature, which is due to the discharge of space charges. Keywords: Barium Hexa Ferrite Lanthanum Nano Crystallite Ferrites XRD FTIR Dielectric Properties © 2021 The Authors, Published by iRASD. This is an Open Access article under the Creative Common Attribution Non-Commercial 4.0 *Corresponding Author’s Email: noorulhudakhan@gmail.com 1. Introduction In today's environment, magnetic materials are critical components of technology. Humans have recognized the relevance of ferrites for many years by researching their many characteristics (Smit & Wijn, 1959). The improvement and development of ferrites is mostly dependent on the advancement and development of methods. Different characteristics of ferrites, such as magnetization, electrical conductivity and permittivity, and dielectric losses, can be controlled by chemical composition, annealing, and doped metal ions (Al- Hilli, Li, & Kassim, 2012; Gilani et al., 2015). The magnetic and electrical characteristics of Barium hexa ferrite are the most well-known. Such materials are ideally suited due to their strong electrical resistance capabilities. They are widely used in the manufacture of microwave devices. Because of their wide range of applications, barium Hexaferrites are https://journals.internationalrasd.org/index.php/jmps mailto:noorulhudakhan@gmail.com Zaheer Abbas Gilani, Siraj Ul Islam, H. M. Noor ul Huda Khan Asghar, Rafaqat Husssain, Furhaj Ahmad Shaikh 23 important magnetic materials. These materials are synthesized in a variety of ways due to their ease of manufacture, low cost, and high chemical stability (Hussain et al., 2011). Sol- gel technique is used to make these ferrites (Garcia, Bilovol, & Socolovsky, 2012). With the use of a standard doping procedure, the dynamic characteristics of these ferrites may be adjusted to meet the requirements. Doping a suitable element in a certain proportion can have a significant impact on the materials' remarkable characteristics (Smit & Wijn, 1959). The material's crystal structure determines its different characteristics. The characteristics and crystal structure of ferrites are used to classify them. Different ferrites, such as spinel, garnet, and Hexaferrites, have different structures that range from simple to complicated (Carter & Norton, 2007). The crystal phase of BaLaxFe12-xO19, according to the researchers, is a single M-type hexagonal phase. It is important to understand the material's structure in order to examine its characteristics. It is extremely difficult to examine a material's characteristics without first learning about its crystal structure (Cullity, 1978). The X-ray diffraction study of the compositions BaLaxFe12-xO19 (x = 0, 0.25, 0.50, 0.75, 1.00) is addressed in detail in this work. In a straightforward manner, the entire method of indexing and computing different relevant structural characteristics is presented. This understanding will allow for a more exact examination of other materials' diffraction patterns. The ferrites behave like an inhomogeneous dielectric material made up of strongly conducting grains separated by an air gap or insulating layers known as grain boundaries. The dielectric constant, tangent loss, AC conductivity, and impedance of ferrite may all be modified by annealing and composition (Sheikh et al., 2019). X-ray diffraction (XRD), Fourier transform infrared spectroscopy (FTIR), and dielectric characteristics analyses are used to analyze the prepared ferrite material. 2. Experimental The production of different compositions of La doped BaFe12O19 was done using the sol-gel auto-combustion process. To make the series of samples with the general formula BaLaxFe12-xO19 (x = 0, 0.25, 0.50, 0.75, 1.00), stoichiometric amounts of analytical grade reagents, such as Barium nitrate (99%), iron (III) nitrate (98%), lanthanum (III) nitrate (99%), and citric acid (99.5%), were weighed using a precise digital balance. These metal nitrates and citric acid (which was used as a fuel) were dissolved separately in de-ionized water, then combined to produce the mixed solution. The magnetic pill (stirrer) was inserted into the solution, and the beaker was set on a hot plate. The solution was stirred, and the hotplate temperature was progressively increased to 150oC. For around 1 hour, the sample was stirred and agitated until the gel was produced. The temperature of the sample was raised to 300 oC as the gel was produced. When the gel was begun to burn, it was heated at this temperature for around 1 hour. It was let to burn regularly. It took around 1hour for the sample to completely burn. Various gases were emitted from the beaker throughout this time. The final result was a dry powder that was homogeneous. The temperature of the hotplate was progressively reduced once the sample had completely burned. The hotplate was turned off after 10 minutes, and the specimen was allowed to cool in normal temperatures. Despite the fact that the material is now in powder form, this was mixed thoroughly using a pestle and mortar. The sample bottle was filled with fine powder. The samples were all made in the same manner. In a muffle furnace, the samples were placed at 700°C for 3 hours. The samples were pelletized with a 4.5-ton pressure by using hydraulic press. The crystal structure of the produced samples was determined using the diffraction pattern obtained from X-ray diffraction (XRD). The XRD was performed using a panalytical Expert Pro to study the crystal structure and determine various crystalline structural characteristics. The range of values for 2 was specified to be between 10°and 80°. To examine tetrahedral and octahedral stretching bands, FTIR analysis was performed. To study the dielectric characteristics of produced ferrite material, an impedance analyzer was used to conduct a dielectric analysis. Several dielectric characteristics, including as the dielectric constant, dielectric loss, tangent loss, AC conductivity, real and imaginary impedance, and modulus, are computed in the frequency range of 1-MHz to 3-GHz, and their changes are investigated as doping increases. Journal of Materials and Physical Sciences 2(1), 2021 24 3. Result and Discussion 3.1. XRD Analysis Sol gel auto combustion is used to make barium hexa ferrites with the general chemical formula BaLaxFe12-xO19 (x = 0.0, 0.25, 0.50, 0.75, and 1.00). Powder XRD is used on the Panalytical Expert Pro to analyse the crystalline structure in detail and detect the crystalline phase formation. Using this information, the first job is to identify the crystal structure of the sample. It's far more difficult to figure out the crystal structure of an unknown substance than it is to figure out the structure of a recognized one. The pattern of diffracted lines in a diffraction pattern reveals the crystal structure, the placements of lines reveal the unit cell, and the intensities of the lines reveal the positions of the atoms (Cullity, 1978). The initial step is to identify this structure, which will provide information on the crystal structure in which the material is found. For this, the sin2 values for all main diffraction lines are computed. These values serve as a foundation for resolving the pattern. If certain diffraction lines appear owing to imperfections in the material or for other reasons, it causes issues and necessitates the use of additional talents. Combining the plane-spacing equation with Bragg's law equation yields a relationship that specifies the Miller indices of a given crystal system. For a hexagonal system, for example, this formula may be expressed as Sin2= A(h2+hk+k2)+Cl2 (1) In this relation, A = λ 2 /3a 2 ) and C = (λ 2 /4c 2 ). value of A can be calculated from hkl (l=0). The x - ray diffraction pattern of all concentrations of la+3 dopant have been analyzed, all X – ray diffraction values have been observed and shown on the basis of a JCPDS card (reference no 00-027-1029), which shows us a values such as (106), (107) (200) (205) (1110) (300) and (220) at different planes. The values ranged from concentration to concentration, and with the addition of La +3, the value of v increases response to the different ionic radii of the la+3 and iron. The lattice distortion changed as lanthanum was doped in hexa ferrite. By the substitution of rare earth metal in hexa ferrites the also change were identified in the lattice parameter a and c (Azim, Atiq, Riaz, & Naseem, 2014). Figure 1: XRD Analysis of BaLaxFe12-XO19 (x = 0.0, 0.25, 0.50, 0.75, and 1.00). The crystalline size is determined using Debye Sherrer's formula for the hkl value of (107) D =kλ/βcos (2) Zaheer Abbas Gilani, Siraj Ul Islam, H. M. Noor ul Huda Khan Asghar, Rafaqat Husssain, Furhaj Ahmad Shaikh 25 From above equation D represent crystal size, λ shows the wavelength which have the value 1.54A°, where k is also another constant which have fixed value 0.89A°, where β shows the full width half maximum. where theta is used for the most intense peaks. The crystal size of the current material doped with rare earth metal ranges from 13.37 nm to 5.84 nm, as shown in table 1, It Tells us about the crystal size in which the trend is regularly decreasing down to 5 nm. The change in curve totally depend on ionic radii of the present material (Fe+3) and the doped materials lanthanum (La+3) (Onreabroy, Papato, Rujijanagul, Pengpat, & Tunkasiri, 2012). The following formula is used to calculate the lattice constant a and c Sin2=A (h2+hk+k2) + Cl2 (3) Where A=λ2/ 3 a2 and C= λ2 / 4c2 First, the standards of the lattice constant "a" range from 5.83 Ao to 5.90 Ao which are shown in table 1, With different concentrations, it gives different rising and decreasing patterns. The variations are caused by the varying radii of the ions La+3 and Fe+3. As a result, the lattice parameter c has also giving a rising and decreasing pattern based on concentration, as shown in table. The ups and downs in the lattice constant trend was caused by the ionic radii of lanthanum and iron, which are in different ranges for “a” and “c” respectively 5.83Å to 5.90Å and 23.1Å to 23.85Å. A particularly fluctuating pattern are because of divergence between ionic radii of accessible and subbed material in fixation. The following expression was used to calculate the X-ray density. x =2M/NAV (4) Since one-unit cell contains two molecules of the substance, 'M' was its molar concentration of the associated substance, multiplying by '2'. The frequency of Avogadro's number is 6.02 1023, and it is denoted by the letter 'NA.' and the volume of the unit cell is denoted by 'V.' Table values show an improvement in the x-ray density of the relevant hexa ferrite doped with rare earth material, with the cause being an increase in the molecular weight of the substance doped with different amounts. The trend showing the increasing with the concentration level.as we know the molecular weight of iron is 55.84 g/mol and the lanthanum 138.9055 g/mol (Azim et al., 2014; Hussain & Maqsood, 2008). The bulk density was calculated by the following formula = m/πr2h (5) Given equation, m indicates mass, r represents the pellet radius in disk shape, h represents the sample's height. The bulk density of all samples have measured, this discovered the rate increases as the lanthanum concentration increases.it also show some decreasing in trend due to ionic radii. Table 1 Calculated different parameters of XRD of BaLaxFe12-X O19 (X= 0.00, 0.25, 0.50, 0.75, 1.00) Parameters X=0.00 X=0.25 X=0.50 X=0.75 X=1.00 Crystalline size (nm) 13.379936 12.193954 5.840577 6.1512175 6.3740861 Lattice constant a (Å) 5.839255 5.889154 5.841297 5.90298 5.884243 Lattice constant c (Å) 23.82 23.11 23.28 23.1 23.81 Cell volume 199.10048 204.24843 199.30943 205.69035 203.73788 x-ray density (gc/m3) 73.494036 76.802935 76.320313 80.182300 80.826302 Bulk density (gc/m3) 2.1084849 2.501271 2.5638718 2.4333474 2.2706820 Lattice strain was calculated by the following formula which is commonly known as stokes Wilson formula, mathematically this formula is written as Lattice strain = ɛ = β cos / 4tan( )10-3 (6) Journal of Materials and Physical Sciences 2(1), 2021 26 Where ɛ show the lattice strain and the here β was known as FWHM. Micro strain was calculated by the following formula, mathematically this formula is written as Micro strain = β cos/4 10-3 (7) The following mathematical expression was used to calculate the staking fault of BaLaxFe12-xO19 (X= 0.00, 0.25, 0.50, 0.75, 1.00). Staking fault (SF) = 2π2/45/ √3tan ( ) (8) The dislocation density was calculated by the following mathematical expression δ= 1/D2 1015 lines /meter (9) The Lattice strain, Micro strain, Dislocation density and Staking fault trend increasing and decreasing at different level, which is depend upon the different concentration of rare earth metal lanthanum doped (Azim et al., 2014). The notable values are shown in table 2. Table 2 Calculated different parameters of XRD of BaLaxFe12-XO19 (X=0.00, 0.25, 0.50, 0.75, 1.00) Parameters X=0.00 X=0.25 X=0.50 X=0.75 X=1.00 Lattice strain (10-3) 8.985351933 10.57688352 20.21259872 21.81314327 21.85618795 Micro strain (10-3) lines-4/meter-4 2.551977734 2.973008241 5.732231212 6.114914363 6.154438432 Dislocation density 1015 lines /meter 5.546924942 7.528193161 27.98632845 31.84778893 32.26081915 Staking fault 0.464850958 0.467477582 0.465223769 0.468159456 0.467024478 3.2. FTIR The FTIR confirms the formation of hexagonal phases of different compositions. FT- IR spectra of BaLaxFe12-xO19 (x=0.0, 0.25, 0.50, 0.75, and 1.00) with various La+3 ion compositions (x=0.0, 0.25, 0.50, 0.75, and 1). There are two frequency bands widths are tracked. From Fig 2 the two frequency bands are ranged as υ2 =413 cm-1 and υ1 =525- 537cm-1.υ1 the large frequency (almost 510 -550) cm-1 due to the inherent absorption bands at the tetrahedral site, and the other is at low frequency range υ2 ( 390-430) cm-1 due to octahedral extending bands (Sheikh et al., 2019). All of the characteristic peaks in Fig 2 can be attributed to M-type barium hexa ferrite. The values of υ1 change to a higher wave number as the La3+ ion content rises, and this can be assigned to the M-type barium ferrite. The values of υ1 change to a greater wavelength as the La3+ ion level increased, and this can be explained by two main realities. The first is that La+3 ions have a lower atomic weight than Fe3+ ions, and the second is that even the atomic weight is inversely proportional to the wave number (El-Sayed, Meaz, Amer, & El Shersaby, 2013). The gap in bond length of Fe3+– O-2 at tetrahedral and octahedral sites induced a shift in the intensity of the absorption bands, i.e. ‘υ1' and ‘υ2'. All of the prepared nanoparticle sets reveal that as the lanthanum concentration increased, the frequency band changes significantly, which may be attributed to grain size and lattice parameters (Shahzadi et al., 2020). Furthermore, Using the bandwidth knowledge, the force coefficients Kt and Ko for octahedral and tetrahedral locales are calculated using the formula below. Ko = 0.942128M (υ 2)2/ (M+32) (10) Kt =√2Ko υ 1/ υ 2 (11) Where M shows the atomic weight of material, where υ1 and υ2 are different frequency. we investigate the constant force to improve the fixation, which demonstrates the conceivable reinforcing of bonding between. Zaheer Abbas Gilani, Siraj Ul Islam, H. M. Noor ul Huda Khan Asghar, Rafaqat Husssain, Furhaj Ahmad Shaikh 27 Figure 2: FTIR Spectra of BaLaxF12-x O19 The tetrahedral and octahedral radii are likewise gotten from the accompanying equations. R Tetra = 𝑎√3( u−0.25 )−Ro (12) Rocta = 𝑎( 5 / 8−u ) −Ro (13) Where Rtetra (tetrahedral radii) and Rocta (octahedral radii), also u and “a” are different parameter, in above equation “a” is known as lattice parameter and oxygen position parameter is u (Sheikh et al., 2019). Table 3 The measured parameters for FTIR Parameters x = 0.0 x = 0.25 x = 0.50 x = 0.75 x = 1.00 Molecular weight 1111.47 1132.2363 1153.0025 1173.7688 1194.535 υ1 / cm −1 530 525 532 536 537 υ2 / cm −1 413 413 413 413 413 Ko(dyne/cm 2)×105 1.56201 1.56281 1.56358 1.56433 1.56505 Kt/(dyne/cm 2) ×105 2.83481 2.80951 2.84838 2.87117 2.87785 3.3. Dielectric Properties The dielectric properties of synthesized ferrite materials with a basic equation of BaLaxFe12-xO19 (x = 0.0, 0.25, 0.50, 0.75, and 1.00) are measured at room temperature using LCR meter over a frequency range of 1 MHz to 3 GHz. Dielectric properties of M-type hexa-ferrites for the substitution of rare earth metal are studied as the function of frequency at encompassing temperature. 3.3.1.Dielectric Constant and Dielectric Loss The graph between permittivity vs frequency is shown below. The dielectric constant has been measured experimentally by using formula given below. ɛʹ =C × d / A×ɛ (14) Journal of Materials and Physical Sciences 2(1), 2021 28 Figures 3 display the variance of dielectric constant vs frequency for BaLaxFe12-xO19 ferrites (x = 0.00, 0.25, 0.50, 0.75, 1.00) at room temperature. The statistics demonstrate that as the Fig 2 display the variance of dielectric constant, dielectric loss vs frequency for BaLaxFe12-xO19 ferrites (x = 0.00, 0.25, 0.50, 0.75, 1.00) at room temperature. This were discovered that the electrical interchange among Fe2+ and Fe3+ causes neighborhood movement, which determine polarization. The plots demonstrate that equally real and imaginary components of dielectric constants indicate frequency scattering. The dielectric constant, dielectric loss values are low at low frequency but instead quickly increases as frequency increases along with frequency of whole structures, indicating a basic pattern for every ferrite sample, this action reflects dispersion. According to Koop's phenomenological theory, this behavior portrays dispersion caused by Maxwell Wagner type interfacial polarization (Iqbal, Islam, Ali, Sadiq, & Ali, 2014). Figure 3: (a) The Dielectric Constant as a function Frequency (b) The Dielectric loss as function of Frequency 3.3.2.Tangent Loss and AC Conductivity The graph clearly shows the tan loss goes down with growing frequency. The electrons follow the field when the frequency of the given alternating current of field of force is even lower compare the hopping frequency of ions among Fe2+ and Fe3+ electrons at neighboring octahedral sites, the ions obey the area thus loss was greatest. (Tan loss) is high at high frequency and rapidly increase at high frequency, according to Koop's phenomenological theorem. As a result, tan loss in the low frequency region is expected to be high, while tan loss in the high frequency region is expected to be high (Iqbal et al., 2014). Table 4 Dielectric parameters for BaLaxFe12-xO19 Parameters Frequency x = 0.0 x = 0.25 x = 0.50 x = 0.75 x = 1.00 Dielectric constant 1MHz 5.22376 4.16556 4.44576 5.41444 5.0067 1GHz 5.159 4.21558 4.60433 5.02073 4.75967 2.5GHz 4.49196 4.09188 5.56372 4.94024 4.45486 3GHZ 4.27519 3.60566 4.25219 4.41541 4.52102 Dielectric loss 1MHz 0.30928 0.38993 -0.05495 -0.33232 0.0531 1GHz -0.02137 0.14784 0.00664 0.07233 0.22985 2.5GHz 1.57008 0.3185 1.31588 0.23878 0.8102 3GHZ 0.1106 -0.01209 0.38168 0.21544 0.40735 Tan loss 1MHz 0.05921 0.09361 -0.01236 -0.06138 0.01061 1GHz -0.00414 0.03507 0.00144 0.01441 0.04829 2.5GHz 0.34953 0.07784 0.23651 0.04833 0.18187 3GHZ 0.02951 0.00163 0.09316 0.05468 0.09635 About 1 MHz and 3 GHz, the AC conductivity of the prepared ferrite sample BaLaxFe12-xO19 (x = 0.0, 0.25, 0.50, 0.75, 1.00) is measured. The expression to be utilized Zaheer Abbas Gilani, Siraj Ul Islam, H. M. Noor ul Huda Khan Asghar, Rafaqat Husssain, Furhaj Ahmad Shaikh 29 σ ac = (t ∕ A) × [zʹ/(zʹ2 + zʺ2 )] (15) where “t” shows that the thickness of pellet, area of the pellet is known as A, Fig 5 illustrates the frequency-dependent alternating current conductivity of all sintered material. The AC conductivity with all samples start to increases from low frequency range, but dispersion conducting was observed at higher frequencies. Ferrite substance are made up of transmitting grains isolated by conductive small sections of grain borders, according to both the Maxwell–Wagner model and the Koop’s conceptual principle. Since dielectric distortion is related to absorption processes. Because of growing resistance of crystal structure the activity of all composition seems to be the same at low frequency (Parveen et al., 2019). Figure 4: (a) Tangent loss as a function of frequency (b) AC conductivity as a function of frequency 3.3.3.Real and Imaginary Impedance Impedance is important in deciding the dielectric possessions of materials. The real and imaginary impedances are strongly directly proportional to the frequency. Fig 6 represent the impedance as a role of the frequency, which ranges between 1 MHz and 3 GHz. The real and imaginary impedance portions of impedance are measured as for each ferrite BaLaxFe12-xO19 (x = 0.0, 0.25, 0.50, 0.75, 1.00),. By using the following formula to calculate the real and imaginary impedance. Zʹ = R = | Z| cos z, (16) Zʺ = X = | Z| sin z, (17) According to impedance analysis, the rise of The frequency at which it is used eliminates the real and imaginary sections of impedance. The impedance plot changes as when the frequency increases, the all the specimens converge on one another, and at a higher frequency, the impedance exhibits coherent nature, which is due to the discharge of space charges. The decrease in real and imaginary impedance components means that conductivity improves as field frequency increases, owing to the concentration difference and the non-uniformity of the given field, which tends to add these distinct charges on the crystal structure. Above are both the imaginary and real impedance diagram. Journal of Materials and Physical Sciences 2(1), 2021 30 Figure 6: (a) The Real impedance as a function with log of frequency (b) The Imaginary impedance as function with log of frequency 3.3.4.Real and Imaginary Electric Modulus Modulus structures were being utilized to investigate the position of grain boundaries over a defined frequency spectrum. Under the given frequency, the imaginary and real modulus of samples is investigated. The following are the formulas for calculating real and imaginary modulus. Mʹ = ɛʹ/(ɛʹ2+ɛʺ) (18) Mʹʺ = ɛʹʹ/(ɛʹ2+ɛʺ) (19) Figures 7 demonstrate the real and imaginary electric modulus. At short frequencies, the real and imaginary components of the electric modulus have very small rates and rise sequentially as the given field frequency rises, while at large frequencies, they reach their limit (3 GHz) (Parveen et al., 2019).The electrical modulus of BaLaxFe12-xO19 ferrites, which induced electrically charged concentration across the inorganic nanoparticles in expelling stimulation peaks, is used to investigate the frequency response of the concentration polarization impact. The sample of impedance with Zʺ vs Zʹ provides a better representation of the concentric spheres in the plane if the region of accuracy of the grain boundary is reduced. If the crystal structure region covers a great volume, the trend for modulus Mʺ vs Mʹ provides huge data about the semicircle. Figure 7: (a) Real Electric Modulus as a function of Frequency (b) Imaginary Electric Modulus as a function of Frequency Zaheer Abbas Gilani, Siraj Ul Islam, H. M. Noor ul Huda Khan Asghar, Rafaqat Husssain, Furhaj Ahmad Shaikh 31 Table 5 AC conductivity, Impedance, Modulus for BaLaxFe12-XO19 (X=0.00, 0.25, 0.50, 0.75, 1.00) Parameters Frequency X=0.00 X=0.25 X=0.50 X=0.75 X=1.00 AC conductivity 1 MHZ 4.4444E-05 1.336E-05 6.119E-06 6.5352E-06 5.62068E-06 1 GHZ 0.00221902 0.0123562 0.000939 0.00582268 0.019071805 2.5 GHZ 0.34628092 0.0683428 0.282689 0.0482143 0.16648189 Zʹ (ohms) 1 MHZ 82209147.0 14892846 1504486. 1666936.62 1430707.84 1 GHZ 0.15416373 8.7130111 0.038683 1.15298201 14.4860242 2.5 GHZ 114.489572 7.4630427 55.06665 2.15162838 32.3932633 zʺ(ohms ) 1 MHZ 618646744 88370979 61590350 606886338 653764098 1 GHZ 5436.83400 7331.8375 6432.649 5665.38172 6117.66131 2.5 GHZ 834.987484 1221.1404 751.5586 932.680606 1018.09238 Mʹ 1 MHZ 0.1424188 0.1702161 0.1421027 0.1410586 0.1464052 1 GHZ 0.1342679 0.1559214 0.1460475 0.137061 0.1424269 2.5 GHZ 0.1310757 0.1585131 0.1243551 0.1385316 0.1447358 Mʺ 1 MHZ 0.0164175 0.0069877 0.002221 0.0023378 0.00216581 1 GHZ 0.000715 0.0053751 0.0003581 0.0019553 0.00693064 2.5 GHZ 0.0485361 0.012392 0.033661 0.0066537 0.02581722 4. Conclusion From decades, these ferrites were regarded as extremely useful electrical materials. The ferrite compounds have a hexagonal structure, but there is also a category of ferrites called hexaferrites that have a hexagonal crystal structure. Nano structural and dielectric features for BaFe12-xLaxO19 (0.00, 0.25.0.50, 0.75, 1.00) nano Hexaferrite (NHFs) was studied present research. The Ba NHF prepared via sol-gel technique. The sol gel process is used to efficiently synthesize Nano crystalline ferrite with the structural formula BaLaxFe12-xO19 (x=0.00, 0.25, 0.50, 0.75, 1.00).sol gel technique is very easy method to synthesized that type of ferrite. With their sharp peak, XRD studies affirm the hexagonal structure. The Debye Scherer expression is used to measure crystalline size, which is observed to be in the Nano size range of 13 nm to 5 nm. The lattice constant also calculated by using the hkl with respect to the present materials JCPDS Card. The values of the lattice constant “a” in range from 5.83 Å to 5.90 Å, as with different concentrations, it gives different rising and decreasing patterns. The values of the lattice constant “c” in range from 23.10 Å to 23.83 Å, as with different concentrations, it gives different rising and decreasing patterns due to ionic radii. The crystal size pattern shows the decreasing order in crystal size. The FTIR confirms the formation of hexagonal phases of different compositions. FTIR findings indicate two stretching frequency bands corresponding to octahedral and tetrahedral, which are typical bands of hexagonal ferrite. In the frequency range of 1 MHZ to 3GHZ. The two frequency υ2 =413 cm-1 and the other υ1 =525-537cm-1. υ1 is the large frequency (almost 510 -550) cm-1 due to the inherent absorption bands at the tetrahedral site, and the other is at low frequency range υ2 (390-430) cm-1 due to octahedral extending bands. Dielectric experiments are carried out. Dielectric experiments give the permittivity and permit loss increase as change with frequency. The real and imaginary impedance curves change as when the frequency increases, the all the specimens converge on one another, and at a higher frequency, the impedance exhibits coherent nature, which is due to the discharge of space charges. There are many others parameters are calculated in dielectric properties such as real and imaginary electric modulus, real and imaginary impedance, dielectric constant, dielectric loss and tangent loss. Conflict of Interest The authors declare that they have no conflict of interest. Reference Al-Hilli, M. F., Li, S., & Kassim, K. S. (2012). Structural analysis, magnetic and electrical properties of samarium substituted lithium–nickel mixed ferrites. Journal of Magnetism and Magnetic Materials, 324(5), 873-879. Journal of Materials and Physical Sciences 2(1), 2021 32 Azim, M., Atiq, S., Riaz, S., & Naseem, S. (2014). Indexing the structural parameters and investigating the magnetic properties of lanthanum doped strontium hexaferrites. Paper presented at the IOP Conference Series: Materials Science and Engineering. Carter, C. B., & Norton, M. G. (2007). Ceramic materials: science and engineering (Vol. 716): Springer. Cullity, B. D. (1978). Elements of X-ray diffraction, Addison. Wesley Mass. El-Sayed, S., Meaz, T., Amer, M., & El Shersaby, H. (2013). Magnetic behavior and dielectric properties of aluminum substituted M-type barium hexaferrite. Physica B: Condensed Matter, 426, 137-143. Garcia, R. M., Bilovol, V., & Socolovsky, L. (2012). Effect of the heat treatment conditions on the synthesis of Sr-hexaferrite. Physica B: Condensed Matter, 407(16), 3109- 3112. Gilani, Z. A., Warsi, M. F., Khan, M. A., Shakir, I., Shahid, M., & Anjum, M. N. (2015). Impacts of neodymium on structural, spectral and dielectric properties of LiNi0. 5Fe2O4 nanocrystalline ferrites fabricated via micro-emulsion technique. Physica E: Low-dimensional Systems and Nanostructures, 73, 169-174. Hussain, S., & Maqsood, A. (2008). Structural and electrical properties of Pb-doped Sr-hexa ferrites. Journal of Alloys and Compounds, 466(1-2), 293-298. Hussain, S., Shah, N. A., Maqsood, A., Ali, A., Naeem, M., & Syed, W. A. A. (2011). Characterization of Pb-doped Sr-ferrites at room temperature. Journal of superconductivity and novel magnetism, 24(4), 1245-1248. Iqbal, M. A., Islam, M., Ali, I., Sadiq, I., & Ali, I. (2014). High frequency dielectric properties of Eu+ 3-substituted Li–Mg ferrites synthesized by sol–gel auto- combustion method. Journal of Alloys and Compounds, 586, 404-410. doi:10.1016/j.jallcom.2013.10.066 Onreabroy, W., Papato, K., Rujijanagul, G., Pengpat, K., & Tunkasiri, T. (2012). Study of strontium ferrites substituted by lanthanum on the structural and magnetic properties. Ceramics International, 38, S415-S419. Parveen, A., Khalid, M., Gilani, Z. A., Aslam, S., Saleem, M., Shaikh, F. A., & Rehman, J. (2019). Dielectric, impedance and modulus spectroscopic studies of Co 0.3 Cd 0.7 Zn 1.5 x Fe 2− x O 4 nanoparticles. Applied Physics A, 125(10), 1-11. Shahzadi, K., Chandio, A. D., Mustafa, G., Khalid, M., Khan, J. K., Akhtar, M. S., & Gilani, Z. A. (2020). Impact of aluminum substitution on the structural and dielectric properties of Ni–Cu spinel ferrite nanoparticles synthesized via sol–gel route. Optical and Quantum Electronics, 52(4), 1-17. Sheikh, F. A., Khalid, M., Shifa, M. S., Aslam, S., Perveen, A., ur Rehman, J., . . . Gilani, Z. A. (2019). Effects of bismuth on structural and dielectric properties of cobalt- cadmium spinel ferrites fabricated via micro-emulsion route. Chinese Physics B, 28(8), 088701. Smit, J., & Wijn, H. (1959). Ferrites, philips technical library. Eindhoven, The Netherlands, 278.