Tailoring Variations in the Microstructures, Linear/Nonlinear Optical, and Mechanical Properties of Dysprosium-Oxide-Reinforced Borate Glasses

Abstract

Hybrid dysprosium-doped borate glassy samples [B-Gly/Dy]^HDG (Borate Glass/Dysprosium)^{Hybrid Doped Glass} were prepared in this study via the melt-quenching method. Its linear/nonlinear optical, photoluminescence, hardness indentation, and micro-creep properties were analyzed. The amorphous structure for all the prepared samples was confirmed from the XRD patterns. In addition, density functional theory (DFT), optimized by TD-DFT and Crystal Sleuth, was used to study the structure and crystallinity of the [B-Gly/Dy]^HDG as isolated molecules and agreed with the peaks of experimental XRD patterns. Additionally, theoretical lattice types were studied using Polymorph, a content studio software, and orthorhombic Pc21b (29) and triclinic P-1 (2) structures were provided. Both mechanical and optical properties were responses to different concentrations of Dy₂O₃ in the glassy borate system. It was found that the length of indentation increases by increasing the load time, and the hardness decreases by increasing the load time. The stress exponent value also increased from 4.1 to 6.3. The indentation strain increases by increasing the load time. The direct optical band gap was evaluated using the Davis–Mott relation. Urbach energy and its connection to the disorder degree in materials were studied depending on the Dy₂O₃ concentration. The acquired optical parameters were also analyzed to determine the nonlinear refractive index as well as the linear and third-order nonlinear optical susceptibility of the investigated glass samples. The photoluminescence emission spectra were recorded, and their attributed transitions were studied. The mechanical studies showed that the hardness values increased by increasing Dy₂O₃ concentrations from 4160.54 to 5631.58 Mpa. The stress exponent value also increased from 4.1 to 6.3. Therefore, the higher value of stress exponent (S) is more resistant to indentation creep.

1. Introduction

With the diversity of glass compositions and improved analysis methods, glass structures suitable for every technological need have been created. Recently, a glass system based on borate reinforced with several oxides has been widely scrutinized due to its outstanding properties [1]. Boric oxide is used to make glass using BO₃ units alone, and the BO₃ units are converted to BO₄ units by adding various cations. Due to the rupturing of B-O-B and the splitting of bridged oxygen [2,3,4,5,6]. Zinc oxide is often employed as a glass matrix modifier, causing defects by breaking the B-O-B link, forming non-bridged oxygen atoms, and creating dangling bonds [7,8,9,10,11,12]. Because of their unique properties, such as effective radiation shielding, a broad glass formation zone, and low melting temperatures, lead borate glasses are highly favored in technical applications [13,14]. Essentially, borate glass frameworks containing lead oxide are notable for their increased visual transmittance [15]. Over glass systems, the essential and optimum utilization of zinc and lead oxide as network exchangers decreases phonon energy [16,17]. Because of their ornamental qualities, rare earth elements are employed in glass production [18,19]. Because of the qualities of glass doped with rare earth elements, it may be used in various applications, including laser materials, plasma screens, optical waveguides, fiber amplifiers, and efficient amplifiers [20,21,22,23].

All oxide glasses based on (B₂O₃, SiO₂, TeO₂, and P₄O₆) have been proven to be the most suitable host materials for the progress of optoelectronic components [24,25]. It is possible to assume that glass based on borate is the most frequent variety because of its excellent transparency, chemical resistance, and thermal stability [26]. The low phonon energy host glass extends lower non-radiative relaxation rates and strong quantum efficiencies [27,28,29]. The optical homogeneity of the glassy matrix causes RE ions to display a variety of latent laser transitions. The spectroscopic analysis of RE ions in glasses yields information on the excited states’ transition probabilities, lifetimes, and branching ratios, all of which are important in the design and growth of different electro-optic and optical systems [30,31,32,33].

Neoteric TDDFT applications (DMol³ and Crystal Sleuth) for researching the structure of glass matrix, stability phase, and nanocomposite compounds [34,35,36] are reviewed. The use of this complete energy-based method for the estimation and investigation of spectroscopic properties has received little attention. This article discusses the structural study using a limited programming language [37]. The objective is to demonstrate that the same atomistic modeling techniques may be consistently employed throughout the experimental inquiry to achieve high levels of precision [38]. In order of crystallinity investigations, Polymorph used content studio software to study the possible crystal sites for the compounds and predict the final crystal structure of the system [39].

In the present work, the impact of Dy₂O₃ additive on the optical and mechanical characteristics of a novel glass system with chemical composition; (50 − x)B₂O₃ + 40Pb₃O₄ + 10CaO + xDy₂O₃ with the different substitution ratio of Dy₂O₃ (x = 0, 1, 2, 3, 4 and 5) was prepared. To explore and describe the modification of the bandgap structure, the UV–Vis absorbance spectra of the studied glass samples were investigated. The effect of adding different ratios of Dy₂O₃ on indentation creep behavior and micro-hardness values has been analyzed.

2. Materials and Methods

2.1. Materials and Reagents

All the oxides (raw materials) used in the study (B₂O₃, Pb₃O₄, CaO, and Dy₂O₃) were purchased from Oxford Laboratory. In contrast, dysprosium oxide was obtained from (Sigma-Aldrich, MO, USA) at a purity of 99.9%.

2.2. Experimental Procedure

The nominal compositions for the six studied glass samples (50 − x)B₂O₃ + 40Pb₃O₄ + 10CaO + xDy₂O₃ with varied Dy₂O₃ content (x = 0, 1, 2, 3, 4, and 5 wt%) were produced using the traditional solid-state approach. Dy0 (x = 0), Dy1 (x = 1), Dy2 (x = 2), Dy3 (x = 3), Dy4 (x = 4), and Dy5 (x = 5) were used to code the glass samples. Boron oxide (B₂O₃), lead oxide (Pb₃O₄), calcium oxide, and dysprosium oxide (Dy₂O₃) were well mixed before being pre-heated for 120 min at 300 degrees Celsius. The resulting formulations were thermally heated in a porcelain crucible at 1100 °C for 30 min before being cast onto a stainless-steel mold to originate glass samples in a disc form. The melting temperature of Dy₂O₃ increased from 1100 °C to 1300 °C when the substitution ratio of Dy₂O₃ increased. Following quenching, the produced samples were directly annealed in a muffle furnace set to 300 °C [34]. The structure of the samples has been studied at room temperature by powder X-ray diffraction analysis using a Bruker, AXS D8 Advance, Germany (Cu-Kα radiation). UV-visible absorption was recorded using the Shimadzu UV-2450 spectrophotometer at a range of (190–900 nm); all the measurements were taken at room temperature. Photoluminescence emission spectra were measured by HoRiBA (IHR 320) using a He-Cd laser with a wavelength of 442 nm as an excitation source.

A digital Vickers microhardness tester was used to accurately measure the hardness of glass specimens (Model FM-7 Future-Tech. Corp. Tokyo Japan). Micro indentation creep methods have substantial benefits in terms of speed, non-destructiveness, accuracy, and accessibility. For all types of glasses and surface treatments, only one indenter type may be utilized [35,36]. Although testing the softest and hardest materials under varying loads is more adaptive and accurate, the surface is subjected to standard stress for a record period using a pyramid-shaped diamond. An indentation is a pyramid with opposite sides that meet at a 136-degree angle. It applies 10 gf of diamond pressure to the material’s surface, and the impression size (typically no more than 0.5 mm) is assessed using a microscope. The Vickers indenter leaves an impression of a black square on a light background, swinging the microscope over a specimen to measure a ±1/1000 mm square depression. The area is calculated by averaging 10 measurements made across the diagonals for each sample.

The following formula is used to compute the number of Vickers (HV) [40,41]:

$$\mathrm{HV}=2\mathrm{F} \mathrm{Sin}\left({136}^{\mathrm{o}}/2\right)/2/{\mathrm{d}}^2$$

(1)

meaning that HV = $1.854\mathrm{F}/{\mathrm{d}}^{2 } \mathrm{approximately},$ where (F) and (d) are the applied load force and average diagonal length.

3. Results

3.1. Structural, Optical, and Mechanical Properties

3.1.1. X-ray Diffraction Analysis

The XRD spectral characteristics of the manufactured [B-Gly] and [B-Gly/Dy]^HDG were compared with the characteristics of the system-isolated matrix (by TD-DFT simulation). The X-ray diffraction patterns of the manufactured glasses with various quantities of Dy₂O₃ additions are shown in Figure 1. This distinctive proved a completely amorphous nature for all samples under study. By changing the concentration of Dy₂O_3, the position and the intensity of the broad prominent peak at 2θ ≈ (29°) are changed.

The XRD patterns in Figure 2a,b demonstrate that [B-Gly] and [B-Gly/Dy₅]^HHG are nearly identical. The XRD analysis in Figure 2a,b indicates that [B-Gly] and [B-Gly/Dy₅]^HNC are almost similar at 2θ = 25.77°. For the different doped concentrations of dysprosium (lanthanides of inert transition elements), two peaks appeared at 2θ = 6.81° and 2θ = 13.62°.

Table 1. The experimental and calculated XRD data using the Refine Version 3.0 (Carnegie Mellon University, Pennsylvania) Software Program (Kurt Barthelme’s & Bob Downs) for experimental [B-Gly] and [B-Gly/Dy]^HDG and simulated parts [B-Gly]^Iso and [B-Gly/Dy]^Iso.

Symmetry	Observed					Computed
	2θ (°)	d (Å)	hkl	FWHM	Int. (a)	2θ (°)	d (Å)	${\mathit{D}}_{\mathit{A}\mathit{v}}$	$\mathit{\delta } { }^{\left(\mathit{d}\right)}$
[B-Gly] Orthorhombic Pc21b (29)
a = 7.74; b = 9.06 and c = 14.82Å	25.77	3.454	020	5.1945	1316.87	26.16	3.456	9.159	109.2
α = γ = β = 90°; V = 1153(4);	35.63	2.554	$\overline{4}21$	0.5971	192.571	35.55	2.561	79.68	12.55
rmse (b)= 0.00002625, Average				2.8958				44.42	60.87
[B-Gly/Dy]HDG Monoclinic2 C1c1(9)	6.771	14.153	101	2.4289	690.493	6.808	14.069	195.88	51.05
a = 6.88; b = 6.89; c = 6.93	12.343	7.4859	201	4.0595	1067.41	12.69	7.2745	117.20	85.32
α = 90.0; β = 110(1)°, γ = 90.0°	25.071	3.6246	020	5.8625	4650.11	24.98	3.6373	81.160	123.2
Machine error = 0.531	31.180	2.9146	$\overline{5}$14	4.4735	2020.23	31.35	2.8985	106.35	94.03
V = 1600(37);	34.101	2.6674	$\overline{6}$05	0.5971	92.0390	33.93	2.6810	79.680	125.5
rmse (b) = 0.00123	35.632	2.5545	$\overline{4}$21	0.2228	40.7130	35.55	2.5605	213.54	46.83
	38.417	2.3728	$\overline{4}$24	5.229	193.835	38.58	2.3632	90.990	109.9
	45.798	2.0016	$\overline{1}$32	2.7222	140.681	45.70	2.0057	174.78	57.22
	58.329	1.5939	$\overline{7}$31	1.7931	89.2510	58.37	1.5928	265.34	37.69
	62.204	1.5027	$\overline{1}$11	2.2945	116.484	62.19	1.5029	207.36	48.23
Average								150.32	77.90

Intensity: ^(b) root-mean-square error; ^(b) nm and ^(c) = 10⁻³. ^(a)—lattice parameters, and ^(d)—Crystallite size.

demonstrates the relationship between the miller index (hkl) and the estimated average crystallite size (D), and the full width at half maximum (FWHM) absolute values. A good agreement between the interplanar distances (d) and the data in database code amcsd 96-411-7035 [42,43] and 0019483 [44] were observed. Diffraction peaks that were quite close to the [B-Gly] and [B-Gly/Dy]^HDG measured data were generated by TDDFT and Crystal Sleuth Microsoft applications [45].

The X-ray diffraction pattern of [B-Gly] and [B-Gly/Dy]^HDG was evaluated by applying the Debye–Scherrer relation, along with the Pesedo–Voigt function; the polarization nearly equal to 0.5 and $1/dhkl=0.0566{Å}^{-1}-0.7446{Å}^{-1}$, $\lambda =1.540562 Å$, $I_2/I_1=0.5$ in the range of 5 ≤ 2θ ≤ 80°. Using the formula of Scherer $\mathrm{D}=0.9\mathsf{\lambda }/\left(\mathrm{FWHM}.\cos \mathsf{\theta }\right)$, where λ = 1.541838 Å, which is the wavelength of the X-ray [46,47]. As presented in Table 1, features such as peak intensity, d-spacing (d), Miller indices (hkl), the average crystallite size (D), and FWHM were studied using the X-ray diffraction data from [B-Gly] and [B-Gly/Dy]^HDG. The average crystalline size is $(D_{av})=44.42 \mathrm{nm} \mathrm{and} 150.32 \mathrm{nm}$ for [B-Gly] and [B-Gly/Dy]^HDG, respectively [48,49,50]. Additionally, theoretical X-ray diffraction models were determined by content studio software computations used in Polymorph [see (Figure 2 Inset)]. The integrals performed on the Brillouin zone are shown in the inset of Figure 2 with $2x2x1$ (Polymorph [B-Gly] and [B-Gly/Dy]^HDG. Estimated PXRD patterns were compared with the experimental XRD structures for the relevant experiment. There is only a slight difference in the position and strength of the specific peaks between the simulated and experimental XRD models; therefore, the general similarity has attracted much attention. Many factors influence the experimental XRD pattern, of which instrumentation and data collection techniques are only two [33].

The simulated XRD for [B-Gly]^Iso and [B-Gly/Dy]^Iso as isolated molecules provides orthorhombic Pc₂₁b (29) and triclinic P-1 (2) structures, respectively. For the experimental patterns of [B-Gly] and [B-Gly/Dy]^HDG, at 2θ equal to 25.77°, prominent peaks at hkl ($020$) appeared. Using the above assessment, the PXRD pattern accuracy of the fabricated material was validated. The atomic scale of [B-Gly]^Iso and [B-Gly/Dy]^Iso was estimated depending on the experimental and calculated PXRD patterns combination [51]. Additionally, the density of the defect was calculated by [52] $\delta =\frac{1}{D},$ specified as the dislocation line length per unit volume. The difference between average crystallite size calculation of borate glassy sample [B-Gly] and dysprosium doped borate glassy samples [B-Gly/Dy]^HBG ($∆D_{Av}$) by the equation of Scherrer and based on the highest peak of diffraction related to (020)1 crystal plane gives the value of ≅ $(∆D_{Av}=150.32-44.42=105.90 \mathrm{nm}$). It can be conculcated that the high-value difference in crystallite size is an attribute to the high atomic mass of dysprosium (Mol. Wt_Dy = 162.50), which is doped in the borate glassy samples [53].

3.1.2. UV–Vis Spectrum Analysis

The glass samples’ UV–Vis absorbance spectra were recorded at room temperature to define and describe the changes in the bandgap structure. The UV–Vis absorption spectra of all produced glass samples are shown in Figure 3.

The UV–Vis absorption spectra of the samples investigated demonstrate that the sample at x = 0 has a prominent UV absorption peak at around 432 nm. The glasses’ absorption band was expanded. Due to the amorphous nature of glass samples, there is no robust increase in absorption at energies near the band gap, which appears as an absorption edge in the UV–Vis absorption spectra. The broad band of near-visible light concentrated at around 425 nm shifted to a wider wavelength (redshift) of 435 nm, originating from band gap transitions with increasing Dy₂O₃ concentration levels. The absorbance spectrum shows an absorption band peak at 800 nm as Dy₂O₃ content was added to the glass: this peak is attributable to the spin-allowed transitions of Dy³⁺ at the ground state (⁶H_15/2) into different exciting H states [49].

The Davis–Mott relation (2) has been utilized to generate optical energy gaps for the examined substances [54,55]:

$$\mathsf{\alpha }\left(hv\right)=x{\left(hv-E_g\right)}^{1/n}/hv$$

(2)

where (E_g) denotes the optical energy band gap of the glass samples, (A) denotes a constant, (α) denotes the absorption coefficient, and hν denotes the incident spectrum photon energy. For direct transitions and plots of (αhν)² vs. hν, calculated band gap energies for glass samples were studied using n = 2 and plots of (αhν)² vs. hν, as shown in Figure 4. In the straight transition from 2.95 eV to 2.90 eV indicated in

Table 2. Concentration (C), Urbach energy (E_u), energy gap indirect (E_OIn), energy gap direct (E_OD), linear refractive index (n), (${\chi }^1, {\chi }^3)$ linear and third-order nonlinear optical susceptibility for the prepared glass samples.

Samples	C (wt%)	Eu (eV)	EOD (eV)	λcut-off (nm)	n(a)	χ1	χ3 (b)	n2 (c)
1	X = 0	0.43	3.07	432	1.35	0.066	3.19	0.89
2	X = 1	0.52	3.14	426	1.38	0.072	4.63	1.26
3	X = 2	0.56	3.11	429	1.39	0.073	4.88	1.32
4	X = 3	0.57	3.05	438	1.55	0.112	0.26	6.5
5	X = 4	0.55	3.07	433	1.37	0.071	4.31	1.18
6	X = 5	0.67	3.09	435	1.49	0.099	0.16	4.13

^(a) = (linear refractive index); ^(b) = 10⁻¹⁵, ^(c) = (non-linear refractive index) 10⁻¹⁵ at (λ = 700 nm).

, the computed band gap energies were slightly adjusted from 3.07 eV for the sample at x = 0 to 3.09 eV at x = 5. As illustrated in Figure 3, the optical band gap reduces as the redshift in the absorption edge increases, resulting in a reduction in non-bridging oxygen (NBO). As a result, the glass structure is compressed [56,57].

In addition to the refractive index of glass samples, direct and indirect transitions were investigated using Equation (3) [58,59,60,61]:

$$n=\left(\frac{1+R}{1-R}\right)+\left[\frac{4R}{{\left(1-R\right)}^2}-K^2\right]{ }^{1/2}$$

(3)

where K (=αλ/4π) is the extinction coefficient, λ is the incident photons wavelength, and α is the absorption coefficient [62,63].

Table 2 shows the refractive index values in reverse order from the optical energy band gaps data. The refractive indices results show that the proposed glass system is a good candidate for photo-electronic and optical filter devices. The following formula describing the width of band tails was used to compute the Urbach energy (E_u), defined by [8,64,65].

$$Ln\left(\alpha \right)=Ln\left({\alpha }_0\right)+h\nu /E_u$$

(4)

where (α) is the absorption coefficient, which is constant, and (E_u) is the Urbach energy.

(E_u) values have been extracted by plotting against and calculating the inverse of the slope for the curves that appear in Figure 5, giving E_u values. The values of the synthesized glass samples increased by increasing the Dy₂O₃ content, as shown in Table 2. The observed increase in Urbach’s energy in the range of 0.43–0.67 eV specifies the increase in the structural disorder of the glass samples [66].

The linear/nonlinear optical parameters were calculated; Figure 6a exhibits the studied glass samples’ refractive index variation versus the photon wavelength λ (nm). With the increasing wavelength, the refractive index decreases for all glass samples. The high refractive index below 380 nm is attributed to the effect of the main absorption. The refractive index is enhanced by increasing the Dy₂O₃ substitution in the glass system and reaches a minimum value at Dy₂O₃ content = 4 wt%. In general, this increase in the refractive index can be attributed to an increase in absorbance in the investigated samples, as given in Table 2 (1.5–1.49) and (0.89–4.13) for linear/nonlinear, respectively. The reflection increases for the fabricated glass samples due to the photons’ interaction on the samples with the filler compound ions and causing the photon to slow, and the refractive index also increases [67]. The value of the refractive index also increased with increases in the Dy₂O₃ content, owing to an increase in the atomic packing density by replacing the Dy element, which has a high relative atomic radius (162.5 pm), with a B element, which has a low relative atomic radius (84 pm). By adding the Dy₂O₃ to the glass lattice, the initial increase in the refractive is related to a change in the structural arrangements of the atoms in the glass matrix, which produces more non-bridging oxygen (NBO). NBOs are more polarizable than bridging oxygen (BO), which means increased polarizability of the glass through the increase in the NBOs produced due to Dy₂O₃ formation. Therefore, the invented samples are candidates used in photovoltaic and optical devices [6].

The extinction coefficient is distinctive and determines how strongly a form absorbs and reflects radiation or light at a certain wavelength [58]. Figure 6b shows the extinction coefficient spectra of all the glasses samples. When compared to the original glass, it can be seen that Dy₂O₃ incorporation caused increased absorption. This behavior is most likely related to the absorption spectra [68].

The nonlinear optical properties of glasses are significant and of enormous interest for photonic devices to be utilized in various technological applications with a wide spectrum of phenomena, such as optical solitons, optical frequency conversion, Raman dispersion, and phase conjugation. To understand the interaction of high-intensity light with matter, the nonlinear optical parameters, i.e., optical susceptibility χ(1), third-order optical susceptibility χ(3), and nonlinear refractive index n₂, are very important. These parameters are estimated through a linear refractive index [69,70]. The increase or decrease in the nonlinear parameter and the optical band gap Eg may refer to the formation of BO bonds and ions of higher polarizability. It is enjoyable to note that n and n₂ are usually immediately linked, such that high index (n and n₂). Therefore, materials with a lower band gap seam exhibit an increased nonlinear optical behavior (sample x = 3). In general, in multi-component oxides, BO and NBO oxygens are in the glass matrix, which affected the value of χ³. These glass materials are promising for application as components of nonlinear optical devices.

3.2. Structural, Optical, and Mechanical Properties

Photoluminescence emission spectra of the investigated glass system at the excitation wavelength (425 nm = 2.92 eV) are shown in Figure 7a, and the values of λ_emission were shown. The value of $E_g^{pl}$ (energy gap of photoluminescence) is between 2.15 and 2.23 since the emission peak is at an approximately constant wavelength value. It can show from the emission spectra of Dy0 that the prominent peak appears around (2.23 eV), and as doping by Dy₂O₃ appears, six emission bands peak at (1.46, 1.65, 1.86, 2.15, 2.40, and 2.54 eV) attributed to the transition from the (⁴F_9/2 − ⁶H_5/2, ⁴F_9/2 − ⁶H_9/2, ⁴F_9/2 − ⁶H_11/2, ⁴F_9/2 − ⁶H_13/2, ⁴F_9/2 − ⁶H_15/2 and ⁴I_13/2 − ⁶H_13/2), respectively [71,72]. A procedure for the deconvolution of the experimental spectra was required for more information and analysis of PL emission due to overlapping emission bands. All experimental curves were fitted by a superposition of several Gaussian components (R² ≥ 0.998) using the standard numeric procedure, as shown in Figure 7b–f.

Hardness Indentation and Micro-Creep Dependence of Dy₂O₃ Composition

The resistance of a material ordered to indentation by a much harder body is known as the hardness of this material. It represents a measure of the resistance against lattice destruction or the resistance to permanent deformation or damage. Information about the strength, molecular bindings, yield strength, and elastic constants of the material is impeded by the hardness of the crystal. The plasticity of the crystal could be understood by a microhardness study of the crystal. In the hardness technique, the crystal is subjected to relatively high pressure on a limited area.

Figure 8 shows the creep behavior of six glass samples containing 0, 1, 2, 3, 4, and 5 wt% Dy₂O₃ concentrations, respectively, using the Vickers hardness test. The length of indentation increases by increasing the time for each sample [73]. Figure 9 shows the relationship between Vickers hardness and indentation time [74]. The irreversible plastic deformation of the material is represented by Vickers hardness, calculated from the residual projected area. The hardness decreases with increases in time in the interval from 5 s to 100 s, which is inverse relation to the length of indentation. The average hardness numbers of Dy₀, Dy₁, Dy₂, Dy₃, Dy₄, and Dy₅ are listed in

Table 3. Hardness and stress exponent value at 5 sec and load 100 gf.

Sample	C (wt%)	HV (MPa)	S
1	x = 0	4160.54	4.2
2	x = 1	3835.40	4.1
3	x = 2	4616.06	5.5
4	x = 3	5103.68	5.9
5	x = 4	5223.20	5.6
6	x = 5	5631.58	6.3

. It is noted that average hardness values at t = 5 s rise by increasing Dy₂O₃ concentrations from 4160.54 to 5631.58 MPa. The stress exponent is computed from Equation (5) and listed in Table 2 according to [75,76]:

$$\mathrm{S}=\lfloor \partial \ln \dot{\mathrm{d}}/\partial {\mathrm{lnH}}_{\mathrm{v}}{\rfloor }_{\mathrm{d}}$$

(5)

The stress exponent studied using Equation (5) is used to define deformation mechanisms, where H_V is the number of Vickers hardness, d is the length of indentation diagonal, and $\dot{\mathrm{d}}$ is a variable rate of diagonal indentation length. The slope of a straight line obtained by plotting $\dot{\mathrm{d}}$ against H_V on the double logarithm scale is equal to the stress exponent (S), as shown in Figure 10 [77,78,79]. The stress exponent is an indication of the deformation mechanism at room temperature. The stress exponent (S) values range from 4.1 to 6.3, as shown in Table 2. Grain boundary sliding is related to n ≈ 2, and the dislocation movement, such as a creep, is related to n ≈ (5–7).

The indentation creep behavior is shown in Figure 11 by plotting strain against indentation time (indentation creep curve) of all glass samples [80]. The first stage shows a faster increase in strain with indentation time, starting from the beginning to 10 sec of indentation time [81,82,83]. The second stage indicates a slow-increasing region for all glass samples where the strain has a slow increase. No specimen breakage occurs because the hardness test is a compression test [84,85,86]. Therefore, the third stage cannot be recorded as it did in an ordinary creep test. Thus, the higher stress exponent (S) value is more resistant to the indentation creep [87,88,89].

4. Conclusions

The effects of dysprosium oxide being added to the glass system with the chemical composition (50 − x)B₂O₃ + 40Pb₃O₄ + 10CaO + xDy₂O₃, along with different substitution ratios on the structure, optical and mechanical properties, were investigated. All studied glasses were prepared using the melt-quenching technique. XRD analysis confirms the amorphous phase of the samples. Theoretical structural studies agreed with the XRD experimental data and predicted the formation of orthorhombic Pc₂₁b (29) and triclinic P-1 (2) structures for the isolated molecules. The UV–VIS spectra were also recorded to evaluate important optical properties such as direct and indirect optical band gap, Urbach energy, and refractive index. It was observed that it varied between 2.93 and 4.06 at a wavelength of 700 nm. The indirect energy gap fluctuated around 2.95 eV, and the direct value of the energy gap was decreased by increasing Dy₂O₃ to reach a maximum (3.14 eV) at x = 1.

In contrast, other essential properties such as χ³, χ¹, and n₂ enhanced with an increase in Dy₂O₃ concentration, which could be useful for optoelectronics and solar cell application. The mechanical studies showed that the hardness values increased by increasing Dy2O3 concentrations from 4160.54 to 5631.58 Mpa. The stress exponent value also increased from 4.1 to 6.3. Therefore, the higher value of stress exponent (S) is more resistant to the indentation creep.