RO135738A2 - Phosphate-telluric vitreous materials with magnetic and magneto-optical properties for faraday rotators and process for preparing them - Google Patents

Abstract

The invention relates to aluminium-phosphate-telluric glass with lithium oxide and titanium dioxide and zinc oxide content, respectively, and to a process for preparing them, said glass having magnetic and magneto-optical properties and being meant to be used as Faraday rotators. According to the invention, the glass has the following compositions, the percentage being expressed by weight: 1. the first two types of glass have 62...63.92% grav. P2O5, 2.22...8.73% grav. Li2O, 9.06...9.90% grav. Al2O3, 3.55...3.88% grav. TiO2 and 15.49...21.25% grav. TeO2; 2. the third type of glass has 47.62% grav. P2O3, 8.55% grav. Al2O3, 23.77% grav. ZnO and 20.07% grav. TeO2, the glass having an optical transmission ranging between 2.57...5.38% at 600 nm and between 41.5...82.4% at 1700 nm, and the refractive indices nF=1.59553...1.61519, ne=1.58852...1.60877, nD=1.58533...1.60561, nC=1.58029...1.60174, the optical dispersion ranging between 0.01345...0.11524, the Abbe number ranging between 38.40...45.02, the glasses having the Faraday rotation angle ranging between 0.09822°...0.11554° and the Verdet constant between 0.01572...0.01718 min/(Oe.cm) at a wavelength of 633 nm. According to the invention, the process consists in introducing the solid reactants, as powder, into the solution of H3SO4, mechanically homogenizing the resulting hot evaporated mixture, followed by thermal treatments of drying and pre-melting treatment, thermally treating the mixture at the melting and refining temperature, after which the resulting glass is shaped by pouring into preheated moulds then it is annealed and optically processed, the temperature being increased at a constant rate until reaching the melting temperature when a constant temperature plateau is maintained, the mechanical homogenization of the melt is applied at a constant stirring rate, the temperature is constantly lowered down to the casting temperature and the mechanical homogenization rate is lowered as well, after which the melt is poured into a preheated mould at the annealing temperature of 400°C.

Description

DESCRIPTION OF THE INVENTION

The invention relates to products of the type of alumino-phosphate-telluritic bottles containing lithium oxide and titanium dioxide and, respectively, zinc oxide, used as Faraday rotators and to the method of obtaining them. in order to prepare these bottles, raw materials such as acid oxides and salts are used. They introduce phosphorus pentaoxide and tellurium dioxide as network formers, and lithium, aluminum, zinc and titanium oxides as network modifiers. The reactants are introduced in the amounts corresponding to the preset compositions, adding an additional amount in the case of lithium oxide and phosphorus pentaoxide, taking into account their evaporation, in the proportion of 15% and 25%, respectively. The process of preparing phosphatotelluritic glasses in solution containing lithium, aluminum, zinc and titanium oxides consists of introducing solid reactants into the phosphoric acid solution, in order to carry out chemical reactions and evaporating the mixture by heating, applying mechanical homogenization. This process of wet processing of the reactants ensures a high chemical homogeneity of the reaction products, which are precursors of the final chemical products in glass. The homogenized and evaporated mixture is thermally treated in order to eliminate the gaseous components, then it is melted in order to form the vitreous structure. The melting of the mixture of chemical compounds is accompanied by mechanical homogenization in order to eliminate gaseous inclusions and achieve a high chemical and optical homogeneity of the bottles obtained in the end. The melted and homogenized bottles are cooled (shaped) by pouring into preheated molds, then, they are heat-treated (annealed) in order to eliminate the mechanical stresses that occur in the molding process. Vitreous materials are optically processed for physico-chemical characterization and their use as Faraday rotators, having magnetic and magneto-optical properties.

The current situation worldwide

Crystalline and glassy materials with magnetic and magneto-optical properties are of particular importance due to their potential applicability in high-precision laser measurements, display systems, etc. [1, 2]. Faraday isolators or rotators are devices used in optical communication systems to block reflected laser beams, thus avoiding damage to optical emission systems and to eliminate parasitic oscillations in amplification systems or certain frequency instabilities in laser diodes [2] . Crystalline and vitreous materials with magnetic and magneto-optical properties are part of Faraday insulators, determining their performance [3]. This use implies the choice of crystalline or glassy materials with significant Faraday effects and low absorption in the visible and near-infrared ranges [4]. Crystalline materials such as iron and yttrium garnet, YsFesO^ and gallium and terbium garnet, TbaGasOu, have magneto-optical properties, intensively used due to their high infrared transmission, low saturation magnetization and high value of the Faraday rotation angle [5,6], Crystalline and vitreous phosphatic materials, having magneto-optical properties, are of particular interest in the realization of Faraday rotators. Thus, eulite-type terbium and barium phosphate, Ba3Tb(PO4)3, obtained by solid phase reaction, followed by slow cooling, melting and single crystal growth by the Czochralski technique, presents remarkable magneto-optical properties [7]. Relatively recently, crystalline nanoparticles dispersed in glassy structures, having magneto-optical properties, are active media used in devices such as current sensors based on optical fibers [7], optical insulators [8], magneto-optical current transformers [ 9], optical modulators [10] and high sensitivity magnetic field detectors [11]. Thus, vitreous phosphatic materials containing Fe2O3 nanoparticles and exhibiting a paramagnetic behavior are being investigated [12, 13]. in the case of glasses of composition 60P2O5-15LÎ2O-8ZnO-3B2O33.5Ga2O3-10.5K2O, the Verdet constant shows high values for 0.22,1 and 2 % m61. Fe2O3

[12]. in the case of the glass of molar composition 6OP2O5-i5Li2O-8ZnO-3B2O3-3.5Bi2O3-lO.5K2OlFe2O3, a high value of the Verdet constant is found compared to glasses containing smaller or larger amounts of Fe2O3, in the range of 0-2 % mol. [13].

Very recently, a phosphate glass with magnetic properties belonging to the Na2O-CaO-P2O5 system was reported, obtained by the coacervation method, in which Co and Pt nanoparticles, coated with S1O2, were introduced to increase the chemical stability of these nanostructures [14 ], The same vitreous oxide system obtained by the same coacervation method was investigated in order to introduce Fe2O3 nanoparticles coated with S1O2 [15]. The glassy material thus obtained has a ferromagnetic behavior at 5 K and a superparamagnetic behavior at 300 K. The formation of Si-OP bonds leads to an increase in the chemical stability of the glass. The influence of Fe3O4 nanoparticles on the magnetic properties in the P2O5-ZnO-Er2O3-Fe3O4 system was studied, finding a ferrimagnetic behavior for a maximum concentration of 2 mol %. Fe3O4. An energy transfer process from Er ³⁺ ions to Fe3O4 nanoparticles is observed, which leads to a decrease in the emission intensity of Er ³ * ions. The presence of ferrites in the glass structure is a prerequisite for improving the magneto-optical properties of these glasses [16]. The influence of NiO nanoparticles on the emission and magnetic properties of glasses from the ZnO-P2O5-Sm2O3-NiO system was also investigated [17]. An energy transfer process from the Sm ³⁺ ions to the NiO nanoparticles is observed, which leads to a decrease in the emission intensity of the Sm ^{3+ ions} . A paramagnetic behavior of these vitreous materials is found, with applications in the field of magneto-optics.

Phosphate glasses containing PbO and B12O3 are recently being investigated for diamagnetic behavior and important Faraday rotation. Thus, the borophosphate glass belonging to the system 45PbO-45BÎ2O3-5B2O3-5P2O5 shows a diamagnetic behavior, a Faraday rotation and increased Vickers hardness compared to the glass without P2O5 [18]. The Verdet constant is close to that of diamagnetic telluritic glasses [19]. It was found that in the case of vitreous materials belonging to the PbO-Bi2O3-B2O3 system, the addition of aluminum metaphosphate, A1(PO3)3 leads to the expansion of the vitreous network, the decrease in density and the increase in the refractive index. Maximum values of the Verdet constant and the figure of merit (the ratio between the Verdet constant and the absorption coefficient) are found for the glass containing 5 mol %. A1(PO ₃ ) ₃ [20]. Li, Ba and Al metaphosphate glasses have recently been studied in terms of the influence of B12O3 and PbO additions on the value of the Verdet constant. Thus, bottles containing both B12O3 and PbO show higher values of the Verdet constant compared to bottles containing only one of the mentioned oxides [21]. Also, aluminoborophosphate glasses containing ZnO, in addition to PbO and B12O3, were investigated in terms of mechanical and magneto-optical properties [22], It was found that the modulus of elasticity and hardness increase by introducing B2O3 and the Faraday rotation angle values and of the Verdet constant are close to those of commercial glasses with magneto-optical properties. The introduction of Ag and ZrO2 nanoparticles into the composition of a glass belonging to the oxide system PbO-BÎ2O3-B2O3 led to an increase in the spin plasmon resonance effect, hardness, nonlinear refractive index and Verdet constant [23]. The best results or obtained for 3% serious. Ag-ZrO2 which recommends these glassy materials for applications in nonlinear optics, photonics and magneto-optics.

The introduction of NiO in the composition of phosphate glasses leads to a significant increase in the Verdet constant. Thus, the glasses that belong to the system 60P2O5-15LÎ2O-8ZnO-3B2O33.5B12O3-I0.5K2O and contain NiO between 0-2% mol., have a diamagnetic character and a Verdet constant close to that of diamagnetic telluritic glasses, being approx. 18 times higher than that of glass without NiO [24].

A category of glasses with magneto-optical properties are those that contain rare earth ions (Ce ³⁺ , Tb ³⁺ , Dy ³⁺ , Er ³⁺ , Sm ³⁺ ) and that exhibit paramagnetic behavior. Thus, the glasses belonging to the oxide system P2O5-La2O3-Ce2O3 show high transmission in

range 1000-2500 nm and values of the Verdet constant close to those of traditional glasses for a maximum of 25 mol %. Ce2O3 [25]. Vitreous materials belonging to the system / TbîCh-LaiCh-PiOs containing Tb2O3 up to a maximum of 35% by weight, show high transmission up to 1500 nm and values of the Verdet constant, in the visible range, close to those of commercial glasses for Faraday rotators [26] . Glasses belonging to the oxide system LÎ2OA12O3-BaO-P2O5-Dy2O3 are investigated in terms of magnetic and magneto-optical properties [27]. A paramagnetic behavior and a Verdet constant in the visible range close to that of commercial diamagnetic glasses are found.

Telluritic glass materials are of particular importance in terms of their applications, namely, Faraday rotators, magnetic field transducers, magnetic field detectors, etc. Thus, the realization of a diamagnetic telluritic glass, with magneto-optical properties, in the form of optical fibers, for magnetic field sensors is reported. The glass that constitutes the core of the fiber belongs to the oxide system TeO2-PbO-B2O3, and the glass that makes up the shell of the fiber belongs to the oxide system TeO2-PbO-B2O3-SiO2 [28]. The values of the Verdet constant in the visible range and the figure of merit recommend the use of these glass fibers for magneto-optical devices. Relatively recently, the synthesis of telluritic glasses belonging to the oxide systems TeO2-ZnO, TeO2-ZnO-Na2O and TeO2-ZnO-La2O3-Na2O was presented. The synthesis took place in a sealed chamber of silicate glass and in a stream of oxygen [29], The variation of the Verdet constant was measured in the range 450-1560 nm, indicating the use of these glasses for Faraday rotators at the wavelength of 1070 nm . Very recently, two scientific papers were published regarding the magnetic and magneto-optical properties of some phosphato-telluritic diamagnetic glasses, belonging to the compositional systems 45ZnO-10A12O340P ₂ O ₅ -5TeO2 [30] and 35Li ₂ O 10A12O3-5TiO ₂ -45P2O ₅ -5TeO2 [31].

An interesting category of telluritic glasses with magneto-optical properties are those containing nanoparticles of oxides or transition/post-transition elements that give these glassy materials a paramagnetic behavior. Thus, a glass belonging to the TeO2-ZnO-Fe3O4 system characterized by increased chemical stability and significant magnetization at a concentration of 2 mol % is reported. Fe3O4 [30]. Very recently, a glass belonging to the oxide system TeO2-PbO-B2O3, doped with Bi1.9Mno.1Te3 nanocrystals, is presented for the first time [33]. These nanocrystals confer chemical stability, diamagnetic behavior and high Verdet constant comparable to that of commercial glasses being usable for Faraday rotators and magnetic field sensors. The glasses belonging to the B2O3-TeO2-PbO system were doped with Bi nanoparticles, showing diamagnetic behavior, increased chemical stability, optical transmission in the visible range and Verdet constant close to that of commercial glasses [34]. Vitreous materials belonging to the oxide system TeO2-PbO-B2O3 are doped with nanoparticles of Fe3O4 and M0S2 [35]. It was found that in the case of an optimal concentration of 2 % grave. Fe3O4-MoS2 having superparamagnetic behavior, high thermal stability and increased Verdet constant are obtained due to spin-orbit coupling and high spin polarizability of Fe3O4 particles, diamagnetism of Mo ⁶⁺ ions and small band gap value of these nanoparticles . The introduction of Fe3O4 nanoparticles into the composition of two glasses belonging to the oxide systems TeO2-PbOB2O3 and PbO-BÎ2O3-B2O3, by the sputtering method in magnetron plasma, was reported [36]. in the case of a 1-5 pm thick Fe3O4 film, deposited by the sputtering method in the magnetron plasma, a remarkable thermal stability and magneto-optical properties are obtained for both glassy oxide systems.

Important magnetic and magneto-optical properties have been presented in papers dealing with telluritic glasses doped with rare earth ions. Thus, the introduction of CO3O4 nanoparticles, having the size of approx. 6 nm, in glasses belonging to the oxide system B2O3~TeO2-MgO-Na2O-Er2O3, leads to the intensification of the paramagnetic behavior due to Co ²⁺ and Er ³ * ions, with applications in the field of lasers with

of magneto-optical devices [37]. Also, the introduction of Mn nanoparticles, having the size of approx. 11 nm in the composition of glassy materials belonging to the EhCh-TeCh-MgO-EusCh system, leads to an intensification of the emission in the visible range due to the energy transfer between Mn nanoparticles and Er ³ * ions [38].

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General description of the invention

The phosphate-telluritic glasses belonging to the compositional systems 30L12O-I0AI2O35TiO2-45P ₂ O ₅ -10TeO2 (Te-1), 25Li2O-10A12O ₃ -5TiO2-45P2O ₅ -15TeO2 (Te-2) and 35ZnO10A1203-40P205-15Te02 (Te-3 ) were synthesized by an unconventional method of wet processing of the reactant mixture, followed by melting, casting and annealing in order to eliminate residual mechanical stresses. The chemical reagents of analytical purity were the following: L12CO3, AI2O3, ZnO, T1O2, TeO2 and H3PO4 (concentration solution 85%). The mixture of reactants is introduced into the H3PO4 solution, achieving a continuous mechanical homogenization that is also applied in the melting stage of the mixture of chemical compounds. The quantities of reactants are set so that metaphosphate-type chemical compounds are formed in the final glassy product, i.e. polymer structures made up of chains of phosphate tetrahedra (PO4) ³ ·, joined by bridges of oxygen atoms. Oxygen atoms that do not form bridges (O' ions, non-bridged) bind to the modifier ions of the vitreous network (lithium, aluminum). Zn ²⁺ , Ti ⁴⁺ and Te ⁴⁺ ions can enter the composition of the phosphate chains forming PO-Zn, PO-Ti and PO-Te bridges, increasing the chemical stability of these glassy materials.

Examples of application of the invention:

Example 1

The initial composition of the alumino-phosphate-telluritic glass containing L12O and T1O2 corresponds to the following molar formula: 30LÎ20-10A1203-5Ti02-45P205-10Te02 (Te-1).

Taking into account the fact that P2O5 volatilizes in percentages of about 25% and L12O in percentages of about 15%, a supplement of phosphoric acid and L12CO3, respectively, is introduced to compensate for the respective losses. Table 1 shows the quantities of raw materials used for the preparation of approx. 50 g of alumino-phosphate-telluritic glass containing L12O and T1O2 (Te-1).

Table 1. Quantities of raw materials used to obtain approx. 50 g glass alumino-phosphate-telluritic glass containing L12O and T1O2 (Te-1).

Raw material Quantity (g) / (ml) Li ₂ CO ₃ 13 g Al2O3 5g _TiO2 2g

_TeO2 8g H3PO4 38 ml

The nominal oxide composition (wt.%) of the alumino-phosphate-telluritic glass containing L12O and TiCh (Te-1) is as follows: 8.73LÎ20-9.90A1203-3.88Ti02-62.00P205-15.49Te02.

The nominal oxide composition corresponds to the initial reagent mixture that is processed to obtain an alumino-phosphate-telluritic glass containing L12O and T1O2 (Te-1). The composition is calculated taking into account the molar formula and the chemical reactants used to synthesize a glassy material with a metaphosphate oxide network.

The obtaining method includes the following steps:

(i) homogenization and evaporation of water from the raw material (in a quartz crucible, with a magnetic stirrer, on an electric hotplate, at a temperature of 180 °C, 60 min);

(ii) drying at 190 °C for 2 hours and at 240 °C for 2 hours in an electric oven;

(iii) thermal treatment prior to melting, at 700 °C, 3 hours;

(iv) melting and refining at 1200 °C, 30 min, in an electric furnace with superkanthal (M0S12) heating elements;

(v) cooling (shaping) the glass by casting at a temperature of 1150 °C, in preheated pure graphite molds;

(vi) elimination of residual mechanical stresses in the glass (annealing) by heat treatment in electric furnaces equipped with heating elements made of kanthal (Fe-Cr-Al alloy);

(vii) annealing stages: level 400 °C, 30 min; temperature drop: 400-350 °C at a rate of 5 °C/h; temperature drop: 350-300 °C at a rate of 10 °C/h; temperature drop: 30020 °C, with the rate of 20 °C/h.

The main reactions that take place during melting are the following:

L12CO3 + 2H3PO4 -> 2LiPO ₃ + 3H ₂ O+ CO2(1)

AI2O3 + 6H3PO4 -> 2A1(PO ₃ ) ₃ + 9H ₂ O(2)

TiO ₂ + 4H3PO4 -> Ti(PO ₃ ) ₄ + 6H ₂ O(3)

TeO ₂ + 4H3PO4 -> Te(PO ₃ ) ₄ + 6H ₂ O(4)

The wet method of processing the reactants has the advantage of a good homogenization of the mixture of chemical reagents and allows the formation of metaphosphate compounds even at the stage of pre-ripening treatment. This process reduces melting and refining time and gives the obtained glasses a high chemical and optical homogeneity.

The ceramic crucible together with the mixture of pre-treated material is placed in the furnace where the melting-forming-conditioning-refining process of the alumino-phosphatotelluritic glass containing L12O and T1O2 (Te-1) takes place. The oven has the following technical characteristics:

> maximum working temperature: 1400 °C/1600 °C;

> heating elements with silite (SiC) or superkanthal (M0S12) electrical resistances;

> dimensions of 400 x 300 x 200 mm;

> automatic temperature control system.

The obtained glass is transparent, dark brown, chemically and mechanically stable.

Example 2

The initial composition of the alumino-phosphate-telluritic glass containing L12O, T1O2 and increased concentration of TeCh, corresponds to the following molar formula; 25LÎ2O-10A12O3-5TÎO245P ₂ O ₅ -15TeO2 (Te-2).

Taking into account the fact that P2O5 volatilizes in percentages of about 25% and L12O in percentages of about 15%, a supplement of phosphoric acid and L12CO3, respectively, is introduced to compensate for the respective losses. Table 2 shows the quantities of raw materials used for the preparation of approx. 56 g of alumino-phosphate-telluritic glass containing L12O, T1O2 and increased concentration of TeO2 (Te-2).

Table 2. Quantities of raw materials used to obtain approx. 56 g of alumino-phosphate-telluritic glass containing L12O, T1O2 and increased concentration of TeO2 (Te-2).

Raw material Quantity (g) / (ml) L12CO3 11 g Al2O3 5g _TiO2 2g _TeO2 12 g H3PO4 38 ml

The nominal oxide composition (wt%) of alumino-phosphate-telluritic glass containing L12O, T1O2 and increased concentration of TeO2 (Te-2) is as follows: 2.22LÎ2O-9.06A12O33.55TiO2-63.92P ₂ O ₅ -21 ,25TeO2.

The nominal oxide composition corresponds to the initial reagent mixture that is processed to obtain an alumino-phosphate-telluritic glass containing L12O, T1O2 and increased concentration of TeO2 (Te-2). The composition is calculated taking into account the molar formula and the chemical reactants used, to synthesize a vitreous material with a metaphosphate oxide network.

The stages of the production method, the chemical reactions that take place in the process of obtaining alumino-phosphate-telluritic glass containing L12O, T1O2 and increased concentration of TeO2 (Te-2) as well as the advantages presented by the method of obtaining these vitreous materials are identical to those shown in example 1.

The ceramic crucible together with the mixture of pre-treated material is introduced into the furnace where the process of melting-forming-conditioning-tempering of the alumino-phosphatotelluritic glass containing L12O, T1O2 and increased concentration of TeO2 (Te-2) takes place.

The melting furnace has the same technical characteristics as those presented in example 1.

The obtained glass is transparent, dark brown, chemically and mechanically stable.

Example 3

The initial composition of the alumino-phosphate-telluritic glass containing ZnO corresponds to the following molar formula: 35ΖηΟ-10Α12θ3-40Ρ2θ5-15Τεθ2 (Te-3).

Taking into account the fact that P2O5 volatilizes in percentages of about 25% and L12O in percentages of about 15%, a supplement of phosphoric acid and L12CO3, respectively, is introduced to compensate for the respective losses. Table 3 shows the quantities of raw materials used for the preparation of approx. 60 g of alumino-phosphate-telluritic glass containing ZnO (Te-3).

Table 3. Quantities of raw materials used to obtain approx. 60 g of alumino-phosphate-telluritic glass containing ZnO (Te-3).

_TeO2 12g H3PO4 34 ml

The nominal oxide composition (wt%) of the alumino-phosphate-telluritic glass containing ZnO (Te-3) is as follows: 23.77ZnO-8.55AhO3-47.62P2O5-20.07TeO2.

The nominal oxide composition corresponds to the initial reagent mixture that is processed to obtain an alumino-phosphate-telluritic glass containing ZnO (Te-3). The composition is calculated taking into account the molar formula and the chemical reactants used, to synthesize a vitreous material with a metaphosphate oxide network.

The obtaining method includes the following steps:

(i) homogenization and evaporation of water from the raw material (in a quartz crucible, with a magnetic stirrer, on an electric hotplate, heated to 180 °C, 40 min);

(ii) drying at 240 °C, 60 min, in an electric oven;

(iii) thermal treatment prior to melting, 850 °C, 3 hours;

(iv) melting and refining at 1150 °C, 30 min, in an electric furnace with superkanthal (M0S12) heating elements;

(v) cooling (shaping) the glass by casting at a temperature of 1100 °C, in preheated pure graphite molds;

(vi) elimination of residual mechanical stresses in the glass (annealing) by heat treatment in electric furnaces equipped with heating elements made of kanthal (Fe-Cr-Al alloy);

(vii) the annealing steps are identical to those shown in example 1.

The main reactions that take place during melting are (2), (4) and:

ZnO + 2H3PO4 -+ Zn(PO ₃ ) ₂ + 3H ₂ O (5)

The advantages presented by the method of obtaining the alumino-phosphate-telluritic glass containing ZnO (Te-3) are identical to those presented in example 1.

The ceramic crucible together with the mixture of pre-treated material is introduced into the furnace where the melting-forming-conditioning-refining process of the alumino-phosphatotelluritic glass containing ZnO (Te-3) takes place.

The melting furnace has the same technical characteristics as those presented in example 1.

The obtained glass is transparent, reddish purple, chemically and mechanically stable.

To improve the chemical and optical homogeneity of the synthesized glasses, mechanical homogenization of the vitrogenic melt was applied. Research was carried out to determine the type of drive device and stirrer required for homogenization in a superluminous ceramic crucible with a capacity of 50 ml. Thus, a ceramic stirrer, made of sintered alumina, operated by an electric motor, shown in Fig.l, was used.

The rotational speed of the stirrer was designed to vary between 100 and 500 rpm, depending on the viscosity of the melt. Tables 4 and 5 show the mechanical homogenization schedule of alumino-phosphate-telluritic glass melts containing Li2O, T1O2 and different concentrations of TeO2 and alumino-phosphate-telluritic glass containing ZnO, respectively.

Table 4. Mechanical homogenization program applied to alumino-phosphatotelluritic glasses containing L12O, T1O2 and different concentrations of TeO2 (Te-1 and Te-2)

Time [h] Temperature [°C] Rotation speed [rpm] Remarks 0.5 1200 250 Tempering temperature

0.2 1200-1150 100 Temperature drop to 1150 °C 0 1150 Stop mechanical homogenization Cooling of glass by casting and shaping

Table 5. Mechanical homogenization program applied to alumino-phosphate-telluritic glass containing ZnO (Te-3)

Time W Temperature [°C] Rotation speed [rpm] Remarks 0.5 1150 250 Tempering temperature 0.2 1150-1100 100 Temperature drop to 1150 °C 0 1100 Stop mechanical homogenization Cooling of glass by casting and shaping

Annealing of the glass samples was performed in a kanthal (Fe-Cr-Al alloy) electric resistance furnace. The technical characteristics of the oven are:

> maximum working temperature: 1100 °C;

> heating elements: electrical resistances from kanthal;

> dimensions: 300 x 250 x 150 mm;

> automatic temperature control system.

Annealing programs have been designed to avoid glass crystallization and optimize energy consumption. At the same time, in order to obtain glass samples with good mechanical resistance, it was aimed to reduce the residual stresses within satisfactory limits and avoid the risk of cracking or breaking during the grinding and polishing process.

The optical transmission of alumino-phosphate-telluritic glasses containing L12O, T1O2, and ZnO, respectively, at wavelengths of 600 and 1700 nm is shown in Table 6.

Table 6. Optical transmission of alumino-phosphate-telluritic glasses containing LiiO, T1O2 and ZnO, respectively, measured at 600 nm and 1700 nm

Glass code Optical transmission (%) 600 nm 1700 nm Te-1 5.38 41.5 Te-2 2.57 82.4 I-3 3.38 88.37

Table 7 shows the refractive indices: uf (486 nm), ne (546 nm), no (589 nm), nc (656 nm), the optical dispersion uf - nc and the Abbe number, u _e = (no - 1) / (nF - nc), belonging to the alumino-phosphate-telluritic glasses containing L12O, T1O2 and different concentrations of TeO2 and the alumino-phosphate-telluritic glass containing ZnO, respectively.

Table 7. The values of refractive index at different wavelengths, optical dispersion and Abbe number of alumino-phosphate-telluritic glasses containing L12O, T1O2 and different concentrations of TeO2 and of alumino-phosphate-telluritic glass containing ZnO.

Glass code No. us no nc np- nc eu Te-1 1.59553 1.58852 1.58533 1.58029 0.01524 38,40 Te-2 1.61519 1.60877 1.60561 1.60174 0.01345 45.02 Te-2 1.60380 1.59791 1.59452 1.59113 0.01267 46.92

Table 8 shows the values of the Faraday rotation angle, Of and of the Verdet constant, V, measured at the reference wavelengths, 400 nm and 633 nm.

Table 8. Faraday rotation angle, Of, and Verdet constant, V, measured at reference wavelengths, 400 nm and 633 nm.

Glass code Faraday rotation angle, Of (°) Constanta Verdet, V (min/(Oe cm) 400 nm 633 nm 400 nm 633 nm Te-1 - 0.09822 - 0.01572 Te-2 - 0.11554 - 0.01718 I-3 0.39439 0.13511 0.05798 0.01994

in the case of bottles code Te-1 and Te-2, due to very large variations in the values of the Faraday rotation angle and the Verdet constant around the wavelength of 400 nm, an exact assessment of these parameters was not possible.

Claims (13)

1. Alumino-phosphate-telluritic glasses (Te-1 and Te-2) characterized by the fact that they have a P2O5 content between 62...63.92 % by weight, Li ₂ O between 2.22...8.73 wt %, AI2O3 between 9.06...9.90 wt %, TiO ₂ between 3.55...3.88 wt %, and TeO2 between 15.49...21.25 wt %. 2. Alumino-phosphate-telluritic glass (Te-3) characterized in that it has a P2O5 content of 47.62% by weight, AI2O3 8.55% by weight, ZnO 23.77% by weight, and TeO ₂ 20, 07% serious. 3. Alumino-phosphate-telluritic glasses according to claim 1, characterized in that they have optical transmittance between 2.57%...5.38% at 600 nm and between 41.5%...82.4% at 1700 nm. 4. Alumino-phosphate-telluritic bottles according to claim 1, characterized in that they have refractive indices: no between 1.59553...1.61519, not between 1.58852...1.60877, no between 1.58533...1.60561, nc between 1.58029...1.60174, optical dispersion between 0.01345...0.01524 and Abbe number between 38.40...45.02. 5. Alumino-phosphate-telluritic bottles according to claim 1, characterized in that they have the Faraday rotation angle between 0.09822 °...0.l 1554 ⁰ at the wavelength of 633 nm and the Verdet constant between 0.01572 min/(0e cm)... 0.01718 min/(0e cm) at 633 nm wavelength. 6. Alumino-phosphate-telluritic glass according to claim 2, characterized in that it has an optical transmission of 3.38% at 600 nm and 88.37% at 1700 nm. 7. Alumino-phosphate-telluritic glass according to claim 2, characterized in that it has refractive indices: np of 1.60380, n _e of 1.59791, no of 1.59452, nc of 1.59113, optical dispersion of 0 .01267 and Abbe number of 46.92. 8. Alumino-phosphate-telluritic glass according to claim 2, characterized in that it has the Faraday rotation angle of 0.39439 ⁰ at the wavelength of 400 nm and 0.13511 ⁰ at 633 nm. 9. Alumino-phosphate-telluritic glass according to claim 2, characterized in that it has a Verdet constant of 0.05798 min/(0e cm) at the wavelength of 400 nm and 0.13511 min/(0e cm) at 633 nm. 10. Process for obtaining some alumino-phosphate-telluritic glasses according to claims 1 and 2 (Te-1, Te-2 Te-3) by which the solid reactants in the form of powders are introduced into the H3PO4 solution, the resulting mixture is mechanically homogenized and hot evaporated, then it undergoes a drying heat treatment and a pre-melting heat treatment, after which it is heat treated at the melting and refining temperature, the obtained glass is shaped by pouring into preheated molds, then annealed and optically processed, characterized in that the temperature is raised at a constant rate to the melting temperature, a plateau is maintained at the melting temperature, mechanical homogenization of the melt is applied with a constant mixing rate, the temperature is lowered at a certain rate to the melting temperature casting and the speed of mechanical homogenization is lowered, after which the melt is poured into a preheated mold at the annealing temperature of 400 °C. 11. Process for obtaining alumino-phosphate-telluritic glasses according to claim 1 and 10 (Te-1 and Te-2), characterized in that the homogenization and evaporation of the reactant mixture take place at a temperature of 180 °C, for 60 min, drying takes place at 190 °C for 2 hours and at 240 °C for 2 hours, then pre-melting treatment at 700 °C for 3 hours, followed by melting and tempering at the temperature of 1200 °C for 30 min, after which the temperature is lowered to 1150 °C when the melt is poured into preheated molds at the annealing temperature of 400 °C. of 12. Process for obtaining an alumino-phosphate-telluritic glass according to claim 2 and 10 (Te-3), characterized in that the homogenization and evaporation of the reactant mixture take place at a temperature of 180 °C, for 40 min, drying has place at a temperature of 240 °C for 60 min, then pre-melting treatment at a temperature of 850 °C for 3 hours, followed by melting and tempering at a temperature of 1150 °C for 30 min, after which it is lowered temperature at 1100 °C when the melt is poured into molds preheated to the annealing temperature of 400 °C. 13. Process for obtaining alumino-phosphate-telluritic glasses according to claim 1,2, 10,11 and 12 (Te-1, Te-2 and Te-3), characterized in that the annealing takes place as follows: level at the temperature of 400 °C for 30 min, then decreasing the temperature to 350 °C at the rate of 5 C/h, followed by decreasing the temperature to 300 °C at the rate of 10 C/h, then decreasing the temperature to 20° C at the rate of 20 C/h.