Cathodoluminescent and photoluminescent glasses

BACKGROUND OF THE INVENTION
Europium can exist in two oxidation states when present in glass. The more common trivalent state, Eu.sup.+3, emits a moderately strong reddish photoluminescence, i.e., upon exposure to ultraviolet radiation, particularly where europium is included in high concentrations; but its cathodoluminescence, i.e., its emission when subjected to cathode rays, is quite weak. The divalent state, Eu.sup.+2, can emit a strong bluish luminescence under both forms of excitation, viz., ultraviolet and cathode rays. However, in many conventionally melted, high temperature glasses a mixture of the two valence states will exist such that the luminescence color exhibited under ultraviolet or cathode ray excitation is the result of contributions from both valence states. Hence, luminescence colors can range from violet or violet-blue at low europium concentrations, thereby indicating a predominance of Eu.sup.+2 emission, to deep pink or red at high europium concentrations, thereby evidencing a predominance of Eu.sup.+3 emission. However, the cathodoluminescent efficiency of such glasses is, in the main, very poor. It has been postulated that the presence of the relatively inefficient Eu.sup.+3 ions degrades the efficiency of the Eu.sup.+2 ions which are present in the glass. Enhancement of the Eu.sup.+2 ion concentration in the glass has been attempted via melting the glass batch under reducing conditions, but such trials have not been uniformly satisfactory and, furthermore, the procedures required are cumbersome and not readily adaptable to commercial glass melting operations.
It has long been recognized that crystals commonly luminesce with much higher efficiencies than do glasses of like composition. Nevertheless, the transparency and freedom from light-scattering defects intrinsically present in glass articles have stimulated continued research to develop glass compositions which will luminesce brilliantly when subjected to a beam of high voltage electrons. Such glasses would be particularly suitable for the formation of transparent faceplates or screens for cathode ray tubes or other applications where image contrast or image resolution is of vital importance.
Unfortunately, with few exceptions, this research has not been rewarding in that the glasses developed have generally demonstrated poor cathodoluminescence efficiency. For example, the large majority of the glasses produced exhibited efficiencies of less than about 1%. Therefore, a cathodoluminescence efficiency of 1% has been deemed a baseline for certifying an improved glass.
OBJECTIVE OF THE INVENTION
The primary objective of the instant invention is to provide a transparent, crystal-free glass which will display a strong bluish luminescence when impinged by ultraviolet or cathode rays and which will exhibit a cathodoluminescence efficiency of at least 1%.
SUMMARY OF THE INVENTION
That objective can be achieved in glass articles which consist essentially, in terms of mole percent on the oxide basis, of about 15-30% Al.sub.2 O.sub.3 and 45-70% SiO.sub.2, the sum of those two components constituting at least 75 mole percent, but no more than 95 mole percent, of the total composition, and at least 0.025% europium, expressed as Eu.sub.2 O.sub.3. The remainder of the composition will consist of other compatible metal oxides which can improve the melting and forming characteristics of the glass and/or modify the physical properties thereof. Such would include well-recognized network formers such as B.sub.2 O.sub.3 and P.sub.2 O.sub.5 and network modifiers such as the alkali metals, divalent metal oxides and, in particular, the alkaline earth metals, and trivalent metal oxides, with Y.sub.2 O.sub.3 and La.sub.2 O.sub.3 being especially useful. Such additions will be included in an amount of at least about 3 mole percent. The method of the invention comprehends three general steps. First, a batch of the proper composition is melted and simultaneously cooled and a glass article of a desired geometry shaped therefrom. Second, the glass article is exposed to a reducing environment at an elevated temperature below the softening point of the glass for a period of time sufficient to produce at least a surface layer on the glass article wherein the europium is present as Eu.sup.+2 ions. Third, the glass article is cooled to room temperature.
The temperature of firing in the reducing environment is dependent upon the composition of the glass. For example, with soft glasses, commonly containing monovalent ions such as the alkali metal ions, temperatures in the vicinity of 600.degree. C. will be operable. In contrast, with harder glasses containing divalent and/or trivalent metal oxides, the firing will be conducted at a temperature in excess of 775.degree. C., but less than about 950.degree. L C., with the preferred temperatures ranging between about 800.degree.-900.degree. C. Hence, incomplete conversion to Eu.sup.+2 is encountered at temperatures below about 775.degree. C., whereas some degree of deformation or softening of the glass is commonly experienced at temperatures above about 950.degree. C. In all cases, the maximum firing temperature will be held below the softening point of the particular glass.
The time required for the firing step is temperature dependent and the progress of the reaction generally follows the law of diffusion, i.e., where the temperature is maintained constant, the rate of penetration, or the distance within the glass wherein the europium is reduced to Eu.sup.+2 ions, is proportional to the square root of time. In general, a firing time of at least about two hours will be required, with 4-16 hours being commonly employed.
Various gaseous reducing atmospheres are effective. For example, mixtures of carbon dioxide and carbon monoxide can be operable as can an atmosphere of hydrogen. A preferred embodiment employs forming gas, a gaseous mixture consisting of 92 volume percent N.sub.2 and 8 volume percent H.sub.2. This combination of gases is relatively inexpensive and avoids the hazards of the hydrogen atmosphere.
DISCUSSION OF THE PRIOR ART
U.S. Pat. No. 2,049,765 discloses alkali metal borosilicate glasses containing a number of sensitizing agents in particulate form which will luminesce when subjected to ultraviolet or cathode rays. More specifically, the patent describes a colloidally-dispersed, crystalline structure in a glass matrix -- hence, an article having the structure of a two-phase system. Europium compounds were alleged to be suitable as sensitizing agents but no exemplary composition of such was provided. Furthermore, there is no disclosure whatever regarding the firing of the glassy-crystalline articles in a reducing environment.
U.S. Pat. No. 3,374,381 describes the fabrication of multi-color photoluminescent glass systems wherein a structure is made up of individual glass elements. These glass elements preferably have the same base components, such that the separate members can be joined together relatively easily, but will be doped with different photoluminescent agents. Hence, when subjected to long wavelength ultraviolet radiation, the different glass elements would luminesce in various colors. The patent mentions the development of glass compositions which will exhibit a bluish photoluminescence and three exemplary compositions are provided, two employing copper and a single example utilizing europium. However, there is no teaching whatever in the patent regarding the firing of glasses in a reducing environment and the sole europium-containing example involved a base glass composition consisting, in mole percent, of 29.8% MgO, 10.6% Al.sub.2 O.sub.3, and 59.6% SiO.sub.2 (column 6, lines 46-56), therefore outside of the composition area operable in the instant invention. Finally, there is no reference made to cathodoluminescence so, obviously, there is no discussion as to the efficiency displayed by the products of the patented invention.
U.S. Pat. No. 3,459,673 describes the preparation, via a hydrolysis technique, of rare earth-doped silica products exhibiting luminescence. Although europium is mentioned as a useful dopant, there is no disclosure of firing the articles in a reducing atmosphere, there is no disclosure regarding a bluish luminescence under either ultraviolet or cathode rays, and the very high silica contents render the glasses far removed from those of the present invention.
U.S. Pat. No. 3,522,191 discloses the melting of europium-containing glasses under reducing conditions, the base compositions of which include substantial amounts of B.sub.2 O.sub.3 and/or P.sub.2 O.sub.5. Such glasses are, self-evidently, outside of the aluminosilicate glasses of the instant invention. Of particular interest, however, is Glass No. 25 in Example III which has the same composition as the sole europium-containing example of U.S. Pat. No. 3,374,381, supra. The comments made by the patentees (who are also the patentees of Patent No. 3,374,381, supra) regarding Glass No. 25 and others indicated a lack of strong luminescence therein and that their B.sub.2 O.sub.3 and/or P.sub.2 O.sub.5 -containing glasses constituted a marked improvement thereover. Those comments also underscored the fact, noted above in the section of the present specification entitled Background of the Invention, that attempts to produce high Eu.sup.+2 ion concentrations in glasses through melting under reducing conditions have been less than uniformly satisfactory. Thus, the instant invention is based upon firing the glass in a reducing environment after it has been shaped into an article.
DESCRIPTION OF PREFERRED EMBODIMENTS
Table I reports a number of approximate glass compositions, expressed in terms of mole percent on the oxide basis, illustrating the operable parameters of the instant invention. (Table IA recites the same glass compositions, but expressed in terms of parts by weight on the oxide basis.) The batch ingredients therefor can comprise any materials, either the oxides or other compounds, which, when melted together, will be converted to the desired oxide in the proper proportions. Some chloride is retained in the glass and, since it is not known with which cation(s) it is combined, it is simply reported in terms of CaCl.sub.2, the actual batch ingredient employed.
The batch ingredients for the individual examples were compounded, ballmilled together to assist in achieving a homogeneous melt, and deposited in platinum crucibles. (Larger scale melts involving pots or continuous melting tanks can, of course, be undertaken.) The crucibles were covered, placed in a furnace operating at about 1650.degree. C., and the melts maintained therewithin for 16 hours with stirring. The melts were then poured into steel molds to yield slabs having dimensions of about 10 inches .times. 4 inches .times. 1/4 inch and those slabs were immediately transferred to annealers operating at 700.degree.- 900.degree. C.
The slabs were annealed to room temperature to allow observation of glass quality and to permit pieces to be cut therefrom. For example, tests for photoluminescence and cathodoluminescence were conducted on polished glass plates of about 10 .times. 10 .times. 1 millimeters.
Table I also records the Annealing Point (A.P.) and Strain Point (St.P.) determinations in .degree.C. conducted on several of the glasses in accordance with conventional measuring techniques.
TABLE I______________________________________ 1 2 3 4 5 6 7 8______________________________________SiO.sub.2 60.3 60.3 60.4 60.3 60.6 60.7 49.8 60.1Al.sub.2 O.sub.3 20.4 20.5 20.5 20.4 20.6 20.6 25.8 20.4CaO 19.2 19.2 18.9 18.7 18.4 18.1 22.0 18.0CaCl.sub.2 -- -- -- -- -- -- 1.0 1.2Na.sub.2 O -- -- -- -- -- -- 1.0 --Eu.sub.2 O.sub.3 0.03 0.06 0.2 0.3 0.45 0.6 0.5 0.3A.P. -- -- -- -- -- -- -- 838.degree.St.P. -- -- -- -- -- -- -- 794.degree. 9 10 11 12 13 14 15 16______________________________________SiO.sub.2 59.9 59.6 67.5 50.1 50.3 67.1 67.0 67.1Al.sub.2 O.sub.3 20.4 20.2 17.5 26.0 26.1 17.4 17.4 17.4CaO 17.9 17.8 13.7 22.6 -- -- -- --CaCl.sub.2 1.2 1.2 -- -- -- -- -- --MgO -- -- -- -- 23.1 15.0 -- --SrO -- -- -- -- -- -- 15.0 --BaO -- -- -- -- -- -- -- 15.1Eu.sub.2 O.sub.3 0.6 1.2 1.3 1.3 0.5 0.5 0.5 0.5A.P. -- -- -- -- 802.degree. -- 863.degree. --St.P. -- -- -- -- 763.degree. -- 814.degree. -- 17 18 19 20 21 22 23______________________________________SiO.sub.2 67.0 66.3 66.9 60.0 82.2 75.5 71.0Al.sub.2 O.sub.3 17.4 23.2 23.4 21.9 1.2 -- 1.1ZnO 15.0 -- -- -- -- -- --Y.sub.2 O.sub.3 -- 10.0 -- -- -- -- --La.sub.2 O.sub.3 -- -- 9.2 -- -- -- --K.sub.2 O -- -- -- 6.0 -- 16.5 3.3Na.sub.2 O -- -- -- 6.0 4.1 -- 3.3Li.sub.2 O -- -- -- 6.0 -- -- 3.3B.sub.2 O.sub.3 -- -- -- -- 12.2 7.7 --SrO -- -- -- -- -- -- 17.7Eu.sub.2 O.sub.3 0.5 0.6 0.6 0.2 0.3 0.3 0.3A.P. 768.degree. 877.degree. 853.degree. -- -- -- --St.P. 726.degree. 833.degree. 809.degree. -- -- -- --______________________________________
TABLE IA______________________________________ 1 2 3 4 5 6 7 8______________________________________SiO.sub.2 53.3 53.2 53.3 52.8 52.5 52.2 41.5 52.0Al.sub.2 O.sub.3 30.7 30.7 30.6 30.4 30.3 30.1 36.6 30.0CaO 15.9 15.8 15.5 15.3 14.9 14.6 17.1 14.6CaCl.sub.2 -- -- -- -- -- -- 1.5 1.9Na.sub.2 O -- -- -- -- -- -- 0.8 --Eu.sub.2 O.sub.3 0.16 0.31 0.93 1.5 2.3 3.1 2.4 1.5______________________________________ 9 10 11 12 13 14 15 16______________________________________SiO.sub.2 51.2 49.7 57.5 40.8 44.5 61.1 53.4 48.6Al.sub.2 O.sub.3 29.6 28.7 25.4 36.0 39.2 27.0 23.6 21.4CaO 14.3 13.9 10.9 17.2 -- -- -- --CaCl.sub.2 1.9 1.8 -- -- -- -- -- --MgO -- -- -- -- 13.7 9.2 -- --SrO -- -- -- -- -- -- 20.7 --BaO -- -- -- -- -- -- -- 27.9Eu.sub.2 O.sub.3 3.0 5.8 6.3 6.0 2.6 2.7 2.4 2.1 17 18 19 20 21 22 23______________________________________SiO.sub.2 55.9 45.3 40.7 51.1 78.7 67.3 61.5Al.sub.2 O.sub.3 24.7 26.9 24.2 31.8 1.9 -- 1.6ZnO 17.0 -- -- -- -- -- --Y.sub.2 O.sub.3 -- 25.6 -- -- -- -- --La.sub.2 O.sub.3 -- -- 33.1 -- -- -- --K.sub.2 O -- -- -- 8.0 -- 23.1 4.5Na.sub.2 O -- -- -- 5.3 4.1 -- 3.0Li.sub.2 O -- -- -- 2.5 -- -- 1.4B.sub.2 O.sub.3 -- -- -- -- 13.6 8.0 --SrO -- -- -- -- -- -- 26.5Eu.sub.2 O.sub.3 2.5 2.2 2.0 1.2 1.7 1.6 1.4______________________________________
Table II records several treatments in reducing atmospheres which were applied to the exemplary compositions of Table I. As was explained above, the slabs formed from the crucible melts were annealed to room temperature to enable test samples to be cut therefrom. Table II recites visual observations of photoluminescence of the polished glass plates exposed to sources of ultraviolet radiations having a wavelength of 2537A and 3650A, respectively, and cathodoluminescence resulting from the bombardment of electrons having an energy of 11 kilovolts (kV). It must be recognized that the annealing to room temperature prior to firing in a reducing environment is not mandatory for the successful operation of the invention. Hence, if desired, the glass shape formed from the molten batch max be immediately subjected to the firing step and then cooled to room temperature. Such practice can increase the speed of the overall process while also providing energy savings.
Forming gas (92% by volume N.sub.2 -- 8% by volume H.sub.2) was utilized as the source of a reducing atmosphere in the firings reported in Table II because of its safety and relative cheapness. The influence of moisture on the action of the reducing environment was studied through the use of "wet" forming gas. That is, the forming gas was passed through a container of distilled water prior to its introduction into the firing chamber. Moisture was thereby picked up from the reservoir of water and carried into the firing chamber. In like manner, the comparison examples of "wet" nitrogen employed the same apparatus.
The test glass samples of Table II were placed within a sealed furnace tube with the appropriate gaseous atmosphere flowing at a rate of 100 cc/minute. The furnace tube was purged with the treating gas prior to the actual firing step to insure reproducibility of results. In each case, the glass was heated from room temperature to the recorded temperature at furnace rate which, in the present case, was about 500.degree. C./minute. It will be understood that much slower, or even faster, heatup rates are possible. However, care must be exercised where more rapid heatup rates are employed to avoid thermal breakage.
TABLE II__________________________________________________________________________Example No. Heat Treatment 2537A 3650A 11 kV Electrons__________________________________________________________________________1 None Blue-white Blue Violet-blue1 900.degree. C.-16 hrs. forming Strong blue Strong blue Strong blue gas2 None Blue-white Blue Blue-violet2 900.degree. C.-16 hrs. forming Strong blue Strong blue Strong blue gas3 None Lavender Blue-white Violet3 900.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas4 None Light pink Light lavender Lavender4 900.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas5 None Pink Lavender Pink5 900.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas6 None Reddish-pink Pink Deep pink6 900.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas7 None Orange-pink Violet pink Violet pink7 900.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas7 900.degree. C.-16 hrs. wet Bright blue Bright blue Bright blue forming gas7 925.degree. C.-16 hrs. forming Bright blue- Bright blue- Bright blue- gas glass softened glass softened glass softened8 None Lavender Blue violet Violet pink8 850.degree. C.-16 hrs. Air Lavender Blue violet Violet pink8 850.degree. C.-16 hrs. Wet N.sub.2 Lavender Blue violet Violet pink8 850.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas8 900.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas8 950.degree. C.-16 hrs. forming Bright blue - Bright blue - Bright blue - gas glass softened glass softened softened9 None Deep pink Violet-pink Deep pink9 900.degree. C.-16 hrs. Air Deep pink Violet-pink Deep pink9 900.degree. C.-16 hrs. N.sub.2 Deep pink Violet-pink Deep pink9 900.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas9 900.degree. C.-16 hrs. wet Bright blue Bright blue Bright blue forming gas10 None Deep red Deep red Deep red10 900.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas10 900.degree. C.-16 hrs. wet Bright blue Bright blue Bright blue forming gas11 None Red-orange Deep pink Deep pink11 750.degree. C.-16 hrs. forming Violet-pink Violet-blue Violet-blue gas11 800.degree. C.-16 hrs. forming Bluish-white Bluish-white Bluish-white gas11 825.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas11 850.degree. C.-4 hrs. forming Bright blue Bright blue Bright blue gas12 None Red-orange Orange pink Deep pink12 750.degree. C.-16 hrs. forming Violet-pink Violet-blue Violet-pink gas12 825.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas12 850.degree. C.-4 hrs. forming Bright blue Bright blue Bright blue gas13 None Deep blue Lavender Violet-pink13 800.degree. C.-4 hrs. forming Bright blue Bright blue Bright blue gas13 825.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas13 900.degree. C.-16 hrs. forming Bright blue - Bright blue - Bright blue - gas glass softened glass softened glass softened14 None Pink Blue-white Deep pink14 825.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas14 850.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas14 950.degree. C.-16 hrs. forming Bright blue- Bright blue- Bright blue - gas glass softened glass softened glass softened15 None Pink Blue-white Deep pink15 825.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas15 950.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas16 None Pink White Deep pink16 825.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas16 850.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas17 None Orange pink Pink Deep pink17 825.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas17 850.degree. C.-4 hrs. forming Bright blue Bright blue Bright blue gas17 850.degree. C.-16 hrs. forming Bright blue-hazy Bright blue-hazy Bright blue-hazy gas glass-opalized at glass-opalized at glass-opalized at 900.degree. C. 900.degree. C. 900.degree. C.18 None Violet-pink Lavender-blue Reddish-pink18 825.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas18 900.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas19 None Pink Blue-violet Pink19 825.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas20 None Pink Blue Violet20 800.degree. C.-16 hrs. forming Bright blue Bright blue Bright blue gas20 850.degree. C.-16 hrs. forming Bright blue- Bright blue- Bright blue- gas glass softened glass softened glass softened21 None Pink Lavender Pink21 650.degree. C.-5 hrs. forming Weak blue Weak blue Weak blue gas21 700.degree. C.-5 hrs. forming Moderate blue Moderate blue Moderate blue gas21 750.degree. C.-16 hrs. forming Moderate blue - Moderate blue - Moderate blue - gas glass softened glass softened glass softened22 None Red Red Red22 700.degree. C.-5 hrs. forming Red Red Red gas22 750.degree. C.-5 hrs. forming Red - glass Red - glass Red- glass gas softened softened softened23 None Red-orange Red-orange Red-orange23 650.degree. C.-5 hrs. forming Red-orange Red-orange Red-orange gas23 700.degree. C.-5 hrs. forming Red-orange - glass Red-orange - glass Red-orange - gas softened softened softened__________________________________________________________________________
Several features of interest can be discerned from Table II. For example, the untreated glasses of Examples 1-6 illustrate the tendency for the luminescence to acquire an increasingly reddish character as greater amounts of europium are incorporated in the glass. However, after exposure to reducing conditions, each manifests a considerably brighter luminescene, and of a blue color, under both ultraviolet and cathode rays. Visually, the brightness of the luminescence increases from Example 1 through Example 6.
Comparison tests utilizing wet and dry forming gas did not evidence any marked difference in effect therebetween. The use of gaseous atmospheres of nitrogen (a neutral environment) and air (an oxidizing environment) clearly pointed to the need for reducing conditions to secure the presence of Eu.sup.+2 ions with the consequent blue luminescence.
Treatments at 750.degree. C. of Examples 11 and 12 demonstrated incomplete conversion to Eu.sup.+2 ions. A temperature of at least about 800.degree. C. appears to be a preferred lower limit for glasses containing divalent or trivalent modifying oxides, depending upon glass composition, and will be determined for each glass of interest. With the softer, monovalent ion glasses, temperatures of about 600.degree. C. will be operable. The upper temperature limit comprises that temperature at which opalization or softening of the glass occurs. Most of the glasses recorded in Table II displayed some degree of softening at 950.degree. C. Exceptions thereto were Examples 7 and 13, which softened at lower temperatures, and Example 17 which opacified.
To prove that the blue surface luminescence was not caused by the development of a transparent surface crystalline phase, Examples 11, 12, and 14, after being exposed to dry forming gas for 16 hours at 950.degree. C., and Example 17, after being fired in dry forming gas for 16 hours at 850.degree. C., were examined by surface X-ray diffraction techniques. Only Example 17, noted as hazy in Table II, exhibited a trace of surface crystallization. The other samples evidenced no trace of crystallization.
Examples 21-23 are softer glasses containing little or no alumina. Thus, Examples 22 and 23 represent glasses in which surface reduction does not take place at temperatures below the glass deformation temperature. Example 21 is illustrative of a borderline composition, with respect to the firing step, in that a weak-to-moderate blue luminescence can be secured at temperatures approaching the softening point thereof. Example 20 can exhibit relatively good blue luminescence but its cathodoluminescence is somewhat less than that of Example 3 containing about the same Eu.sub.2 O.sub.3 content on the molar basis.
A more detailed examination of the cathodoluminescence behavior of several of the exemplary compositions is set out in Table III. Because these luminescent surfaces are produced by the action of a diffusing gas, viz., hydrogen, the depth and uniformity of the surface layer so produced must be characterized as a function of the penetrating power of impinging electrons to which the surface may be exposed during actual service. Most conventional cathode ray tube phosphors consist of some luminescence activator uniformly distributed within the structure of a host material, customarily a crystalline material.
A measurement of cathodoluminescence intensity versus electron accelerating potential, measured at a constant beam current, for such a uniform material will generally yield a straight line. This linearity indicates that over the electron energy range encountered in the conventional cathode ray tube, such as a television receiver tube, the cathodoluminescence efficiency of the phosphor is constant. Since electrons of different energies penetrate the phosphor to different depths, linearity also illustrates that the efficiency of the phosphor is constant throughout the thickness of the phosphor corresponding to the penetration depth of the impinging electrons. A convenient estimate of electron penetration depth is given by the "penetration limit" defined as that depth beyond which negligible power is transmitted to the material. Penetration limits are set out below for the electron energy range, expressed in electron volts (KEV), customarily obtaining in the cathode ray tube and color television industries. The data are derived from Terrill's Equation recited on page 158 of An Introduction to Luminescence of Solids, Humboldt W. Leverenz, Dover Publications, Inc., New York, 1968. A glass density of 2.5 g/cm.sup.3 is assumed in the calculations.
______________________________________Electron Energy in KEV Penetration Limit in Microns______________________________________ 5 0.2510 1.0015 2.2520 4.0025 6.25______________________________________
Hence, to provide constant efficiency for electrons up to 25 KEV in energy, the reducing conditions to which the glass is exposed must be capable of insuring the presence of Eu.sup.+2 ions to a depth of about 6 microns.
Table III records measurements made on several of the examples from Table I over the range of 6-24 kV acceleration potential (6-24 KEV electron energy). The range of linearity of cathodoluminescence intensity and, therefore, of constant efficiency is given as well as the calculated efficiency. Also, the wavelength of maximum photoluminescent intensity and the C.I.E. color coordinates are reported. Finally, Table III reports a measure of aging resistance (AR) expressed in %.
The aging of a cathodoluminescent phosphor is defined as the loss of luminescence intensity under sustained electron bombardment. It is measured during an accelerated aging test in which a sample is exposed to a high current density (30 microamperes/cm.sup.2) of high energy electrons (25 kV) for a period of 10 minutes. Aging resistance is defined as the ratio of the intensity of cathodoluminescence after 10 minutes exposure to the test conditions, to the intensity at the commencement of the test.
In general, higher-temperature, longer-time, heat treatments in reducing environments give rise to the most desirable combination of linearity, high efficiency over the electron energy range of most interest, and good aging resistance. It will be appreciated, of course, that optimum conditions must be determined for each individual glass.
In general, the aging resistance of these surface-activated europium-containing glasses is superior to that of most conventional glasses. It is exceeded only by that exhibited by the manganese-doped RO-Al.sub.2 O.sub.3 -SiO.sub.2 glasses disclosed in U.S. Pat. No. 3,962,117.
Although Table III reports visual descriptions of "bright blue" cathodoluminescence, it is apparent from the C.I.E. color coordinates that a range of bluish colors can be obtained, differing principally in saturation. Saturation is that quality of color which differentiates an intense "pure" blue color (saturated) from a pastel blue (relatively unsaturated). Side-by-side comparisons of polished glass plates can be useful in distinguishing such color differences in the respective luminescence emissions.
TABLE III__________________________________________________________________________Example Linear Efficiency Wave Length C.I.E. Coordinates (at 24 kV)No. Heat Treatment Range (kV) % A AR x y__________________________________________________________________________ 7 900.degree. C. - 16 hrs. 6-24 1.7 4500 50 0.180 0.185 forming gas 7 900.degree. C. - 16 hrs. 6-24 1.5 4600 52 0.189 0.212 wet forming gas 8 900.degree. C. - 16 hrs. 6-24 2.0 4300 61 0.167 0.121 forming gas 9 900.degree. C. - 16 hrs. 6-24 1.9 4450 57 0.172 0.150 forming gas 9 900.degree. C. - 16 hrs. 6-24 1.7 4500 56 0.176 0.166 wet forming gas10 None 6-24 0.17 6200 -- 0.615 0.31710 900.degree. C. - 16 hrs. 6-24 1.4 4500 49 0.183 0.200 forming gas10 900.degree. C. - 16 hrs. 6-24 1.3 4600 40 0.198 0.220 wet formng gas11 825.degree. C. - 16 hrs. 6-24 0.3 4400 68 0.189 0.167 forming gas11 850.degree. C. - 4 hrs. 6-16 1.7 4500 55 0.178 0.169 forming gas12 825.degree. C. - 16 hrs. 6-24 0.5 4400 69 0.181 0.153 forming gas12 850.degree. C. - 4 hrs. 6-10 1.1 4700 48 0.248 0.258 forming gas13 850.degree. C. - 4 hrs. 6-12 1.5 4450 60 0.178 0.145 forming gas14 825.degree. C. - 16 hrs. 6-24 1.7 4500 57 0.184 0.193 forming gas14 850.degree. C. - 16 hrs. 6-24 1.7 4500 51 0.184 0.199 forming gas15 825.degree. C. - 16 hrs. 6-24 2.1 4500 60 0.176 0.165 forming gas15 950.degree. C. - 16 hrs. 6-22 2.2 4500 54 0.172 0.156 forming gas16 825.degree. C. - 16 hrs. 6-24 1.9 4400 69 0.162 0.113 forming gas16 850.degree. C. - 4 hrs. 6-22 1.8 4500 48 0.183 0.192 forming gas17 825.degree. C. - 16 hrs. 6-20 1.3 4400 69 0.172 0.147 forming gas17 800.degree. C. - 4 hrs. 6-22 1.9 4500 52 0.176 0.167 forming gas18 825.degree. C. - 16 hrs. 6-16 1.2 4700 43 0.213 0.248 forming gas18 900.degree. C. - 16 hrs. 6-20 1.2 4650 46 0.200 0.249 forming gas19 825.degree. C. - 16 hrs. 6-24 1.8 4500 47 0.170 0.162 forming gas__________________________________________________________________________
Table III clearly demonstrates the superior cathodoluminescent properties exhibited by the glasses of the instant invention. Hence, power conversion efficiencies greater than 1% are customarily achieved and, in some instances, can surpass 2%. Also, the values of aging resistance commonly exceed 50% in the above-described test.
Table IV reports several examples, expressed in mole percent on the oxide basis, which were produced in accordance with the method outlined above for the exemplary compositions of Table I and Annealing Points (A.P.) and Strain Points (St.P.) where measured. (Table IVA records the compositions in terms of weight percent.)
TABLE IV__________________________________________________________________________24 25 26 27 28 29 30 31 32 33 34 35 36 37__________________________________________________________________________SiO.sub.2 59.6 59.9 59.8 59.9 59.9 59.9 59.9 59.9 59.9 59.8 59.9 59.9 59.9 59.9Al.sub.2 O.sub.3 10.6 19.9 20.0 20.0 19.9 9.9 10.0 10.0 20.0 10.0 20.0 20.0 20.0 20.0MgO 29.8 19.0 -- -- -- -- -- -- -- -- -- -- -- --CaO -- -- 19.9 -- -- -- -- -- -- -- 16.9 16.9 -- --SrO -- -- -- -- -- 29.9 -- -- -- -- -- -- -- --BaO -- -- -- -- -- -- 29.9 -- -- -- -- -- -- --ZnO -- -- -- -- -- -- -- 29.9 -- -- -- -- -- --CdO -- -- -- 19.9 -- -- -- -- -- -- -- -- -- --PbO -- -- -- -- 19.9 -- -- -- -- -- -- -- --K.sub.2 O -- -- -- -- -- -- -- -- 19.9 9.9 -- 1.0 -- --Na.sub.2 O -- -- -- -- -- -- -- -- -- 9.9 3.0 1.0 19.9 --Li.sub.2 O -- -- -- -- -- -- -- -- -- 10.1 -- 1.0 -- 19.9Eu.sub.2 O.sub.3 0.006 0.3 0.25 0.26 0.24 0.24 0.24 0.24 0.26 0.24 0.25 0.25 0.25 0.25A.P. -- -- -- 766.degree. 693.degree. -- -- -- -- 453.degree. -- -- 764.degree. 668.degree.St.P. -- -- -- 702.degree. 646.degree. -- -- -- -- 414.degree. -- -- 707.degree. 622.degree.__________________________________________________________________________
TABLE IVA__________________________________________________________________________24 25 26 27 28 29 30 31 32 33 34 35 36 37__________________________________________________________________________SiO.sub.2 61.0 55.1 52.6 43.4 35.4 46.1 38.7 50.4 47.3 59.8 52.5 52.5 51.7 57.0Al.sub.2 O.sub.3 18.5 31.2 30.0 24.6 20.0 13.0 11.0 14.3 26.8 15.5 29.7 29.7 29.3 32.2MgO 20.5 12.3 -- -- -- -- -- -- -- -- -- -- -- --CaO -- -- 16.4 -- -- -- -- -- -- -- 13.9 13.9 -- --SrO -- -- -- -- -- 39.8 -- -- -- -- -- -- -- --BaO -- -- -- -- -- -- 49.4 -- -- -- -- -- -- --ZnO -- -- -- -- -- -- -- 34.1 -- -- -- -- -- --CdO -- -- -- 30.9 -- -- -- -- -- -- -- -- -- --PbO -- -- -- -- 43.8 -- -- -- -- -- -- -- -- --K.sub.2 O -- -- -- -- -- -- -- -- 24.7 14.3 -- 0.9 -- --Na.sub.2 O -- -- -- -- -- -- -- -- -- 9.4 2.7 0.4 17.8 --Li.sub.2 O -- -- -- -- -- -- -- -- -- 4.6 -- 1.3 -- 9.4Eu.sub.2 O.sub.3 0.05 1.4 1.3 1.1 0.9 1.1 0.9 1.2 1.2 1.3 1.3 1.3 1.3 1.4__________________________________________________________________________
Table V sets out several treatments in reducing atmospheres consisting of dry forming gas to which the glass articles of Table IV were subjected. In like manner to Table II above, Table V recites visual observations of photoluminescence of polished glass plates exposed to sources of ultraviolet radiations having a wavelength of 2537A and 3650A, respectively, and cathodoluminescence resulting from the bombardment of electrons having an energy of 11 kilovolts. The treatment in forming gas was carried out similarly to that described in Table II except that in no example was the gas passed through distilled water prior to introduction into the furnace.
A comparison of the visual observations with respect to Examples 7, 9, and 10 of Table III indicated that the luminescence produced utilizing a wet reducing atmosphere was slightly less efficient and, perhaps, the color less saturated than when a dry atmosphere was employed. In any event, no significant advantage was observed with the H.sub.2 O-containing environment and the elimination of the water column simplifies the procedure and, hence, the use of a dry atmosphere is more desirable from a practical point of view.
Table V______________________________________Ex. HeatNo. Treatment 2537A 3650A 11 kV Electrons______________________________________24 None Weak Weak blue Very weak blue blue24 900.degree. C.-16 hrs. Weak Weak blue Very weak blue blue Glass exhibited a slightly hazy appearance25 None Violet- Blue- Very weak pink pink white25 900.degree. C.-16 hrs. Blue Blue Very bright blue26 None Pink Blue- Very weak pink white26 900.degree. C.-16 hrs. Blue Blue Very bright blue27 None Bright Deep Very weak pink orange- orange- red red27 900.degree. C.-16 hrs. Flat blue Dull Moderate blue orange- red Glass exhibited a yellow color28 None Bright Deep Very weak pink orange- orange- yellow red28 850.degree. C.-16 hrs. Dead Dead Very weak blue Glass exhibited a black surface skin29 None Orange Yellow- Weak orange pink white29 850.degree. C.-16 hrs. -- -- Moderate blue- white30 None Yellow- Yellow- Very weak pink orange orange30 850.degree. C.-16 hrs. -- -- Weak pink white31 Glass became opalized upon cooling from melt32 Glass extremely viscous, did not pour33 None Yellow- Red Weak pink orange white33 850.degree. C.-16 hrs. Glass flowed and devitrified33 600.degree. C.-5 hrs. Glass softened and opalized34 None Pink Blue- Very weak pink white34 900.degree. C.-16 hrs. Blue Blue Very bright blue forming gas35 None pink Blue- Very weak pink white35 900.degree. C.-16 hrs. Blue Blue Very bright blue forming gas36 None Salmon Blue- Weak orange pink white36 850.degree. C.-16 hrs. -- -- Moderate blue forming gas36 700.degree. C.-5 hrs. -- -- Bright-blue forming gas37 None Violet Light Weak pink- pink blue orange37 850.degree. C.-16 hrs. -- -- Very bright blue forming gas37 650.degree. C.-5 hrs. -- -- Bright blue forming gas______________________________________
Tables IV and V help to illustrate the compositional parameters that must be observed to achieve the desired properties of the inventive glasses. For example, compositions 24, 29, 30, 31, and 33, falling somewhat outside the prescribed ranges of components, exhibited poor luminescence under both ultraviolet radiation and electron bombardment. Example 27 points up that CdO is not as an effective an addition as are the alkaline earth metal oxides and Example 28 demonstrates an adverse effect resulting from extensive additions of lead. The surface skin was thought to be caused by the reduction of the lead oxide to metallic lead.
In summary, glasses consisting solely of Eu.sub.2 O.sub.3, Al.sub.2 O.sub.3, and SiO.sub.2 are difficult to melt and form, such that other components, i.e., network formers and/or network modifiers, are included in amounts of at least 3 mole percent. As is evident from Tables I and IV, a wide variety of ingredients can be added which will improve the melting and forming characteristics of the glass and impart greater glass stability. In general, divalent metal oxides, and particularly the alkaline earth metal oxides, comprise the preferred additions.
The strength and brilliance of the blue luminescence appear to be enhanced with greater amounts of europium in the glass composition. Therefore, the presence of at least about 0.1 mole percent is preferred. However, the visual appearance does not seem to vary appreciably at concentrations in excess of about 2 mole percent, so that figure is deemed to be a practical maximum.

Number	Name	Date
3457182	Lee et al.	Jul 1969
3471408	Young	Oct 1969
3663474	Lee et al.	May 1972
3843551	Muller	Oct 1974

Cathodoluminescent and photoluminescent glasses

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