CN114455836B

CN114455836B - Near infrared light absorbing glass, element and filter

Info

Publication number: CN114455836B
Application number: CN202210295801.XA
Authority: CN
Inventors: 孙伟
Original assignee: CDGM Glass Co Ltd
Current assignee: CDGM Glass Co Ltd
Priority date: 2022-03-24
Filing date: 2022-03-24
Publication date: 2023-07-18
Anticipated expiration: 2042-03-24
Also published as: CN114455836A

Abstract

The present invention provides a near infrared light absorbing glass comprising P in its composition ⁵⁺ 、Cu ²⁺ 、Rn ⁺ 、R ²⁺ And Ln ³⁺ The Rn is ⁺ Is Li ⁺ 、Na ⁺ 、K ⁺ One or more of R ²⁺ Is Mg ²⁺ 、Ca ²⁺ 、Sr ²⁺ 、Ba ²⁺ One or more of Ln ³⁺ Is La (La) ³⁺ 、Gd ³⁺ 、Y ³⁺ The transmittance tau at 400nm of the near infrared light absorbing glass having a thickness of 0.5mm or less ₄₀₀ A transmittance τ at 500nm of 80.0% or more ₅₀₀ A transmittance τ at 1100nm of 83.0% or more ₁₁₀₀ Is 10.0% or less. Through reasonable component design, the near infrared light absorption glass obtained by the invention has excellent transmission characteristics in a visible region and excellent absorption characteristics in a near infrared region.

Description

Near infrared light absorbing glass, element and filter

Technical Field

The present invention relates to a glass, and more particularly, to a near infrared light absorbing glass, and a near infrared light absorbing element and a filter made thereof.

Background

In recent years, the spectral sensitivity of semiconductor imaging devices such as CCDs and CMOS used in digital cameras, camera phones, and VTR cameras has been spread from the visible region to the near infrared region, and near human visual acuity has been obtained by using filters that absorb light in the near infrared region. The visible light wavelength that can be perceived by the human eye is typically between 400 and 700nm, and therefore, an image similar to the luminance factor of the human eye can be obtained by using a filter that absorbs near infrared light. As the demand for color sensitivity correction filters has increased, there has been a corresponding demand for near infrared light absorbing glasses for use in the manufacture of such filters, which have excellent transmission characteristics in the visible region and excellent absorption characteristics in the near infrared region.

Disclosure of Invention

The invention aims to provide near-infrared light absorbing glass which has excellent transmittance in a visible region and excellent absorption performance in a near-infrared region.

The technical scheme adopted for solving the technical problems is as follows:

(1) The near infrared light absorbing glass contains P in the components ⁵⁺ 、Cu ²⁺ 、Rn ⁺ 、R ²⁺ And Ln ³⁺ The Rn is ⁺ Is Li ⁺ 、Na ⁺ 、K ⁺ One or more of R ²⁺ Is Mg ²⁺ 、Ca ²⁺ 、Sr ²⁺ 、Ba ²⁺ One or more of Ln ³⁺ Is La (La) ³⁺ 、Gd ³⁺ 、Y ³⁺ The transmittance tau at 400nm of the near infrared light absorbing glass having a thickness of 0.5mm or less ₄₀₀ A transmittance τ at 500nm of 80.0% or more ₅₀₀ A transmittance τ at 1100nm of 83.0% or more ₁₁₀₀ Is 10.0% or less.

(2) The near-infrared light absorbing glass according to (1), wherein the near-infrared light absorbing glass has a thickness of 0.5mm or less and a transmittance τ at 400nm ₄₀₀ 82.0% or more, preferably 84.0% or more; and/or a transmittance τ at 500nm ₅₀₀ 85.0% or more, preferably 88.0% or more; and/or transmittance τ at 1100nm ₁₁₀₀ The content is 7.0% or less, preferably 5.0% or less, and more preferably 3.0% or less.

(3) The near infrared light absorbing glass according to (1) or (2), wherein the cationic component contains, in mole percent: p (P) ⁵⁺ :51 to 72%, preferably P ⁵⁺ : 56-68%, more preferably P ⁵⁺ : 60-65%; and/or Cu ²⁺ :5 to 25%, preferably Cu ²⁺ :6 to 20%, more preferably Cu ²⁺ : 8-15%; and/or Rn ⁺ :5 to 25%, preferably Rn ⁺ :7 to 20%, more preferably Rn ⁺ : 10-17%; and/or R ²⁺ :1 to 18%, preferably R ²⁺ :3 to 16%, more preferably R ²⁺ : 5-14%; and/or Ln ³⁺ : greater than 0 but less than or equal to 8%, preferably Ln ³⁺ : from 0.1 to 6%, more preferably Ln ³⁺ : 0.5-4%, rn ⁺ Is Li ⁺ 、Na ⁺ 、K ⁺ One or more of R ²⁺ Is Mg ²⁺ 、Ca ²⁺ 、Sr ²⁺ 、Ba ²⁺ One or more of Ln ³⁺ Is La (La) ³⁺ 、Gd ³⁺ 、Y ³⁺ One or more of the following.

(4) The near infrared light absorbing glass according to any one of (1) to (3), wherein the cationic component further comprises, in mole percent: al (Al) ³⁺ :0 to 10%, preferably Al ³⁺ :0.5 to 8%, more preferably Al ³⁺ :1 to 5 percent; and/or Zn ²⁺ :0 to 10%, preferably Zn ²⁺ :0 to 5%, more preferably Zn ²⁺ :0 to 2 percent; andand/or Si ⁴⁺ :0 to 5%, preferably Si ⁴⁺ : from 0 to 2%, more preferably Si ⁴⁺ :0 to 1 percent; and/or B ³⁺ :0 to 5%, preferably B ³⁺ : from 0 to 2%, more preferably B ³⁺ :0 to 1 percent; and/or Zr ⁴⁺ :0 to 5%, preferably Zr ⁴⁺ :0 to 2 percent, more preferably Zr ⁴⁺ :0 to 1 percent; and/or Sb ³⁺ +Sn ⁴⁺ +Ce ⁴⁺ :0 to 1%, preferably Sb ³⁺ +Sn ⁴⁺ +Ce ⁴⁺ :0 to 0.5%, more preferably Sb ³⁺ +Sn ⁴⁺ +Ce ⁴⁺ ：0～0.1％。

(5) The near infrared light absorbing glass according to any one of (1) to (4), wherein the composition satisfies one or more of the following 5 cases in terms of mole percent:

1)Al ³⁺ /Ln ³⁺ at least 0.2, preferably Al ³⁺ /Ln ³⁺ From 0.2 to 20.0, more preferably Al ³⁺ /Ln ³⁺ From 0.5 to 15.0, al being more preferred ³⁺ /Ln ³⁺ From 1.0 to 10.0, al being more preferred ³⁺ /Ln ³⁺ 1.5 to 8.0;

2)Li ⁺ /(Mg ²⁺ +Al ³⁺ ) From 0.4 to 10.0, preferably Li ⁺ /(Mg ²⁺ +Al ³⁺ ) From 0.6 to 7.0, more preferably Li ⁺ /(Mg ² ⁺ +Al ³⁺ ) From 1.0 to 5.0, li being more preferred ⁺ /(Mg ²⁺ +Al ³⁺ ) 1.2 to 3.0;

3)Cu ²⁺ /Al ³⁺ is 1.0 to 15.0, preferably Cu ²⁺ /Al ³⁺ From 2.0 to 10.0, more preferably Cu ²⁺ /Al ³⁺ From 3.0 to 8.0, cu being more preferable ²⁺ /Al ³⁺ 4.0 to 7.0;

4)Ln ³⁺ /(Ba ²⁺ +Al ³⁺ ) Is 0.02 or more, preferably Ln ³⁺ /(Ba ²⁺ +Al ³⁺ ) From 0.02 to 2.0, more preferably Ln ³⁺ /(Ba ²⁺ +Al ³⁺ ) Is 0.05 to 1.0, and Ln is more preferable ³⁺ /(Ba ²⁺ +Al ³⁺ ) From 0.08 to 0.8, ln is more preferable ³⁺ /(Ba ²⁺ +Al ³⁺ ) 0.1 to 0.5;

5)P ⁵⁺ /R ²⁺ from 3.0 to 30.0, preferably P ⁵⁺ /R ²⁺ From 3.5 to 25.0, more preferably P ⁵⁺ /R ²⁺ From 4.0 to 20.0, more preferably P ⁵⁺ /R ²⁺ 5.0 to 10.0.

(6) The near infrared light absorbing glass according to any one of (1) to (5), wherein: li (Li) ⁺ :5 to 25%, preferably Li ⁺ :8 to 20%, more preferably Li ⁺ : 10-16%; and/or Na ⁺ :0 to 10%, preferably Na ⁺ :0 to 5%, more preferably Na ⁺ :0 to 2 percent; and/or K ⁺ :0 to 10%, preferably K ⁺ :0 to 5%, more preferably K ⁺ :0 to 2 percent; and/or Mg ²⁺ :0 to 15%, preferably Mg ²⁺ :0.5 to 10%, more preferably Mg ²⁺ : 2-8%; and/or Ca ²⁺ :0 to 10%, preferably Ca ²⁺ :0 to 5%, more preferably Ca ²⁺ :0 to 2 percent; and/or Sr ²⁺ :0 to 10%, preferably Sr ²⁺ :0 to 5%, more preferably Sr ²⁺ :0 to 2 percent; and/or Ba ²⁺ :0 to 10%, preferably Ba ²⁺ :0.5 to 8%, more preferably Ba ²⁺ :1 to 6 percent; and/or La ³⁺ :0 to 5%, preferably La ³⁺ :0 to 3%, more preferably La ³⁺ :0 to 2 percent; and/or Gd ³⁺ :0 to 5%, preferably Gd ³⁺ :0 to 3%, more preferably Gd ³⁺ :0 to 2 percent; and/or Y ³⁺ :0 to 6%, preferably Y ³ ⁺ :0.1 to 5%, more preferably Y ³⁺ ：0.5～3％。

(7) The near infrared light absorbing glass according to any one of (1) to (6), wherein the anionic component comprises, in mole percent: o (O) ^2- :85 to 99.5%, preferably O ^2- :88 to 99%, more preferably O ^2- : 91-98%; and/or F ^- :0.5 to 15%, preferably F ^- :1 to 12%, more preferably F ^- ：2～9％。

(8) The near infrared light absorbing glass according to any one of (1) to (7), wherein the components thereof are represented by mole percent, wherein: ln (Ln) ³⁺ /F ^- Is 0.01 or more, preferably Ln ³⁺ /F ^- 0.02 to 10.0, more preferably Ln ³⁺ /F ^- Is 0.05 to 5.0, and Ln is more preferable ³⁺ /F ^- From 0.05 to 2.0, ln being more preferred ³⁺ /F ^- 0.1 to 1.0; and/or F ^- /Cu ²⁺ From 0.05 to 2.0, preferably F ^- /Cu ²⁺ From 0.1 to 1.5, more preferably F ^- /Cu ²⁺ F is more preferably 0.2 to 1.0 ^- /Cu ²⁺ Is 0.3 0.8.

(9) The near infrared light absorbing glass according to any one of (1) to (8), wherein the anionic component further comprises, in mole percent: cl ^- +Br ^- +I ^- :0 to 2%, preferably Cl ^- +Br ^- +I ^- :0 to 1%, more preferably Cl ^- +Br ^- +I ^- ：0～0.5％。

(10) The near-infrared light absorbing glass according to any one of (1) to (9), which has a transition temperature T _g At 410℃or lower, preferably 400℃or lower, more preferably 390℃or lower, and even more preferably 370 to 390 ℃; and/or density ρ of 3.3g/cm ³ Hereinafter, it is preferably 3.2g/cm ³ Hereinafter, it is more preferably 3.1g/cm ³ Hereinafter, it is more preferably 3.0g/cm ³ The following are set forth; and/or coefficient of thermal expansion alpha _20-120℃ 110X 10 ^-7 Preferably 100X 10, and K is less than or equal to ^-7 Preferably not more than/K, more preferably 95X 10 ^-7 and/K or below; and/or hardness H _v 380kgf/mm ² Above, preferably 390kgf/mm ² The above is more preferably 400kgf/mm ² The above is more preferably 410kgf/mm ² The above; young's modulus E of 5500X 10 ⁷ ～8500×10 ⁷ Pa, preferably 6000X 10 ⁷ ～8000×10 ⁷ Pa, more preferably 6500×10 ⁷ ～7500×10 ⁷ Pa。

(11) The near-infrared light absorbing glass according to any one of (1) to (10), wherein the near-infrared light absorbing glass has a thickness of 0.5mm or less and a spectral transmittance in a wavelength range of 500 to 700nm of a wavelength lambda corresponding to a transmittance of 50% ₅₀ The wavelength is 635nm or less, preferably 600 to 630nm, more preferably 610 to 625nm.

(12) The near infrared light absorbing glass according to any one of (1) to (11), wherein the thickness of the near infrared light absorbing glass is 0.05 to 0.4mm, preferably 0.1 to 0.3mm, more preferably 0.1mm or 0.15mm or 0.2mm or 0.25mm.

(13) A near-infrared light absorbing glass element comprising the near-infrared light absorbing glass according to any one of (1) to (12).

(14) A filter comprising the near infrared light absorbing glass according to any one of (1) to (12) or the near infrared light absorbing glass element according to (13).

(15) An apparatus comprising the near infrared light absorbing glass according to any one of (1) to (12), or the near infrared light absorbing glass element according to (13), or the optical filter according to (14).

The beneficial effects of the invention are as follows: through reasonable component design, the near infrared light absorption glass obtained by the invention has excellent transmission characteristics in a visible region and excellent absorption characteristics in a near infrared region.

Detailed Description

The following describes embodiments of the present invention in detail, but the present invention is not limited to the following embodiments, and can be implemented with appropriate modifications within the scope of the object of the present invention. In the repeated explanation, explanation is omitted appropriately, but the gist of the invention is not limited thereto. The near infrared light absorbing glass of the present invention is sometimes referred to simply as glass.

[ near-infrared light absorbing glass ]

The ranges of the respective components (ingredients) constituting the near-infrared light absorbing glass of the present invention are described below. In the present specification, if not specified, the content of the cationic component is expressed as a mole percent (mol%) of the cation to the total cationic component, and the content of the anionic component is expressed as a mole percent (mol%) of the anion to the total anionic component; the ratio between the cation component contents is the ratio of the mole percent contents between the cation component contents; the ratio between the contents of the anionic components is the ratio of the contents of the respective anionic components in mole percent; the ratio between the contents of the anionic and cationic components is the ratio between the molar percentage of the cationic component to the molar percentage of the anionic component to the anionic component.

Unless otherwise indicated in a particular context, numerical ranges set forth herein include upper and lower limits, and "above" and "below" include endpoints, and all integers and fractions within the range, and are not limited to the specific values set forth in the defined range. The term "and/or" as used herein is inclusive, e.g. "a and/or B", meaning either a alone, B alone, or both a and B.

The ion valences of the components described below are representative values used for convenience, and are not different from other ion valences. The ion valences of the components in the glass may be other than the representative value. For example, P is usually present in the glass in a state of ion valence +5, and is therefore referred to as "P" in this patent ⁵⁺ "as a representative value, but there is the possibility of existence in other ionic valence states, which is also within the scope of protection of this patent.

< cationic component >

P ⁵⁺ Is an indispensable component for forming a glass skeleton, can promote the formation of glass and is beneficial to improving the near infrared absorption performance of the glass, if P ⁵⁺ The content of (2) is lower than 51%, the effect is insufficient, and the near infrared absorption function of the glass cannot meet the design requirement; if P ⁵⁺ The content of (2) exceeds 72%, the devitrification tendency of the glass increases, and the weather resistance decreases. Thus P in the present invention ⁵⁺ The content of (2) is 51 to 72%, preferably 56 to 68%, more preferably 60 to 65%.

Al ³⁺ The glass has the advantages of increasing the stability of the glass, improving the strength of the glass and improving the weather resistance of the glass, but when the content exceeds 10%, the crystallization tendency of the glass increases and the melting property of the glass becomes poor. Thus Al in the present invention ³⁺ The content of (2) is 0 to 10%, preferably 0.5 to 8%, more preferably 1 to 5%.

Cu ²⁺ Is an essential component for obtaining near infrared light absorption performance of the glass of the present invention, and if the content thereof is less than 5%, the near infrared light absorption performance of the glass is obtainedThe absorption performance is difficult to meet the design requirement, but if Cu ²⁺ The content of (2) exceeds 25%, the transmittance in the visible light region of the glass is lowered, the valence state of Cu in the glass is changed, the desired light absorption performance is hardly obtained, and the devitrification resistance of the glass is lowered. Thus Cu in the present invention ²⁺ The content of (2) is 5 to 25%, preferably 6 to 20%, more preferably 8 to 15%.

In some embodiments, cu ²⁺ Content of (2) and Al ³⁺ Ratio between contents of Cu ²⁺ /Al ³⁺ The glass can have excellent transmittance in the visible light range and can improve near infrared absorption and proper Young modulus of the glass by controlling the glass within the range of 1.0-15.0. Therefore, cu is preferable ²⁺ /Al ³⁺ Is 1.0 to 15.0, more preferably Cu ²⁺ /Al ³⁺ Is 2.0 to 10.0, more preferably Cu ²⁺ /Al ³⁺ From 3.0 to 8.0, cu being more preferable ²⁺ /Al ³⁺ 4.0 to 7.0.

Ln ³⁺ (Ln ³⁺ Is La (La) ³⁺ 、Gd ³⁺ 、Y ³⁺ One or more of (a) is advantageous in improving the visible light transmittance and near infrared absorption properties of the glass, improving the chemical stability and hardness of the glass, and if the content exceeds 8%, the crystallization resistance of the glass becomes poor. Thus, the Ln of the present invention ³⁺ The content of (2) is greater than 0 but less than or equal to 8%, preferably 0.1 to 6%, more preferably 0.5 to 4%. Y is Y ³ ⁺ In glass compared with La ³⁺ And Gd ³⁺ More advantageously, the desired spectral characteristics of the present invention are obtained, and therefore Y is preferred ³⁺ The content of (2) is 0 to 6%, more preferably 0.1 to 5%, still more preferably 0.5 to 3%; preferably La ³⁺ The content of (2) is 0 to 5%, more preferably 0 to 3%, still more preferably 0 to 2%; preferably Gd ³⁺ The content of (2) is 0 to 5%, more preferably 0 to 3%, still more preferably 0 to 2%.

In some embodiments, al ³⁺ Content of (3) and Ln ³⁺ Ratio Al between the contents of (C) ³⁺ /Ln ³⁺ The Young's modulus and the abrasion degree of the glass are controlled to be more than 0.2, which is favorable for obtaining proper Young's modulus and abrasion degree of the glass. Therefore, al is preferable ³⁺ /Ln ³⁺ Is not less than 0.2 of the total weight of the composition,more preferably Al ³⁺ /Ln ³⁺ From 0.2 to 20.0, al being more preferred ³⁺ /Ln ³⁺ 0.5 to 15.0. Further, al is added to ³⁺ /Ln ³⁺ The temperature is controlled within the range of 1.0-10.0, which is beneficial to the glass to obtain higher hardness and prevents the transition temperature of the glass from rising. Therefore, al is more preferable ³⁺ /Ln ³⁺ From 1.0 to 10.0, and even more preferably Al ³⁺ /Ln ³⁺ 1.5 to 8.0.

Rn ⁺ (Rn ⁺ Is Li ⁺ 、Na ⁺ 、K ⁺ One or more of them) can lower the melting temperature and viscosity of the glass and promote more Cu to Cu ²⁺ Exists in the state of (C), but with Rn ⁺ The chemical stability of the glass is deteriorated by the increase. In the invention, more than 5% of Rn is introduced ⁺ To obtain the above properties, but when Rn ⁺ The content of (2) exceeds 25%, the devitrification resistance of the glass is lowered, the molding property of the glass is deteriorated, and the thermal expansion coefficient is increased. Thus, rn in the present invention ⁺ The content of (2) is 5 to 25%, preferably 7 to 20%, more preferably 10 to 17%.

Li ⁺ Can reduce the melting temperature and viscosity of the glass, improve the visible light transmittance of the glass, and simultaneously has better contribution to chemical stability than Na ⁺ And K ⁺ In the present invention, li is preferably contained in an amount of 5% or more ⁺ . But when Li ⁺ The content exceeds 25%, and the devitrification resistance and the moldability of the glass are lowered. Thus Li ⁺ The lower limit of the content of (2) is preferably 5%, the lower limit is more preferably 8%, the lower limit is more preferably 10%, li ⁺ The upper limit of the content of (2) is preferably 25%, more preferably 20%, and still more preferably 16%.

Na ⁺ Is a component for improving glass meltability. In the present invention, na is used as a catalyst ⁺ The content of (2) is 10% or less, and the glass chemical stability is improved and the weather resistance and the processability are prevented from being lowered. Preferably Na ⁺ The content of (2) is 5% or less, more preferably Na ⁺ The content of (2) is not more than 2%.

K ⁺ Can improve the transmittance of glass in the visible light region, and when the content exceeds 10%, the glass is stableQualitative degradation and chemical strengthening performance degradation. Thus, K is ⁺ The content of (2) is 10% or less, preferably K ⁺ The content of (C) is 5% or less, more preferably K ⁺ The content of (2) is not more than 2%.

R ²⁺ (R ²⁺ Is Mg ²⁺ 、Ca ²⁺ 、Sr ²⁺ 、Ba ²⁺ One or more of) can be used to reduce the melting temperature and coefficient of thermal expansion of the glass, improve the glass forming stability and strength of the glass, but when R ²⁺ The content of (2) exceeds 18%, and the devitrification resistance of the glass decreases. R in the invention ²⁺ The content of (2) is 1 to 18%, preferably 3 to 16%, more preferably 5 to 14%.

In some embodiments, by controlling P ⁵⁺ /R ²⁺ In the range of 3.0-30.0, the chemical stability of the glass is improved, and the density and the thermal expansion coefficient of the glass are reduced. Therefore, preference is given to P ⁵⁺ /R ²⁺ From 3.0 to 30.0, more preferably P ⁵⁺ /R ²⁺ P is more preferably 3.5 to 25.0 ⁵⁺ /R ²⁺ From 4.0 to 20.0, more preferably P ⁵⁺ /R ²⁺ 5.0 to 10.0.

Mg ²⁺ Can lower the melting temperature of the glass, improve the processing performance of the glass, and if the content exceeds 15 percent, the crystallization resistance of the glass is reduced, thus Mg ²⁺ The content of (2) is 15% or less, preferably Mg ²⁺ The content of (C) is 0.5-10%, more preferably Mg ²⁺ The content of (2-8%).

In some embodiments, li ⁺ /(Mg ²⁺ +Al ³⁺ ) The value of (2) is controlled within the range of 0.4-10.0, so that the glass has excellent transmittance in the visible light range, the near infrared absorption of the glass is improved, and the rise of the density and the thermal expansion coefficient of the glass is prevented. Therefore, li is preferred ⁺ /(Mg ²⁺ +Al ³⁺ ) From 0.4 to 10.0, more preferably Li ⁺ /(Mg ²⁺ +Al ³⁺ ) From 0.6 to 7.0, li being more preferred ⁺ /(Mg ²⁺ +Al ³⁺ ) From 1.0 to 5.0, li being more preferred ⁺ /(Mg ²⁺ +Al ³⁺ ) 1.2 to 3.0.

By containing less than 10% Ca ²⁺ Glass canTo prevent the decrease of the crystallization resistance while reducing the high temperature viscosity, ca is preferable ²⁺ The content of (2) is 5% or less, more preferably 2% or less.

By containing less than 10% of Sr ²⁺ Can prevent the reduction of chemical stability and crystallization resistance of glass, preferably Sr ²⁺ The content of (2) is 5% or less, more preferably 2% or less.

Ba ²⁺ The transmittance of the glass in the visible light region can be improved, the glass forming stability and strength of the glass can be improved, and if the content exceeds 10%, the density of the glass is increased. In some embodiments of the invention, the method is performed by subjecting Ba to ²⁺ The content of (2) is more than 0.5%, so that the chemical stability of the glass can be improved, and the thermal expansion coefficient of the glass can be reduced. Thus, ba ²⁺ The content of (2) is 10% or less, preferably Ba ²⁺ The content of (C) is 0.5-8%, more preferably Ba ²⁺ The content of (2) is 1-6%.

In some embodiments, by letting Ln ³⁺ /(Ba ²⁺ +Al ³⁺ ) Above 0.02, the glass is beneficial to reducing the thermal expansion coefficient of the glass and preventing the transition temperature from rising. Therefore, ln is preferable ³⁺ /(Ba ²⁺ +Al ³⁺ ) More preferably Ln, of 0.02 or more ³⁺ /(Ba ²⁺ +Al ³⁺ ) Is 0.02 to 2.0, and Ln is more preferable ³⁺ /(Ba ²⁺ +Al ³⁺ ) 0.05 to 1.0. Further, by combining Ln ³⁺ /(Ba ²⁺ +Al ³⁺ ) The hardness of the glass is controlled within the range of 0.08-0.8, which is also beneficial to optimizing the hardness of the glass. Therefore, ln is more preferable ³⁺ /(Ba ²⁺ +Al ³⁺ ) From 0.08 to 0.8, ln is still more preferable ³⁺ /(Ba ²⁺ +Al ³⁺ ) 0.1 to 0.5.

B ³⁺ The glass melting temperature can be lowered, and when the content exceeds 5%, the near infrared light absorption characteristics are lowered. Thus B ³ ⁺ The content is 0 to 5%, preferably 0 to 2%, more preferably 0 to 1%, and even more preferably no B ³⁺ 。

Si ⁴⁺ Can promote the formation of glass and improve the chemical stability of glass, when the content exceeds 5%, the glass is meltedThe meltability is poor, unmelted impurities are liable to be formed in the glass, and the near infrared light absorption characteristics of the glass are liable to be lowered. Thus Si is ⁴⁺ The content of (C) is 0 to 5%, preferably 0 to 2%, more preferably 0 to 1%, and even more preferably Si-free ⁴⁺ 。

Zn ²⁺ Can lower the glass transition temperature, improve the thermal stability of the glass, and when the content exceeds 10%, the glass is reduced in devitrification resistance, thus Zn ²⁺ The content is limited to 10% or less, preferably 5% or less, and more preferably 2% or less. In some embodiments, it is further preferred that Zn is not contained ²⁺ 。

Zr ⁴⁺ The chemical stability of the glass can be improved, but if the content exceeds 5%, the melting property of the glass is significantly reduced and the crystallization resistance is lowered. Thus, zr ⁴⁺ The content is limited to 0 to 5%, preferably 0 to 2%, more preferably 0 to 1%, and the one-step preferably does not contain Zr ⁴⁺ 。

Sb ³⁺ 、Sn ⁴⁺ 、Ce ⁴⁺ One or more components of the glass can be used as a clarifying agent to improve the clarifying effect of the glass, improve the bubble degree grade of the glass and Sb ³⁺ 、Sn ⁴⁺ 、Ce ⁴⁺ The content of the components alone or in total is 0 to 1%, preferably 0 to 0.5%, more preferably 0 to 0.1%.

< anionic component >

O ^2- Is an important anion component in the glass, can stabilize a network structure, form stable glass, and can ensure Cu ions in the glass to be Cu ²⁺ The glass is in the form of a glass, so that the characteristic of absorbing light rays in the near infrared region is ensured. If O ^2- If the content of (C) is too small, it is difficult to form a stable glass, and Cu ²⁺ Is easily reduced to Cu ⁺ The effect of absorbing light in the near infrared region is not achieved; but O is ^2- When the content of (B) is too high, the smelting temperature of the glass is higher, so that the spectral transmittance in the visible light region is obviously reduced, and the requirements are not met. Thus, O is ^2- The content of (2) is limited to 85 to 99.5%, preferably 88 to 99%, and more preferably 91 to 98%.

F ^- The glass melting temperature can be reduced, the visible light transmittance of the glass can be improved, the viscosity of the glass can be reduced, and proper amount of glass is favorable for improving the crystallization resistance of the glass. If F ^- The content exceeds 15%, the stability of the glass is reduced, the glass is easy to volatilize in the melting process, the environment is polluted, and the glass is easy to form stripes. Thus F ^- The content of (2) is limited to 0.5 to 15%, preferably 1 to 12%, more preferably 2 to 9%.

In some embodiments, by controlling Ln ³⁺ /F ^- At 0.01 or more, the near infrared absorption performance of the glass can be improved, and the glass transition temperature can be prevented from rising. Therefore, ln is preferable ³⁺ /F ^- More preferably Ln, of 0.01 or more ³⁺ /F ^- Is 0.02 to 10.0, and Ln is more preferable ³⁺ /F ^- 0.05 to 5.0. Further, by controlling Ln ³⁺ /F ^- In the range of 0.05 to 2.0, the glass can be given a suitable Young's modulus. Therefore, ln is more preferable ³⁺ /F ^- From 0.05 to 2.0, ln is still more preferable ³⁺ /F ^- 0.1 to 1.0.

In some embodiments, by controlling F ^- /Cu ²⁺ In the range of 0.05 to 2.0, the glass can obtain a suitable Young's modulus and a lower coefficient of thermal expansion. Therefore, F is preferred ^- /Cu ²⁺ From 0.05 to 2.0, more preferably F ^- /Cu ²⁺ F is more preferably 0.1 to 1.5 ^- /Cu ²⁺ F is more preferably 0.2 to 1.0 ^- /Cu ²⁺ 0.3 to 0.8.

Cl ^- 、Br ^- 、I ^- One or more components of the glass can be used as a clarifying agent to improve the clarifying effect of the glass, improve the bubble degree grade of the glass and Cl ^- 、Br ^- 、I ^- The content of the components alone or in total is 0 to 2%, preferably 0 to 1%, more preferably 0 to 0.5%.

< non-contained component >

V, cr, mn, fe, co, ni, ag and Mo, etc., and even when they are contained in small amounts alone or in combination, the spectral transmittance of the glass is disturbed, which is disadvantageous in forming the near infrared light absorbing glass of the present invention, and therefore, it is preferable that the above components are not contained.

As, pb, th, cd, tl, os, be and Se components have been used as harmful chemicals in recent years, and are required to be environmentally friendly not only in the glass manufacturing process but also in the processing process and disposal after production. Therefore, in the case where the influence on the environment is emphasized, it is preferable that they are not substantially contained except for unavoidable mixing. Thus, the glass becomes practically free from environmental pollutants. Therefore, the glass of the present invention can be manufactured, processed, and discarded without taking special measures against the environment.

The term "free of" and "0%" as used herein means that the component is not intentionally added as a raw material to the near infrared light absorbing glass of the present invention; however, it is also within the scope of the present invention that certain other impurities or components may be present as raw materials and/or equipment for producing the glass that are not intentionally added, may be present in small or trace amounts in the final near infrared light absorbing glass.

[ method of production ]

The manufacturing method of the near infrared light absorbing glass comprises the following steps: the glass is produced by adopting conventional raw materials and conventional processes, using carbonate, nitrate, phosphate, metaphosphate, sulfate, hydroxide, oxide, fluoride and the like as raw materials, proportioning according to the conventional method, adding the prepared furnace charge into a smelting furnace at 700-1000 ℃ for smelting, clarifying, stirring and homogenizing to obtain homogeneous molten glass without bubbles and undissolved substances, and casting and annealing the molten glass in a mould. Those skilled in the art can appropriately select the raw materials, the process methods, and the process parameters according to actual needs.

The near infrared light absorbing glass of the present invention can also be molded by a well-known method. In some embodiments, the near infrared light absorbing glass described herein can be manufactured into shaped bodies including, but not limited to, sheets by various processes including, but not limited to, slot draw, float, roll, and other sheet forming processes known in the art. Alternatively, the glass may be formed by float or roll processes as are known in the art.

The near-infrared light absorbing glass of the present invention can be a glass molded body of a sheet produced by a method such as grinding or polishing, but the method for producing the glass molded body is not limited to these methods.

The near infrared light absorbing glass of the present invention can have any thickness that is reasonably useful.

Next, the performance of the near infrared light absorbing glass of the present invention will be described.

< transition temperature >

Glass transition temperature (T) _g ) The test was carried out according to the method specified in GB/T7962.16-2010.

In some embodiments, the near infrared light absorbing glass of the present invention has a transition temperature (T _g ) The temperature is 410℃or lower, preferably 400℃or lower, more preferably 390℃or lower, and still more preferably 370 to 390 ℃.

< Density >

The density (ρ) of the glass was tested according to the method specified in GB/T7962.20-2010.

In some embodiments, the near infrared light absorbing glass of the present invention has a density (ρ) of 3.3g/cm ³ Hereinafter, it is preferably 3.2g/cm ³ Hereinafter, it is more preferably 3.1g/cm ³ Hereinafter, it is more preferably 3.0g/cm ³ The following is given.

< coefficient of thermal expansion >

Coefficient of thermal expansion (alpha) of glass _20-120 DEG C) was tested according to the method specified in GB/T7962.16-2010.

In some embodiments, the near infrared light absorbing glass of the present invention has a coefficient of thermal expansion (α _20-120℃ ) 110X 10 ^-7 Preferably 100X 10, and K is less than or equal to ^-7 Preferably not more than/K, more preferably 95X 10 ^-7 and/K or below.

< hardness >

Hardness of glass (H) _v ) The following method is adopted for testing: the diamond quadrangular pyramid with 136-degree included angle between opposite surfaces is used for pressingThe load (N) when a pyramid-shaped depression is pressed into the test surface is divided by the surface area (mm) calculated by the length of the depression ² ) Is represented by a value of (a). The test load was 100 (N) and the holding time was 15 (seconds).

In some embodiments, the hardness (H _v ) 380kgf/mm ² Above, preferably 390kgf/mm ² The above is more preferably 400kgf/mm ² The above is more preferably 410kgf/mm ² The above.

< Young's modulus >

Young's modulus (E) of the glass is obtained by testing longitudinal wave speed and transverse wave speed by adopting ultrasonic waves and then calculating according to the following formula.

Wherein, in the formula:

e is Young's modulus, pa;

g is the shear modulus, pa;

V _T is transverse wave speed, m/s;

V _S is longitudinal wave speed, m/s;

ρ is the density of the glass, g/cm ³ 。

In some embodiments, the near infrared light absorbing glass of the present invention has a Young's modulus (E) lower limit of 5500X 10 ⁷ Preferably, the lower limit of the ratio is 6000X 10 ⁷ Preferably, the lower limit of the ratio is 6500X 10 ⁷ The upper limit of Young's modulus (E) is 8500X 10 ⁷ Preferably, the upper limit of the ratio is 8000X 10 ⁷ The upper limit of the ratio to the total of the ratio is 7500X 10 ⁷ /Pa。

< spectral transmittance >

The spectral transmittance of the glass of the present invention refers to the value obtained by spectrophotometry in the manner described: assuming that the glass sample has two planes parallel to each other and optically polished, light is perpendicularly incident from one parallel plane and exits from the other parallel plane, and the intensity of the exiting light divided by the intensity of the incident light is the transmittance, which is also referred to as the external transmittance.

In some embodiments, when the near infrared light absorbing glass has a thickness of 0.5mm or less, the spectral transmittance has the characteristics shown below:

spectral transmittance at 400nm wavelength (τ ₄₀₀ ) The content is 80.0% or more, preferably 82.0% or more, and more preferably 84.0% or more.

Spectral transmittance at 500nm wavelength (τ ₅₀₀ ) 83.0% or more, preferably 85.0% or more, more preferably 88.0% or more

Spectral transmittance at 1100nm wavelength (τ ₁₁₀₀ ) The content is 10.0% or less, preferably 7.0% or less, more preferably 5.0% or less, and even more preferably 3.0% or less.

In some embodiments, when the near infrared light absorbing glass has a thickness of 0.5mm or less, the spectral transmittance in the wavelength range of 500 to 700nm is 50% at the corresponding wavelength (λ ₅₀ ) The wavelength is 635nm or less, preferably 600 to 630nm, more preferably 610 to 625nm.

In the above spectral transmittance test, the thickness of the near infrared light absorbing glass is preferably 0.05 to 0.4mm, more preferably 0.1 to 0.3mm, still more preferably 0.1mm or 0.15mm or 0.2mm or 0.25mm.

[ near-infrared light absorbing glass element ]

The near-infrared light absorbing glass element according to the present invention contains the above-mentioned near-infrared light absorbing glass, and examples thereof include a thin plate-like glass element or lens used in a near-infrared light absorbing filter, and is suitable for use in color correction of a solid-state image pickup device, and has various excellent properties of the above-mentioned glass.

The thickness of the near infrared light absorbing glass element (the interval between the incident surface and the emission surface of the transmitted light) is determined by the transmittance characteristics of the element, and is preferably 0.05 to 0.4mm, more preferably 0.1 to 0.3mm, still more preferably 0.1mm or 0.15mm or 0.2mm or 0.25mm, and the corresponding wavelength (lambda) when the transmittance reaches 50% in the spectral transmittance in the wavelength range of 500 to 700nm ₅₀ ) The wavelength is 635nm or less, preferably 600 to 630nm, more preferably 610 to 625nm. To obtain such a near infrared light absorbing glass elementThe composition of the glass was adjusted to produce a device having the above-mentioned spectral characteristic thickness.

[ Filter ]

The optical filter according to the present invention is a near-infrared filter comprising the near-infrared light absorbing glass or the near-infrared light absorbing glass element, and is provided with a near-infrared light absorbing element comprising the near-infrared light absorbing glass having both surfaces optically polished, and the color correction function of the optical filter is imparted by such an element, and also has various excellent properties of the glass.

[ Equipment ]

The near infrared light absorbing glass, or the near infrared light absorbing glass element, or the optical filter of the present invention can be manufactured by a well-known method into devices such as portable communication devices (e.g., mobile phones), smart wearable devices, photographic devices, image pickup devices, display devices, and monitoring devices.

Examples

< near-infrared light absorbing glass example >

In order to further clearly illustrate and describe the technical solutions of the present invention, the following non-limiting examples are provided.

In this example, glasses having compositions shown in tables 1 to 3 were obtained by using the above-described method for producing near infrared light absorbing glass. The characteristics of each near infrared light absorbing glass were measured by the test method of the present invention, and the measurement results are shown in tables 1 to 3.

Table 1.

Table 2.

/>

Table 3.

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The near infrared light absorbing glasses prepared in the examples described in tables 1 to 3 above were processed into glass sheets having a thickness of 0.2mm, and the spectral transmittance of each example near infrared light absorbing glass was measured according to the test method described above, and the results are shown in tables 4 to 6 below.

Table 4.

Table 5.

Examples	9#	10#	11#	12#	13#	14#	15#	16#
									τ ₄₀₀ (％)	86.7	86.5	86.2	87.0	86.3	85.2	85.7	86.0
τ ₅₀₀ (％)	89.5	89.3	89.0	90.2	89.1	88.3	88.6	88.3
									τ ₁₁₀₀ (％)	1.5	1.3	1.6	1.2	1.7	2.1	1.8	2.1
λ ₅₀ (nm)	620	618	624	618	625	628	627	626

Table 6.

Examples	17#	18#	19#	20#	21#	22#	23#	24#
									τ ₄₀₀ (％)	85.9	86.0	86.8	87.1	85.8	86.2	86.1	86.3
τ ₅₀₀ (％)	88.7	88.8	89.8	90.3	88.9	88.9	89.1	89.3
									τ ₁₁₀₀ (％)	2.0	1.6	1.4	1.2	2.0	1.7	1.9	1.8
λ ₅₀ (nm)	625	625	619	620	625	623	624	625

< near-infrared light absorbing glass element example >

The near infrared light absorbing glass of examples 1 to 24 described above was produced into a near infrared light absorbing glass element by a method known in the art, and examples thereof include a thin plate-like near infrared light absorbing glass element or lens used in a near infrared light absorbing filter, and the like, and the glass is suitable for use in color correction of a solid-state imaging device and has various excellent properties.

< Filter example >

The near infrared light absorbing glass and/or the near infrared light absorbing glass element of examples 1 to 24# described above were made into filters by methods known in the art, and the filters of the present invention had a color correction function while also having various excellent properties of the above-described glasses.

< device example >

The near infrared light absorbing glass and/or near infrared light absorbing glass element and/or the optical filter of the present invention can be manufactured by well-known methods into devices such as portable communication devices (e.g., mobile phones), smart wearable devices, photographic devices, image pickup devices, display devices, and monitoring devices. But also for imaging devices, sensors, microscopes, medical technology, digital projection, optical communication technology/information transmission, or for imaging devices and apparatuses in the field of vehicle mounting, for example.

Claims

1. A near infrared light absorbing glass comprising P in the composition ⁵⁺ 、Cu ²⁺ 、Rn ⁺ 、R ²⁺ And Ln ³⁺ The cationic component contains, in mole percent: p (P) ⁵⁺ ：51～72％；Cu ²⁺ ：5～25％；Rn ⁺ ：5～25％；R ²⁺ ：1～18％；Ln ³⁺ : greater than 0 but less than or equal to 8%; al (Al) ³⁺ :0 to 10 percent, wherein Li ⁺ /(Mg ²⁺ +Al ³⁺ ) Is 0.4 to 10.0 percent,does not contain V, the Rn ⁺ Is Li ⁺ 、Na ⁺ 、K ⁺ One or more of R ²⁺ Is Mg ²⁺ 、Ca ²⁺ 、Sr ²⁺ 、Ba ²⁺ One or more of Ln ³⁺ Is La (La) ³⁺ 、Gd ³⁺ 、Y ³ ⁺ One or more of the following; the anionic component contains: f (F) ^- : 0.5-15%; a transmittance τ at 400nm of a near infrared light absorbing glass having a thickness of 0.5mm or less ₄₀₀ A transmittance τ at 500nm of 80.0% or more ₅₀₀ A transmittance τ at 1100nm of 83.0% or more ₁₁₀₀ Is 10.0% or less.

2. The near infrared light absorbing glass according to claim 1, wherein the near infrared light absorbing glass having a thickness of 0.5mm or less has a transmittance τ at 400nm ₄₀₀ 82.0% or more; and/or a transmittance τ at 500nm ₅₀₀ 85.0% or more; and/or transmittance τ at 1100nm ₁₁₀₀ Is 7.0% or less.

3. The near infrared light absorbing glass according to claim 1, wherein the near infrared light absorbing glass having a thickness of 0.5mm or less has a transmittance τ at 400nm ₄₀₀ 84.0% or more; and/or a transmittance τ at 500nm ₅₀₀ 88.0% or more; and/or transmittance τ at 1100nm ₁₁₀₀ Is less than 5.0%.

4. The near infrared light absorbing glass according to claim 1, wherein the near infrared light absorbing glass having a thickness of 0.5mm or less has a transmittance τ at 1100nm ₁₁₀₀ Is 3.0% or less.

5. The near infrared light absorbing glass according to claim 1, wherein the cationic component contains, in mole percent: p (P) ⁵⁺ : 56-68%; and/or Cu ²⁺ : 6-20%; and/or Rn ⁺ : 7-20%; and/or R ²⁺ : 3-16%; and/or Ln ³⁺ :0.1 to 6 percent; and/or Al ³⁺ :0.5 to 8 percent, theRn ⁺ Is Li ⁺ 、Na ⁺ 、K ⁺ One or more of R ²⁺ Is Mg ²⁺ 、Ca ²⁺ 、Sr ²⁺ 、Ba ²⁺ One or more of Ln ³⁺ Is La (La) ³⁺ 、Gd ³⁺ 、Y ³⁺ One or more of the following.

6. The near infrared light absorbing glass according to claim 1, wherein the cationic component contains, in mole percent: p (P) ⁵⁺ : 60-65%; and/or Cu ²⁺ : 8-15%; and/or Rn ⁺ : 10-17%; and/or R ²⁺ : 5-14%; and/or Ln ³⁺ :0.5 to 4 percent; and/or Al ³⁺ :1 to 5 percent of Rn ⁺ Is Li ⁺ 、Na ⁺ 、K ⁺ One or more of R ²⁺ Is Mg ²⁺ 、Ca ²⁺ 、Sr ²⁺ 、Ba ²⁺ One or more of Ln ³⁺ Is La (La) ³⁺ 、Gd ³⁺ 、Y ³⁺ One or more of the following.

7. The near infrared light absorbing glass according to claim 1, wherein the cationic component further comprises, in mole percent: zn (zinc) ²⁺ : 0-10%; and/or Si ⁴⁺ : 0-5%; and/or B ³⁺ : 0-5%; and/or Zr ⁴⁺ : 0-5%; and/or Sb ³⁺ +Sn ⁴⁺ +Ce ⁴⁺ ：0～1％。

8. The near infrared light absorbing glass according to claim 1, wherein the cationic component further comprises, in mole percent: zn (zinc) ²⁺ : 0-5%; and/or Si ⁴⁺ :0 to 2 percent; and/or B ³⁺ :0 to 2 percent; and/or Zr ⁴⁺ :0 to 2 percent; and/or Sb ³⁺ +Sn ⁴⁺ +Ce ⁴⁺ ：0～0.5％。

9. The near infrared light absorbing glass according to claim 1, wherein the cation is represented by mole percentThe components also contain: zn (zinc) ²⁺ :0 to 2 percent; and/or Si ⁴⁺ :0 to 1 percent; and/or B ³⁺ :0 to 1 percent; and/or Zr ⁴⁺ :0 to 1 percent; and/or Sb ³⁺ +Sn ⁴⁺ +Ce ⁴⁺ ：0～0.1％。

10. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the components thereof, expressed in mole percent, satisfy one or more of the following 5 cases:

1)Al ³⁺ /Ln ³⁺ is more than 0.2;

2)Li ⁺ /(Mg ²⁺ +Al ³⁺ ) 0.6 to 7.0;

3)Cu ²⁺ /Al ³⁺ 1.0 to 15.0;

4)Ln ³⁺ /(Ba ²⁺ +Al ³⁺ ) Is 0.02 or more;

5)P ⁵⁺ /R ²⁺ 3.0 to 30.0.

11. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the components thereof, expressed in mole percent, satisfy one or more of the following 5 cases:

1)Al ³⁺ /Ln ³⁺ 0.2 to 20.0;

2)Li ⁺ /(Mg ²⁺ +Al ³⁺ ) 1.0 to 5.0;

3)Cu ²⁺ /Al ³⁺ 2.0 to 10.0;

4)Ln ³⁺ /(Ba ²⁺ +Al ³⁺ ) 0.02 to 2.0;

5)P ⁵⁺ /R ²⁺ 3.5 to 25.0.

12. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the components thereof, expressed in mole percent, satisfy one or more of the following 5 cases:

1)Al ³⁺ /Ln ³⁺ 0.5 to 15.0;

2)Li ⁺ /(Mg ²⁺ +Al ³⁺ ) 1.2 to 3.0；

3)Cu ²⁺ /Al ³⁺ 3.0 to 8.0;

4)Ln ³⁺ /(Ba ²⁺ +Al ³⁺ ) 0.05 to 1.0;

5)P ⁵⁺ /R ²⁺ 4.0 to 20.0.

13. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the components thereof, expressed in mole percent, satisfy one or more of the following 4 cases:

1)Al ³⁺ /Ln ³⁺ 1.0 to 10.0;

2)Cu ²⁺ /Al ³⁺ 4.0 to 7.0;

3)Ln ³⁺ /(Ba ²⁺ +Al ³⁺ ) 0.08 to 0.8;

4)P ⁵⁺ /R ²⁺ 5.0 to 10.0.

14. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the components thereof, expressed in mole percent, satisfy one or more of the following 2 cases:

1)Al ³⁺ /Ln ³⁺ 1.5 to 8.0;

2)Ln ³⁺ /(Ba ²⁺ +Al ³⁺ ) 0.1 to 0.5.

15. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein, expressed in mole percent, wherein: li (Li) ⁺ : 5-25%; and/or Na ⁺ : 0-10%; and/or K ⁺ : 0-10%; and/or Mg ²⁺ : 0-15%; and/or Ca ² ⁺ : 0-10%; and/or Sr ²⁺ : 0-10%; and/or Ba ²⁺ : 0-10%; and/or La ³⁺ : 0-5%; and/or Gd ³⁺ : 0-5%; and/or Y ³⁺ ：0～6％。

16. The near infrared light absorbing glass according to any one of claims 1 to 9, characterized by comprisingExpressed in mole percent, wherein: li (Li) ⁺ : 8-20%; and/or Na ⁺ : 0-5%; and/or K ⁺ : 0-5%; and/or Mg ²⁺ : 0.5-10%; and/or Ca ² ⁺ : 0-5%; and/or Sr ²⁺ : 0-5%; and/or Ba ²⁺ : 0.5-8%; and/or La ³⁺ :0 to 3 percent; and/or Gd ³⁺ :0 to 3 percent; and/or Y ³⁺ ：0.1～5％。

17. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein, expressed in mole percent, wherein: li (Li) ⁺ : 10-16%; and/or Na ⁺ :0 to 2 percent; and/or K ⁺ :0 to 2 percent; and/or Mg ²⁺ : 2-8%; and/or Ca ²⁺ :0 to 2 percent; and/or Sr ²⁺ :0 to 2 percent; and/or Ba ²⁺ :1 to 6 percent; and/or La ³⁺ :0 to 2 percent; and/or Gd ³⁺ :0 to 2 percent; and/or Y ³⁺ ：0.5～3％。

18. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the anionic component contains, in mole percent: o (O) ^2- ：85～99.5％。

19. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the anionic component contains, in mole percent: o (O) ^2- : 88-99 percent; and/or F ^- ：1～12％。

20. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the anionic component contains, in mole percent: o (O) ^2- : 91-98%; and/or F ^- ：2～9％。

21. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the components thereof are expressed in mole percent, wherein: ln (Ln) ³⁺ /F ^- Is more than 0.01The method comprises the steps of carrying out a first treatment on the surface of the And/or F ^- /Cu ²⁺ 0.05 to 2.0.

22. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the components thereof are expressed in mole percent, wherein: ln (Ln) ³⁺ /F ^- 0.02 to 10.0; and/or F ^- /Cu ²⁺ 0.1 to 1.5.

23. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the components thereof are expressed in mole percent, wherein: ln (Ln) ³⁺ /F ^- 0.05 to 5.0; and/or F ^- /Cu ²⁺ 0.2 to 1.0.

24. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the components thereof are expressed in mole percent, wherein: ln (Ln) ³⁺ /F ^- 0.05 to 2.0; and/or F ^- /Cu ²⁺ 0.3 to 0.8.

25. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the components thereof are expressed in mole percent, wherein: ln (Ln) ³⁺ /F ^- 0.1 to 1.0.

26. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the anionic component further comprises, in mole percent: cl ^- +Br ^- +I ^- ：0～2％。

27. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the anionic component further comprises, in mole percent: cl ^- +Br ^- +I ^- ：0～1％。

28. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the components thereof are expressed in mole percent,the anionic component also contains: cl ^- +Br ^- +I ^- ：0～0.5％。

29. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the near infrared light absorbing glass has a transition temperature T _g Is below 410 ℃; and/or density ρ of 3.3g/cm ³ The following are set forth; and/or coefficient of thermal expansion alpha _20-120℃ 110X 10 ^-7 and/K or below; and/or hardness H _v 380kgf/mm ² The above; young's modulus E of 5500X 10 ⁷ ～8500×10 ⁷ Pa。

30. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the near infrared light absorbing glass has a transition temperature T _g Is below 400 ℃; and/or density ρ of 3.2g/cm ³ The following are set forth; and/or coefficient of thermal expansion alpha _20-120℃ 100X 10 ^-7 and/K or below; and/or hardness H _v Is 390kgf/mm ² The above; young's modulus E of 6000×10 ⁷ ～8000×10 ⁷ Pa。

31. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the near infrared light absorbing glass has a transition temperature T _g Is below 390 ℃; and/or density ρ of 3.1g/cm ³ The following are set forth; and/or coefficient of thermal expansion alpha _20-120℃ 95X 10 ^-7 and/K or below; and/or hardness H _v 400kgf/mm ² The above; young's modulus E of 6500×10 ⁷ ～7500×10 ⁷ Pa。

32. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the near infrared light absorbing glass has a transition temperature T _g 370-390 ℃; and/or density ρ of 3.0g/cm ³ The following are set forth; and/or hardness H _v 410kgf/mm ² The above.

33. According to any one of claims 1 to 9A near-infrared light absorbing glass characterized by having a thickness of 0.5mm or less and a spectral transmittance in a wavelength range of 500 to 700nm of a wavelength lambda corresponding to a transmittance of 50% ₅₀ 635nm or less.

34. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the near infrared light absorbing glass has a thickness of 0.5mm or less, and has a spectral transmittance in a wavelength range of 500 to 700nm of a wavelength λ corresponding to a transmittance of 50% ₅₀ 600-630 nm.

35. The near infrared light absorbing glass according to any one of claims 1 to 9, wherein the near infrared light absorbing glass has a thickness of 0.5mm or less, and has a spectral transmittance in a wavelength range of 500 to 700nm of a wavelength λ corresponding to a transmittance of 50% ₅₀ 610-625 nm.

36. The near infrared light absorbing glass according to claim 33, wherein the thickness of the near infrared light absorbing glass is 0.05 to 0.4mm.

37. The near infrared light absorbing glass according to claim 33, wherein the thickness of the near infrared light absorbing glass is 0.1 to 0.3mm.

38. The near infrared light absorbing glass according to claim 33, wherein the thickness of the near infrared light absorbing glass is 0.1mm or 0.15mm or 0.2mm or 0.25mm.

39. The near infrared light absorbing glass according to any one of claims 1 to 4, wherein the thickness of the near infrared light absorbing glass is 0.05 to 0.4mm.

40. The near infrared light absorbing glass according to any one of claims 1 to 4, wherein the thickness of the near infrared light absorbing glass is 0.1 to 0.3mm.

41. The near infrared light absorbing glass according to any one of claims 1 to 4, wherein the thickness of the near infrared light absorbing glass is 0.1mm or 0.15mm or 0.2mm or 0.25mm.

42. A near-infrared light absorbing glass member comprising the near-infrared light absorbing glass according to any one of claims 1 to 41.

43. A filter comprising the near infrared light absorbing glass according to any one of claims 1 to 41 or the near infrared light absorbing glass element according to claim 42.

44. An apparatus comprising the near infrared light absorbing glass of any one of claims 1 to 41, or comprising the near infrared light absorbing glass element of claim 42, or comprising the optical filter of claim 43.