DE102007009174A1 - Radiation converter comprises a fluorescent layer from needle-shaped crystals on a substrate, where reflecting metal is incorporated in between the needle-shaped crystals - Google Patents

Abstract

Radiation converter (I) comprises a fluorescent layer from needle-shaped crystals on a substrate, where a reflecting metal is incorporated in between the needle-shaped crystals. An independent claim is included for the preparation of the radiation converter comprising applying the fluorescent layer from needle-shaped crystals on a substrate and evaporating the needle-shaped crystal reflecting metal.

Description

The The invention relates to a radiation converter in which on a substrate a phosphor layer formed of acicular crystals is applied. The invention further relates to a method for the production of a radiation converter in which on a substrate a phosphor layer formed of acicular crystals is applied.

Such a radiation converter is used in a digital X-ray detector (Flat Panel Detector) in combination with an active matrix, which is subdivided into a plurality of pixel readout units with photodiodes. The incident X-radiation is first converted into visible light in the phosphor layer (scintillator layer) of the radiation converter, which is converted by the photodiodes into electrical charge and stored spatially resolved. This so-called indirect conversion is for example in the article of M. Spahn et al. "Flat-panel Detectors in X-Ray Diagnostics" in "The Radiologist 43 (2003)", pages 340 to 350 , described.

usual Scintillator layers consist of CsI: Tl, CsI: Na, NaI: Tl or similar Materials containing alkali halides, with CsI being particularly good as a scintillator material as it is acicular can be raised. This gives you despite high Layer thickness, which is an optimal absorption of X-rays ensures a good spatial resolution of the x-ray image. The good spatial resolution results from the so-called "Optical diffusion".

task The invention is a radiation converter with improved light properties to accomplish. The invention is further based on the object a method for producing a radiation transducer with improved Specify light properties.

The The object is achieved by a radiation converter according to claim 1 and by a method according to claim 8 solved. Advantageous embodiments of the radiation converter according to the invention and the method according to the invention are respectively Subject of further claims.

Of the Radiation converter according to claim 1 comprises a Substrate on which a needle-shaped crystals formed Phosphor layer is applied. According to the invention in the spaces between the needle-shaped crystals a reflective metal introduced.

The The method according to claim 8 according to the invention Production of a radiation converter in which on a substrate a phosphor layer formed of acicular crystals is applied, is characterized in that during vapor deposition added to the acicular crystals reflecting metal becomes.

at the radiation converter according to claim 1 is by the reflecting metal introduced into the interspaces a lateral propagation of the generated in the phosphor layer Scintillator light greatly reduced, causing the MTF (modulation Transfer function) is improved accordingly. This is with conventional photosensitive sensors, such as photodiodes and CCDs, an improved Resolution achievable.

at the method according to claim claim 8, a phosphor layer is added by the addition of a specular metal created in which a lateral spread of in the phosphor layer produced scintillator light is greatly reduced. One according to the Method according to claim 8 produced radiation converter has compared with known radiation converters an improved MTF (modulation transfer function) on, so with such a Radiation converter in conventional photosensitive Sensors, such as photodiodes and CCDs, improved resolution is achievable.

These it is the material from which the phosphor layer is made and which is also referred to as scintillator material, for example the alkali halide CsI: Tl (with Tl doped CsI), then this is Material at least slightly hygroscopic. The added reflective Metal should therefore not be corrosive and may be applied to the scintillator material also not corrosive. Furthermore, the reflective metal must for manufacturing reasons its liquid Aggregate state at about 640 ° C own.

The Addition of the reflective metal is preferably anhydrous. This is the CVD method (CVD - Chemical Vapor Deposition, chemical Vapor deposition) contamination of the vacuum by water of crystallization prevented.

As a reflective metal tin (II) chloride is used according to a particularly advantageous embodiment of the radiation converter according to the invention or the method according to the invention, wherein the proportion of tin (II) chloride is preferably about 0.5 wt .-%. By adding about 0.5% by weight of tin (II) chloride, a lateral spread of the scintillator light generated in the phosphor layer is particularly greatly reduced. As a result, the crude MTF increases from approximately 55% to approximately 80%. Under raw MTF, the MTF is an unprotected phosphor layer, ie a phosphor layer without protection influencing the MTF shift, to understand.

following are in the single figure normalized emission spectra of three Phosphor layers (scintillator layers) are shown.

With 1 In this case, an emission spectrum of a phosphor layer (area 13 cm × 13 cm) denotes, which according to an advantageous embodiment of the invention from the Alkalihalo genid CsI: Tl [thallium (Tl) doped cesium iodide (CsI)] with an addition of about 0, 5 wt .-% SnCl ₂ [stannous chloride].

One with 2 The emission spectrum referred to refers to a phosphor layer (area 20 cm × 25 cm) of CsI: Tl, which, however, contains no SnCl ₂ .

Another emission spectrum that with 3 refers to a phosphor layer (area 20 cm × 25 cm) made of CsI: Tl, which is mixed with a UV-curing epoxy resin, whereby a yellow coloration of the scintillator material CsI: Tl is prevented.

As from a comparison of the three emission spectra readily apparent is, are the emission maxima of the three aforementioned phosphor layers generated light in the range of 510 nm to 520 nm and thus in the range the maximum sensitivity of photodiodes and CCDs (Charge Coupled Devices), which is in the range of about 500 nm to 520 nm.

The addition of 0.5% by weight of SnCl ₂ to improve the MTF thus does not lead to a shift of the emission maximum in regions outside the maximum sensitivity of photodiodes and CCDs (about 500 nm to 520 nm) for the scintillator material CsI: Tl. A loss of luminous efficacy, which would have to be compensated by an undesirable increase in the dose, thus occurs in a radiation converter whose scintillator material is the emission spectrum 1 owns, not one.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited non-patent literature

• M. Spahn et al. "Flat Panel Detectors in X-Ray Diagnostics" in "The Radiologist 43 (2003)", pages 340 to 350 [0002]

Claims (12)

A radiation converter in which a phosphor layer formed from needle-shaped crystals is applied to a substrate, characterized in that a reflecting metal is introduced into the spaces between the needle-shaped crystals. Radiation converter according to Claim 1, characterized that the reflective metal is metallic tin (Sn). Radiation converter according to claim 1, characterized in that the reflective metal is tin (II) chloride (SnCl ₂ ). Radiation converter according to claim 1, characterized in that the specular metal is tin (II) iodide (SnI ₂ ). Radiation converter according to claim 3, characterized in that the proportion of tin (II) chloride (SnCl ₂ ) is 0.5 wt .-%. Radiation converter according to Claim 1, characterized that the phosphor layer of thallium-doped cesium iodide (CsI: Tl) exists. Radiation converter according to Claim 1, characterized that the phosphor layer of sodium-doped cesium iodide (CsI: Na) exists. Method for producing a radiation converter, in which on a substrate one of acicular crystals formed phosphor layer is applied, characterized that during vapor deposition of the needle-shaped crystals reflecting metal is added. Method according to claim 8, characterized in that that metallic tin (Sn) is added as the reflective metal. A method according to claim 8, characterized in that tin (II) chloride (SnCl ₂ ) is added as the reflecting metal. A method according to claim 8, characterized in that tin (II) iodide (SnI ₂ ) is added as the reflecting metal. Method according to claim 8, characterized in that the addition of the reflective metal is anhydrous.