SCINTILLATOR PLATE, RADIATION DETECTOR, AND MANUFACTURING METHOD OF SCINTILLATOR PLATE

Organization Name

CANON KABUSHIKI KAISHA

Inventor(s)

TOMOYUKI Oike of Kanagawa (JP)

SCINTILLATOR PLATE, RADIATION DETECTOR, AND MANUFACTURING METHOD OF SCINTILLATOR PLATE - A simplified explanation of the abstract

This abstract first appeared for US patent application 18670192 titled 'SCINTILLATOR PLATE, RADIATION DETECTOR, AND MANUFACTURING METHOD OF SCINTILLATOR PLATE

Simplified Explanation: The patent application describes a scintillator plate with a columnar crystal that emits light when exposed to radiation, covered by a protective film to shield it from water vapor. The protective film has specific roughness and thickness requirements.

Key Features and Innovation:

• Scintillator plate with columnar crystal emitting light when irradiated
• Protective film to safeguard crystal from water vapor
• Protective film has specific roughness and thickness criteria

Potential Applications: This technology could be used in:

• Medical imaging devices
• Radiation detectors
• Nuclear physics experiments

Problems Solved:

• Protection of columnar crystal from water vapor damage
• Ensuring consistent light emission from crystal

Benefits:

• Enhanced durability of scintillator plate
• Improved performance in various applications
• Long-lasting protection against environmental factors

Commercial Applications: Potential commercial uses include:

• Manufacturing of medical imaging equipment
• Research and development in nuclear physics
• Production of radiation detection devices

Prior Art: Readers can explore prior research on scintillator plates, protective films, and crystal durability in scientific journals and patent databases.

Frequently Updated Research: Stay updated on advancements in scintillator plate technology, protective film materials, and crystal protection methods for the latest innovations in this field.

Questions about Scintillator Plate Technology: 1. What are the specific characteristics of the protective film in this scintillator plate technology? 2. How does the columnar crystal in this technology differ from traditional scintillator materials?

2. Another relevant generic question, with a detailed answer: How does the protective film in this scintillator plate technology contribute to the overall performance and longevity of the device?

Original Abstract Submitted

A scintillator plate includes a columnar crystal formed on a substrate and configured to emit light based on irradiating radiation, the columnar crystal having a predetermined column diameter, and a protective film formed to cover the columnar crystal and configured to protect the columnar crystal from water vapor, the protective film having a predetermined thickness. An arithmetic average roughness of the protective film is less than or equal to the column diameter, and a thickness of the protective film is less than or equal to 4 times the column diameter.