閃爍體探測器市場 - 2023 年至 2028 年預測

閃爍體探測器市場預計將從2021年的7.597億美元增長到2028年的9.74076億美元，複合年增長率為4.82%。

閃爍體探測器使研究人員能夠發現大量的輻射和粒子。 在後續步驟中使用粒子同時檢測光電倍增管和光電二極管。 當粒子撞擊閃爍體探測器時，閃爍體探測器吸收粒子的能量並發光。 閃爍體探測器通常由石英等透明材料製成，但如果含有重元素，它們的性能往往會更好。 這是因為閃爍體探測器能夠吸收材料中的伽馬射線。 閃爍體探測器同時進行許多標記實驗的能力是其廣泛使用的驅動力。

此外，主要製造商對技術改進的關注、亞洲國家核電站數量的增加以及閃爍體探測器在廣泛的最終應用中的使用不斷增加正在導致閃爍體探測器市場的增長。

此外，閃爍體探測器在醫學掃描和其他放射應用中的使用越來越多，以及心臟和神經系統疾病患病率的不斷增加，將推高閃爍體探測器的市場價值。 研發成本將會上升，為閃爍體探測器市場的擴大鋪平道路。

不斷進步的技術正在推動市場增長。

不斷增長的技術進步和各種應用的新技術正在推動市場發展。 多個組織正在研究這項技術，包括國土安全部國內核探測辦公室，該辦公室正在探索光譜個人輻射探測器的新技術。 這項研究旨在識別和識別核材料和放射性材料，以及開發更好的檢測系統。 這項工作產生的技術可以與全新的手持設備結合起來並用於日常活動。 我們的重點是加強核材料和放射性材料的探測能力，這對於提高國土安全部識別和遏制核威脅的能力至關重要。

被動快速移動中子探測解決方案通過各種主動探測方法提高了對屏蔽原生核材料的探測能力，並可作為特定核材料（特別是武器級鈽）存在的潛在指標。此外，閃爍體探測器的誘人特性，例如高精度、高效性以及檢測更低水平輻射的能力，吸引了各個行業的眾多進步。

此外，在 PET 掃描儀中使用閃爍材料的日益增多預計將大大促進醫學成像技術的發展，從而增加主要國家醫療設備的收入。 例如，根據國際貿易局2020年報告，美國醫療器械收入從2019年的1980億美元增至2020年的2090億美元。

醫療行業的應用將推動閃爍體探測器市場的需求。

閃爍體探測器用於製造各種醫療成像設備，包括平面 X 光線成像、X 光線電腦斷層掃描 (X 光線 CT)、SPECT 和 PET 掃描。 閃爍體探測器和閃爍材料用於診斷成像設備，因為它們提供有關伽馬射線和X射線的精確位置、發射時間和轉換時間的相關資訊，有助於拍攝準確的圖像。 因此，由於腫瘤和損傷等慢性疾病的增加，對診斷成像的需求不斷增加，正在推動該領域的增長。 根據 NHS 最近的一份報告，2022 年英格蘭記錄了 4400 萬次影像檢查，比上一年的 3490 萬次增加了 26%。 最常見的是X光線檢查，2180萬例（同比增長30%），其次是超音波檢查，1010萬例（同比增長23%），計算機斷層掃描670萬例（同比增長23%）。同比增長21% ），磁共振成像（MRI）為380萬（同比增長28%）。

閃爍體探測器用於製造各種醫療成像設備，包括平面 X 光線成像、X 光線計算機斷層掃描 (X 光線 CT)、SPECT 和 PET 掃描。 閃爍體探測器和閃爍材料用於診斷成像設備，因為它們提供有關伽馬射線和X射線的精確位置、發射時間和轉換時間的相關資訊，有助於拍攝準確的圖像。 因此，由於腫瘤和損傷等慢性疾病的增加，對診斷成像的需求不斷增加，正在推動該領域的增長。 根據 NHS 最近的一份報告，2022 年英格蘭記錄了 4400 萬次影像檢查，比上一年的 3490 萬次增加了 26%。 普通X 光檢查佔最多病例，為2,180 萬例（比上年增長30%），其次是超音波診斷，為1,010 萬例（比上年增長23%），電腦斷層掃描為670 萬例（比上年增長21%） 、磁共振成像（MRI，380萬，同比增長28%）。

慢性病和流行病等情況的增加加速了最新診斷醫療設備的研發，推動了閃爍體探測器在醫療保健領域的增長。我是。 例如，2023 年 5 月，佛羅裡達州立大學的一組科學家開發了新一代有機-無機混合材料，該材料有潛力提高 CT 掃描、X 射線機以及其他輻射探測和成像技術的圖像質量。 化學與生物化學系馬必武教授及其同事開發了這種新材料。 這些材料在暴露於 X 光線或其他高能輻射時會發光。

內容

第 1 章簡介

• 市場概況
• 市場定義
• 調查範圍
• 市場細分
• 貨幣
• 先決條件
• 基準年和預測年的時間表

第 2 章研究方法

• 調查數據
• 先決條件

第 3 章執行摘要

• 研究亮點

第 4 章市場動態

• 市場促進因素
• 市場抑制因素
• 波特五力分析
• 行業價值鏈分析

第 5 章閃爍體探測器市場：按材料分析

• 簡介
• 有機
• 無機

第 6 章閃爍體探測器市場：按產品分析

• 簡介
• 袖珍設備
• 手持設備
• 固定/固定係統

第 7 章閃爍體探測器市場：最終用戶行業分析

• 簡介
• 醫療
• 能源/電力
• 製造業
• 防禦
• 其他

第 8 章閃爍體探測器市場：區域分析

• 簡介
• 北美
  • 美國
  • 加拿大
  • 墨西哥
• 南美洲
  • 巴西
  • 其他
• 歐洲
  • 英國
  • 德國
  • 法國
  • 其他
• 中東和非洲
  • 沙特阿拉伯
  • 以色列
  • 其他
• 亞太地區
  • 日本
  • 中國
  • 韓國
  • 印度
  • 印度尼西亞
  • 台灣
  • 其他

第 9 章競爭格局與分析

• 主要公司及戰略分析
• 新興公司和市場盈利能力
• 合併、收購、協議和合作
• 供應商競爭力矩陣

第 10 章公司簡介

• Applied Scintillation Technologies Ltd.
• Argus Imaging Bv Inc.
• Hamamatsu Photonics K.K.
• Radiation Monitoring Devices Inc
• Hitachi Metal Ltd.
• Mirion Technologies
• Siemens
• Zecotek Photonics Inc
• Ludlum Measurements
• Amcrys
• Saint Gobain
• Zecotek Photonics Inc.

The scintillator market is predicted to grow at a CAGR of 4.82% from US$700.597 million in 2021 to US$974.076 million by 2028.

Scintillators enable researchers to find numerous radiation and particles. The photomultipliers and photodiodes are simultaneously detected using the particles in a later step. When a particle strikes a scintillator, the scintillator emits luminesce by absorbing the energy of the particle. Scintillators, which typically consist of water-clear crystalline materials, are more likely to perform better if they contain heavy elements. This is since it enables the scintillators to absorb gamma radiation from the substance. The scintillators' capacity to conduct many labeling experiments at once is what is driving their wider use.

Further, expanding focus on technological improvements by the major producers, rising the number of nuclear power plants in Asian countries, and the expanding use of scintillators for a broad range of end-use applications are leading to the market growth of scintillators.

Moreover, the increasing use of scintillators in medical scanning and other radiological applications in medicine, as well as the rising prevalence of heart and neurological illnesses, will boost the scintillator market value. The cost of conducting research and development will rise, which will pave the way for the market for scintillators to expand.

Increasing technological advancements to boost market growth.

Growing technical advancement and novel technologies for a variety of uses is driving the market. Various organizations are researching this technology such as The Domestic Nuclear Detection Office of the Department of Homeland Security, which is trying to explore new technologies for Spectroscopic Personal Radiation Detectors. The study attempts to locate and recognize nuclear or radioactive sources as well as develop better detection systems. The technologies created through this effort could be combined with brand-new handheld gadgets and used in regular activities. It is putting a lot of effort into enhancing nuclear and radiological detection capabilities, which is essential to improving the DHS's capacity to recognize and contain nuclear threats.

The passive fast-moving neutron detection solution, which in turn increases the detection of shielded unique nuclear material across various active detection methods, is a possible indicator of the presence of certain nuclear materials, notably weapons-grade plutonium. Further, the enticing characteristics of scintillators, such as high precision, effectiveness, and the capacity to detect even lower radiation levels, are drawing numerous advancements in a variety of industries.

Additionally, the expanding practice of using scintillating materials in PET scanners is expected to significantly contribute to the development of medical imaging techniques which has increased the revenue for medical devices in major countries. For instance, as per the 2020 report of International Trade Administration, the revenue of medical devices in America increased from US$198 billion in 2019 to US$209 billion in 2020.

Application in the medical industry to boost the demand for the scintillators market.

Scintillators are used in the production of a wide variety of medical imaging devices such as planar x-ray imaging, x-ray computed tomography (x-ray CT), SPECT and PET scan. Scintillators and scintillating materials are used in imaging devices as they provide relevant information regarding the exact position, emission time and time of conversion of each gamma and X ray which help in taking precise images. Therefore, growing demand for diagnostic images because of rising prevalence of chronic disease such as tumors or injuries is driving the growth of this segment. According to a recent NHS report, in England, 44.0 million imaging tests were recorded in 2022, up from 34.9 million the previous year, representing a 26 per cent rise. Plain radiography or X-ray was the most common, accounting for 21.8 million treatments, an increase of 30 per cent from previous year followed by Diagnostic Ultrasonography with 10.1 million scans, an increase of 23 per cent), Computerized Axial Tomography recorded 6.7 million scans, representing an increase of 21 per cent, and Magnetic Resonance Imaging (MRI, 3.8 million, an increase of 28%).

Scintillators are used in the production of a wide variety of medical imaging devices such as planar x-ray imaging, x-ray computed tomography (x-ray CT), SPECT and PET scan. Scintillators and scintillating materials are used in imaging devices as they provide relevant information regarding the exact position, emission time and time of conversion of each gamma and X ray which help in taking precise images. Therefore, growing demand for diagnostic images because of rising prevalence of chronic disease such as tumors or injuries is driving the growth of this segment. According to a recent NHS report, in England, 44.0 million imaging tests were recorded in 2022, up from 34.9 million the previous year, representing a 26 per cent rise. Plain radiography or X-ray was the most common, accounting for 21.8 million treatments, an increase of 30 per cent from previous year followed by Diagnostic Ultrasonography with 10.1 million scans, an increase of 23 per cent), Computerized Axial Tomography recorded 6.7 million scans, representing an increase of 21 per cent, and Magnetic Resonance Imaging (MRI, 3.8 million, an increase of 28%).

Rising prevalence of chronic disease and pandemic like situations have led to increased research and trails to develop latest diagnostic medical devices, driving the growth of scintillators in the healthcare sector. For instance, in May 2023, a group of Florida State University scientists has developed a new generation of organic-inorganic hybrid materials that potentially improve picture quality in CT scans, X-Ray machines, and other radiation detection and imaging technologies. Professor Biwu Ma of the Department of Chemistry and Biochemistry and his colleagues developed these novel materials, which may be used as scintillators. When exposed to X-Rays and other high-energy radiations, these materials emit light.

Key Developments

• In August 2020, researchers from Florida State University created eco-friendly X-ray Scintillators with High Efficiency that are less expensive and environmentally hazardous than current technology.
• in November 2022, Canon Medical Systems Corporation (Canon Medical), a subsidiary of Canon Inc., has created the first photon-counting CT system using scintillators in the United States that incorporates Redlen's sophisticated technology. This system was deployed at Japan's National Cancer Centre Exploratory Oncology Research & Clinical Trial Centre, where it is now employed for research into the clinical uses of PCCT.

Segmentation:

By Material Type

• Organic
• Inorganic

By Product

• Pocket-Size Instruments
• Hand-Held Instruments
• Fixed or Installed Systems

By End-User Industry

• Healthcare
• Energy and Power
• Manufacturing
• Defense
• Others

By Geography

• North America
• USA
• Canada
• Others
• South America
• Brazil
• Others
• Europe
• UK
• Germany
• France
• Others
• Middle East and Africa
• Saudi Arabia
• Israel
• Others
• Asia Pacific
• China
• Japan
• South Korea
• India
• Indonesia
• Taiwan
• Others

TABLE OF CONTENTS

1. INTRODUCTION

• 1.1. Market Overview
• 1.2. Market Definition
• 1.3. Scope of the Study
• 1.4. Market Segmentation
• 1.5. Currency
• 1.6. Assumptions
• 1.7. Base, and Forecast Years Timeline

2. RESEARCH METHODOLOGY

• 2.1. Research Data
• 2.2. Assumptions

3. EXECUTIVE SUMMARY

• 3.1. Research Highlights

4. MARKET DYNAMICS

• 4.1. Market Drivers
• 4.2. Market Restraints
• 4.3. Porter's Five Force Analysis
  • 4.3.1. Bargaining Power of Suppliers
  • 4.3.2. Bargaining Power of Buyers
  • 4.3.3. Threat of New Entrants
  • 4.3.4. Threat of Substitutes
  • 4.3.5. Competitive Rivalry in the Industry
• 4.4. Industry Value Chain Analysis

5. SCINTILLATOR MARKET ANALYSIS BY MATERIAL TYPE

• 5.1. Introduction
• 5.2. Organic
• 5.3. Inorganic

6. SCINTILLATOR MARKET ANALYSIS BY PRODUCT

• 6.1. Introduction
• 6.2. Pocket-Size Instruments
• 6.3. Hand-Held Instruments
• 6.4. Fixed or Installed Systems

7. SCINTILLATOR MARKET ANALYSIS BY END-USER INDUSTRY

• 7.1. Introduction
• 7.2. Healthcare
• 7.3. Energy and Power
• 7.4. Manufacturing
• 7.5. Defense
• 7.6. Others

8. SCINTILLATOR MARKET ANALYSIS BY GEOGRAPHY

• 8.1. Introduction
• 8.2. North America
  • 8.2.1. United States
  • 8.2.2. Canada
  • 8.2.3. Mexico
• 8.3. South America
  • 8.3.1. Brazil
  • 8.3.2. Others
• 8.4. Europe
  • 8.4.1. UK
  • 8.4.2. Germany
  • 8.4.3. France
  • 8.4.4. Others
• 8.5. Middle East and Africa
  • 8.5.1. Saudi Arabia
  • 8.5.2. Israel
  • 8.5.3. Others
• 8.6. Asia Pacific
  • 8.6.1. Japan
  • 8.6.2. China
  • 8.6.3. South Korea
  • 8.6.4. India
  • 8.6.5. Indonesia
  • 8.6.6. Taiwan
  • 8.6.7. Others

9. COMPETITIVE ENVIRONMENT AND ANALYSIS

• 9.1. Major Players and Strategy Analysis
• 9.2. Emerging Players and Market Lucrativeness
• 9.3. Mergers, Acquisitions, Agreements, and Collaborations
• 9.4. Vendor Competitiveness Matrix

10. COMPANY PROFILES

• 10.1. Applied Scintillation Technologies Ltd.
• 10.2. Argus Imaging Bv Inc.
• 10.3. Hamamatsu Photonics K.K.
• 10.4. Radiation Monitoring Devices Inc
• 10.5. Hitachi Metal Ltd.
• 10.6. Mirion Technologies
• 10.7. Siemens
• 10.8. Zecotek Photonics Inc
• 10.9. Ludlum Measurements
• 10.10. Amcrys
• 10.11. Saint Gobain
• 10.12. Zecotek Photonics Inc.