Scintillator

Scintillator Market Outlook

The global scintillator market is anticipated to reach approximately USD 1.5 billion by 2035, exhibiting a compound annual growth rate (CAGR) of around 6.2% from 2025 to 2035. This growth trajectory is primarily driven by the increasing demand for advanced radiation detection and imaging systems, particularly in the healthcare and defense sectors. Additionally, the rising focus on safety and security in various applications such as nuclear power plants and homeland security is contributing significantly to the market's expansion. The rapid advancement in technology, leading to enhanced scintillator materials with improved efficiencies, is also influencing market growth positively. Furthermore, the rising need for innovative scientific research methodologies continues to propel the demand for scintillation detectors across various sectors.

Growth Factor of the Market

The scintillator market is experiencing robust growth, largely fueled by several key factors. Firstly, the healthcare sector is increasingly leveraging scintillator-based imaging systems, which are critical for diagnostic and therapeutic applications in nuclear medicine. Additionally, the heightened focus on national security and defense mechanisms has led to significant investments in advanced radiation detection technologies, thereby boosting the scintillator market. Furthermore, the evolving landscape of scientific research necessitates the use of scintillator materials for particle detection and analysis, enhancing the overall market demand. The increasing adoption of scintillators in industrial applications, such as non-destructive testing and quality control, also plays a vital role in driving market growth. Lastly, the expanding application of scintillators in nuclear power plants for radiation monitoring is expected to positively impact the market dynamics.

Key Highlights of the Market

• The market is projected to witness a CAGR of 6.2% from 2025 to 2035.
• Healthcare applications are anticipated to dominate the market, driven by increasing use in imaging systems.
• Rising investments in homeland security and defense are bolstering demand for scintillator-based detection systems.
• Technological advancements in scintillation materials are enhancing efficiency and performance.
• Growing applications in scientific research and industrial sectors are contributing to overall market growth.

By Product Type

Inorganic Scintillators:

Inorganic scintillators are widely recognized for their exceptional light output and radiation detection efficiency, making them a preferred choice in numerous applications. These scintillators typically include materials such as sodium iodide (NaI) and cesium iodide (CsI). Inorganic scintillators are particularly favored in medical imaging and radiation therapy due to their ability to provide high-resolution images and accurate data. The durability and stability of inorganic scintillators in high-energy environments also contribute to their growing adoption in industrial and nuclear applications. Their ongoing development to enhance efficiency and reduce cost further strengthens their position in the market. As research continues, new inorganic materials are being explored for enhanced performance, which is expected to widen their application scope in the coming years.

Organic Scintillators:

Organic scintillators are primarily composed of organic compounds and are characterized by their lightweight and flexible nature. These materials are particularly valued in applications requiring high time resolution and fast response times, such as in particle physics and radiation detection. Organic scintillators can be utilized in a variety of forms, including pellets, films, and powders, which makes them versatile for different detection systems. The ability to customize organic scintillators for specific applications is a notable advantage, allowing for enhanced performance in varied environments. Their widespread use in both commercial and research settings reflects a growing trend towards organic scintillator technology. As industries seek lighter and more adaptable scintillation materials, the organic scintillator segment is poised for growth.

Liquid Scintillators:

Liquid scintillators are a unique category of scintillation materials that offer distinct advantages, particularly in large-scale radiation detection applications. These materials are typically composed of organic solvents mixed with scintillation solutes, enabling them to yield high light output and excellent energy resolution. Liquid scintillators are particularly beneficial in applications such as neutrino detection and nuclear physics research, where their ability to fill large volumes enhances detection capabilities. Furthermore, the flexibility in the formulation of liquid scintillators allows for optimization based on specific application needs, making them suitable for a wide range of scientific research. The ongoing advancements in liquid scintillator technology are expected to bolster their adoption in future applications, particularly in the context of high-energy particle detection.

Plastic Scintillators:

Plastic scintillators are widely recognized for their cost-effectiveness and versatility, making them popular in various applications ranging from medical diagnostics to industrial testing. These materials are lightweight and can be fabricated into different shapes and sizes, which allows for easy integration into detection systems. Plastic scintillators provide a good balance between performance and price, making them an attractive option for many industries. Their robustness and ability to operate well in harsh environments further enhance their appeal in applications such as radiation monitoring and safety inspections. The advancements in polymer-based scintillator technologies are also paving the way for improved performance metrics, which will likely drive further market growth in this segment.

Others:

This segment encompasses various scintillator types that do not fit into the primary categories mentioned above. These may include hybrid scintillators that combine different materials to leverage the benefits of each, or novel materials currently under research that promise enhanced performance characteristics. The development of these alternative scintillation materials is crucial as it can lead to significant advancements in radiation detection capabilities. As new technologies emerge and research progresses, the "Others" category is expected to capture an increasing share of the market, especially if these materials can demonstrate superior efficiency, cost-effectiveness, or application-specific advantages.

By Application

Healthcare:

The healthcare sector is one of the largest consumers of scintillator materials, primarily due to their pivotal role in medical imaging and treatment. Scintillators are extensively utilized in positron emission tomography (PET) and single-photon emission computed tomography (SPECT) imaging, where they facilitate the detection of gamma rays emitted from radioactive tracers in the body. The accurate and efficient performance of scintillators is crucial for ensuring high image quality and diagnostic accuracy. Moreover, the increasing incidence of chronic diseases necessitates the expansion of advanced medical imaging solutions, thereby fostering the demand for scintillator materials. As innovations in medical technology continue, scintillators will play a significant role in enhancing patient care through improved imaging and treatment modalities.

Homeland Security and Defense:

Scintillator materials are essential components in the realm of homeland security and defense, where they are deployed in radiation detection systems for surveillance and monitoring. The rising global concerns regarding nuclear security and potential threats from radioactive materials have necessitated robust detection systems that can promptly identify and respond to such risks. Scintillators are employed in handheld devices, portal monitors, and other detection equipment that are critical in ensuring national safety. Moreover, continuous investments in advanced technologies to enhance detection capabilities are anticipated to drive the scintillator market in this sector. The integration of scintillation detectors into security protocols further emphasizes the importance of these materials in safeguarding public safety.

Nuclear Power Plants:

In nuclear power plants, scintillator materials serve a vital function in monitoring radiation levels and ensuring operational safety. As these facilities generate significant amounts of radiation, accurate detection and measurement are paramount to maintaining safety standards and regulatory compliance. Scintillator detectors are employed to monitor radiation in various components of the plant, including reactors and waste storage areas. The growing emphasis on safety protocols and accident prevention in nuclear facilities has led to an increased demand for reliable radiation detection solutions. Furthermore, as countries around the world are investing in nuclear energy as a cleaner alternative to fossil fuels, the demand for scintillator materials in this application is expected to grow, promoting advancements in detection technology.

Industrial:

In industrial applications, scintillators are utilized for non-destructive testing and quality control processes, ensuring the integrity and safety of materials and components. Scintillation detectors facilitate the detection of structural flaws and hidden defects in a variety of materials, thus enhancing product quality and safety. Industries such as oil and gas, aerospace, and automotive are increasingly adopting these technologies to meet stringent safety regulations and improve operational efficiency. The growing focus on maintaining high standards in production processes, coupled with the need for advanced inspection techniques, will likely drive the demand for scintillator materials in the industrial sector. Continued advancements in detection technology will further bolster the market's growth in this area.

Scientific Research:

The scientific research application of scintillators is a vital contributor to the market, as these materials are extensively used in experimental setups across various fields such as particle physics, astrophysics, and materials science. Scintillators play a crucial role in detecting high-energy particles and radiation, thus enabling researchers to conduct experiments and derive meaningful insights into fundamental scientific phenomena. As research institutions and universities continue to explore new technologies and scientific frontiers, the demand for innovative scintillator materials will likely increase. The development of specialized scintillators tailored for specific research applications is an emerging trend that will further enhance the market's potential in this segment.

By Distribution Channel

Direct Sales:

Direct sales channels play a significant role in the scintillator market, particularly for companies producing specialized or high-performance scintillators. By engaging directly with end-users, manufacturers are able to offer tailored solutions and establish strong customer relationships which can lead to repeat business and customer loyalty. This direct engagement allows for better understanding of client needs, enabling companies to refine their products and services accordingly. Moreover, direct sales often facilitate faster transactions and provide end-users with immediate technical support, enhancing overall satisfaction. As manufacturers strengthen their direct sales capabilities, they are likely to capture a larger share of the market by providing high-quality products and services aligned with customer expectations.

Distributor Sales:

Distributor sales serve as a critical channel for reaching a broader customer base in the scintillator market. Distributors often have established networks and relationships with various sector stakeholders, including healthcare facilities, research institutions, and industrial plants. This extensive reach enables manufacturers to tap into diverse markets that may be difficult to penetrate through direct sales alone. Additionally, distributors often provide value-added services, such as technical support and inventory management, which can significantly enhance customer satisfaction. The collaboration between manufacturers and distributors is essential for ensuring that scintillator products are readily available to end-users across various regions and industries, thereby sustaining market growth. As the demand for scintillator materials continues to expand, the role of distributors will be increasingly important in facilitating market access.

By Ingredient Type

Cesium Iodide:

Cesium iodide (CsI) is one of the most commonly used scintillation materials due to its excellent luminescent properties and high light output. CsI is particularly favored in medical imaging applications, as it provides high resolution and is effective in gamma-ray detection. The material's stability and durability in various operating environments enhance its applicability across a range of settings, including healthcare and industrial sectors. Furthermore, advancements in the manufacturing process have led to the development of CsI crystals with improved performance metrics, which are anticipated to further drive demand. Given the ongoing evolution in imaging technology and radiation detection, cesium iodide remains a key player in the scintillator market.

Sodium Iodide:

Sodium iodide (NaI) is another widely used scintillator known for its high efficiency in detecting gamma radiation. NaI is particularly prominent in medical applications such as SPECT imaging, where its properties enable high-quality image acquisition. The relatively low cost and availability of sodium iodide further contribute to its popularity across various applications. However, NaI crystals are hygroscopic, which necessitates careful handling and encapsulation to maintain performance. Despite this challenge, innovations in encapsulation technology are helping to mitigate these issues, allowing for continued growth of sodium iodide in both medical and industrial applications. As research progresses, the versatility of NaI is expected to further enhance its market presence.

Lutetium Orthosilicate:

Lutetium orthosilicate (LSO) is recognized for its exceptional performance in high-energy applications, particularly in positron emission tomography (PET) imaging. LSO offers superior energy resolution and a very fast decay time, making it ideal for applications requiring quick response times. The increasing adoption of LSO in advanced imaging systems is a testament to its efficacy and reliability. Additionally, as the demand for more precise and efficient imaging technologies rises, lutetium orthosilicate is well-positioned to capitalize on this trend. Ongoing research into enhancing the properties of LSO and its potential applications in other fields further signifies its growing importance in the scintillator market.

Bismuth Germanate:

Bismuth germanate (Bi4Ge3O12) is a scintillation material known for its high density and effective gamma-ray detection capabilities. Its properties make it suitable for various applications, including medical imaging, homeland security, and industrial radiography. BGO provides good energy resolution and is particularly effective in environments with high radiation levels. However, the relatively high cost and limited availability of bismuth germanate compared to other scintillation materials can pose challenges. Despite these hurdles, the unique properties of BGO ensure its continued relevance in niche markets. As industries seek advanced detection solutions, the demand for bismuth germanate is expected to persist, especially in specialized applications.

Others:

This category encompasses various scintillator materials that do not fall under the major ingredient types listed above. These may include new compounds or hybrid materials that combine multiple ingredients to achieve desired scintillation characteristics. The development of alternative scintillator materials can offer advantages such as improved performance, cost-efficiency, or enhanced adaptability for specific applications. As research institutions and manufacturers continue to explore innovative materials, the "Others" segment is expected to gain traction, providing new opportunities for growth in the scintillator market. The increasing focus on sustainable and environmentally-friendly materials may also pave the way for the emergence of new scintillator compositions that meet contemporary market demands.

By Region

The North American scintillator market is projected to generate significant revenue, primarily due to the high demand in the healthcare and defense sectors. The presence of advanced healthcare facilities and research institutions supports the continuous adoption of scintillator technologies for various applications, including medical imaging and radiation detection. Furthermore, the United States government’s investments in homeland security and nuclear safety initiatives are likely to propel market growth in this region. With a CAGR of approximately 6.5% from 2025 to 2035, North America is expected to lead the scintillator market, driven by ongoing technological advancements and increased spending on radiation detection systems.

In Europe, the scintillator market is also poised for robust growth, driven by the increasing adoption of advanced imaging technologies in medical diagnostics and ongoing research activities in the fields of physics and material sciences. The European market is characterized by a strong focus on innovation and the development of new scintillator materials to address emerging application needs. As countries in the region enhance their nuclear safety protocols, the demand for scintillator materials to monitor radiation is anticipated to grow significantly. The European scintillator market is expected to experience a CAGR of around 5.8% from 2025 to 2035, further contributing to the overall global growth.

Opportunities

As the scintillator market continues to evolve, numerous opportunities are emerging across various sectors. The rapidly growing healthcare industry presents a significant opportunity for scintillator manufacturers, especially in the realm of diagnostic imaging. With rising investments in healthcare technologies and an increasing focus on early disease detection, the demand for advanced imaging systems that utilize scintillation materials is anticipated to surge. Furthermore, the ongoing advancements in scintillator technology, including the development of novel materials with enhanced performance characteristics, will open new avenues for innovation. Companies that invest in research and development to create next-generation scintillators may find themselves well-positioned to capitalize on this growing demand. Additionally, strategic partnerships with healthcare providers and research institutions can further strengthen market positioning and drive growth.

Moreover, the increasing focus on safety and security in various applications presents substantial opportunities for scintillator adoption in the homeland security and defense sectors. Governments and organizations worldwide are recognizing the need for advanced radiation detection systems to enhance national security and ensure public safety. As these sectors continue to invest in state-of-the-art detection technologies, scintillator manufacturers can leverage this trend to expand their market presence. Innovations in distribution channels, such as the development of online platforms and improved supply chain logistics, can also facilitate access to scintillator products, further enhancing market growth. Overall, the scintillator market is rife with opportunities for companies willing to adapt and innovate in response to evolving industry needs.

Threats

While the scintillator market presents numerous opportunities, several threats could hinder its growth trajectory. One of the primary challenges is the intense competition from alternative radiation detection technologies that may offer superior efficiency or cost benefits. Emerging technologies, such as solid-state detectors, could potentially replace traditional scintillation detectors in certain applications, resulting in a decline in demand for scintillator materials. Additionally, fluctuations in raw material prices can impact production costs and, subsequently, pricing strategies for scintillator products. This economic uncertainty may deter investments in new projects or technologies, thereby affecting overall market growth. Furthermore, stringent regulatory standards in various regions regarding radiation detection and safety can complicate market entry for new players, limiting competition and innovation.

Another significant threat to the scintillator market is the potential for supply chain disruptions, particularly in light of recent global events that have highlighted vulnerabilities in manufacturing and distribution networks. These disruptions can lead to delays in product availability and increased costs, which may affect customer satisfaction and market dynamics. Furthermore, the growing emphasis on environmentally-friendly materials and sustainable manufacturing practices may pose challenges for traditional scintillator manufacturers. Companies will need to adapt to changing consumer preferences and regulatory landscapes, which could necessitate significant investments in research and development. Addressing these threats will be critical for maintaining a competitive edge in the scintillator market.

Competitor Outlook

• Saint-Gobain
• Eljen Technology
• Thallion Technologies
• Radiation Detection Company
• Hamamatsu Photonics
• Mirion Technologies
• Canberra Industries
• Hitachi Metals, Ltd.
• Scintillation Solutions
• Nuvia Group
• Advanced Scintillation Materials, Inc.
• GE Healthcare
• Amcrys
• Alpha Spectra
• Optical Science

The competitive landscape of the scintillator market is characterized by a mix of established players and emerging companies, all vying for market share through innovation and strategic positioning. Key players such as Saint-Gobain and Hamamatsu Photonics have established themselves as leaders in the industry, leveraging their extensive experience and technological expertise to deliver high-quality scintillation products. These companies continuously invest in research and development to enhance their product offerings and address the evolving needs of various application sectors. Moreover, partnerships with research institutions and healthcare providers help these leading companies to stay at the forefront of industry advancements, enabling them to respond swiftly to market changes.

Emerging companies, like Eljen Technology and Thallion Technologies, are making strides in the scintillator market by focusing on niche applications and innovative materials. These companies often emphasize agility and flexibility in their operations, allowing them to respond rapidly to customer demands and industry trends. By developing specialized scintillation products that cater to specific market needs, emerging players are carving out their space in a competitive landscape. Additionally, the collaboration between established and emerging companies can foster technological advancements, resulting in superior scintillation materials and solutions that benefit the entire market.

The competitive dynamics in the scintillator market are also influenced by factors such as pricing strategies, distribution channels, and customer service. Companies that establish strong relationships with distributors and end-users are likely to gain a competitive advantage. Furthermore, as sustainability becomes an increasingly crucial aspect of business operations, companies that invest in environmentally-friendly practices and materials may stand out in the market. Overall, the scintillator market's competitive landscape is expected to evolve continuously, with ongoing technological advancements and strategic collaborations shaping its future.

• 1 Appendix

  • 1.1 List of Tables
  • 1.2 List of Figures

• 2 Introduction

  • 2.1 Market Definition
  • 2.2 Scope of the Report
  • 2.3 Study Assumptions
  • 2.4 Base Currency & Forecast Periods

• 3 Market Dynamics

  • 3.1 Market Growth Factors
  • 3.2 Economic & Global Events
  • 3.3 Innovation Trends
  • 3.4 Supply Chain Analysis

• 4 Consumer Behavior

  • 4.1 Market Trends
  • 4.2 Pricing Analysis
  • 4.3 Buyer Insights

• 5 Key Player Profiles

  • 5.1 Amcrys
    • 5.1.1 Business Overview
    • 5.1.2 Products & Services
    • 5.1.3 Financials
    • 5.1.4 Recent Developments
    • 5.1.5 SWOT Analysis
  • 5.2 Nuvia Group
    • 5.2.1 Business Overview
    • 5.2.2 Products & Services
    • 5.2.3 Financials
    • 5.2.4 Recent Developments
    • 5.2.5 SWOT Analysis
  • 5.3 Saint-Gobain
    • 5.3.1 Business Overview
    • 5.3.2 Products & Services
    • 5.3.3 Financials
    • 5.3.4 Recent Developments
    • 5.3.5 SWOT Analysis
  • 5.4 Alpha Spectra
    • 5.4.1 Business Overview
    • 5.4.2 Products & Services
    • 5.4.3 Financials
    • 5.4.4 Recent Developments
    • 5.4.5 SWOT Analysis
  • 5.5 GE Healthcare
    • 5.5.1 Business Overview
    • 5.5.2 Products & Services
    • 5.5.3 Financials
    • 5.5.4 Recent Developments
    • 5.5.5 SWOT Analysis
  • 5.6 Optical Science
    • 5.6.1 Business Overview
    • 5.6.2 Products & Services
    • 5.6.3 Financials
    • 5.6.4 Recent Developments
    • 5.6.5 SWOT Analysis
  • 5.7 Eljen Technology
    • 5.7.1 Business Overview
    • 5.7.2 Products & Services
    • 5.7.3 Financials
    • 5.7.4 Recent Developments
    • 5.7.5 SWOT Analysis
  • 5.8 Canberra Industries
    • 5.8.1 Business Overview
    • 5.8.2 Products & Services
    • 5.8.3 Financials
    • 5.8.4 Recent Developments
    • 5.8.5 SWOT Analysis
  • 5.9 Hamamatsu Photonics
    • 5.9.1 Business Overview
    • 5.9.2 Products & Services
    • 5.9.3 Financials
    • 5.9.4 Recent Developments
    • 5.9.5 SWOT Analysis
  • 5.10 Mirion Technologies
    • 5.10.1 Business Overview
    • 5.10.2 Products & Services
    • 5.10.3 Financials
    • 5.10.4 Recent Developments
    • 5.10.5 SWOT Analysis
  • 5.11 Hitachi Metals, Ltd.
    • 5.11.1 Business Overview
    • 5.11.2 Products & Services
    • 5.11.3 Financials
    • 5.11.4 Recent Developments
    • 5.11.5 SWOT Analysis
  • 5.12 Thallion Technologies
    • 5.12.1 Business Overview
    • 5.12.2 Products & Services
    • 5.12.3 Financials
    • 5.12.4 Recent Developments
    • 5.12.5 SWOT Analysis
  • 5.13 Scintillation Solutions
    • 5.13.1 Business Overview
    • 5.13.2 Products & Services
    • 5.13.3 Financials
    • 5.13.4 Recent Developments
    • 5.13.5 SWOT Analysis
  • 5.14 Radiation Detection Company
    • 5.14.1 Business Overview
    • 5.14.2 Products & Services
    • 5.14.3 Financials
    • 5.14.4 Recent Developments
    • 5.14.5 SWOT Analysis
  • 5.15 Advanced Scintillation Materials, Inc.
    • 5.15.1 Business Overview
    • 5.15.2 Products & Services
    • 5.15.3 Financials
    • 5.15.4 Recent Developments
    • 5.15.5 SWOT Analysis

• 6 Market Segmentation

  • 6.1 Scintillator Market, By Application
    • 6.1.1 Healthcare
    • 6.1.2 Homeland Security and Defense
    • 6.1.3 Nuclear Power Plants
    • 6.1.4 Industrial
    • 6.1.5 Scientific Research
  • 6.2 Scintillator Market, By Product Type
    • 6.2.1 Inorganic Scintillators
    • 6.2.2 Organic Scintillators
    • 6.2.3 Liquid Scintillators
    • 6.2.4 Plastic Scintillators
    • 6.2.5 Others
  • 6.3 Scintillator Market, By Ingredient Type
    • 6.3.1 Cesium Iodide
    • 6.3.2 Sodium Iodide
    • 6.3.3 Lutetium Orthosilicate
    • 6.3.4 Bismuth Germanate
    • 6.3.5 Others
  • 6.4 Scintillator Market, By Distribution Channel
    • 6.4.1 Direct Sales
    • 6.4.2 Distributor Sales

• 7 Competitive Analysis

  • 7.1 Key Player Comparison
  • 7.2 Market Share Analysis
  • 7.3 Investment Trends
  • 7.4 SWOT Analysis

• 8 Research Methodology

  • 8.1 Analysis Design
  • 8.2 Research Phases
  • 8.3 Study Timeline

• 9 Future Market Outlook

  • 9.1 Growth Forecast
  • 9.2 Market Evolution

• 10 Geographical Overview

  • 10.1 Europe - Market Analysis
    • 10.1.1 By Country
      • 10.1.1.1 UK
      • 10.1.1.2 France
      • 10.1.1.3 Germany
      • 10.1.1.4 Spain
      • 10.1.1.5 Italy
  • 10.2 Scintillator Market by Region
  • 10.3 Asia Pacific - Market Analysis
    • 10.3.1 By Country
      • 10.3.1.1 India
      • 10.3.1.2 China
      • 10.3.1.3 Japan
      • 10.3.1.4 South Korea
  • 10.4 Latin America - Market Analysis
    • 10.4.1 By Country
      • 10.4.1.1 Brazil
      • 10.4.1.2 Argentina
      • 10.4.1.3 Mexico
  • 10.5 North America - Market Analysis
    • 10.5.1 By Country
      • 10.5.1.1 USA
      • 10.5.1.2 Canada
  • 10.6 Middle East & Africa - Market Analysis
    • 10.6.1 By Country
      • 10.6.1.1 Middle East
      • 10.6.1.2 Africa

• 11 Global Economic Factors

  • 11.1 Inflation Impact
  • 11.2 Trade Policies

• 12 Technology & Innovation

  • 12.1 Emerging Technologies
  • 12.2 AI & Digital Trends
  • 12.3 Patent Research

• 13 Investment & Market Growth

  • 13.1 Funding Trends
  • 13.2 Future Market Projections

• 14 Market Overview & Key Insights

  • 14.1 Executive Summary
  • 14.2 Key Trends
  • 14.3 Market Challenges
  • 14.4 Regulatory Landscape

Segments Analyzed in the Report

The global Scintillator market is categorized based on

By Product Type

• Inorganic Scintillators
• Organic Scintillators
• Liquid Scintillators
• Plastic Scintillators
• Others

By Application

• Healthcare
• Homeland Security and Defense
• Nuclear Power Plants
• Industrial
• Scientific Research

By Distribution Channel

• Direct Sales
• Distributor Sales

By Ingredient Type

• Cesium Iodide
• Sodium Iodide
• Lutetium Orthosilicate
• Bismuth Germanate
• Others

By Region

• North America
• Europe
• Asia Pacific
• Latin America
• Middle East & Africa

Key Players

• Saint-Gobain
• Eljen Technology
• Thallion Technologies
• Radiation Detection Company
• Hamamatsu Photonics
• Mirion Technologies
• Canberra Industries
• Hitachi Metals, Ltd.
• Scintillation Solutions
• Nuvia Group
• Advanced Scintillation Materials, Inc.
• GE Healthcare
• Amcrys
• Alpha Spectra
• Optical Science