The Global Market for Radiation Detection Equipment and Materials 2023-2033
The radiation detection equipment market is an essential part of various industries, including medical imaging, nuclear power, manufacturing, security, and environmental monitoring. The main objective of this equipment is to detect and measure the presence of ionizing radiation, which includes alpha, beta, gamma, and neutron radiation. Market growth is driven by national security, nuclear power generation, and medical imaging/diagnostics applications. Geiger counters and scintillation detectors are the most commonly used technologies. Semiconductor detectors are growing fastest for high resolution analysis. The market is consolidated with the top 5 suppliers accounting for the majority of the market.
Report contents include:
Report contents include:
- Overview of radiation types and sources.
- Principles of radiation detection.
- Market trends and drivers.
- SWOT analysis.
- Analysis of Equipment/devices market including:
- Proportional Radiation Detectors (PRDs)
- Semiconductor Proportional Radiation Detectors (SPRD)
- Dosimeters
- Area Monitors
- Survey Meters
- RIIDs
- Portal Monitors, Fixed
- Portal Monitors, Portable
- Portable Backpack Systems
- Contamination Monitors.
- Analysis of leading equipment suppliers and market shares.
- Equipment pricing analysis.
- Emerging technologies and innovations.
- Analysis of radiation detection materials market including:
- NaI scintillators
- Cesium Iodide crystals
- Thin film scintillators
- Lanthanam-based materials
- CLYC-based materials
- Oxide-based materials
- Silicate-based materials
- Yittrium-based materials
- Plastic scintillators
- Nanomaterials.
- Material supplier analysis.
- Pricing analysis and cost structure.
- Analysis of end-use markets including:
- Nuclear Energy
- Food Industry
- Industrial Radiography
- Oil and Mining
- Security and Military
- Medical Imaging
- Environmental monitoring.
- Global market revenues 2018-2033 (Billion USD) by equipment type, end-use markets and region.
- Profiles of 33 companies including product offerings. Companies profiled include Berkeley Nucleonics, CoDeAc Solutions, Fuji Electric, Kromek, Mirion Technologies, Saint-Gobain, and Thermo Fisher Scientific.
1 RESEARCH METHODOLOGY
2 ACRONYMS AND TERMS
3 INTRODUCTION
3.1 Overview of radiation types and sources
3.2 Principles of radiation detection
3.2.1 Ionization
3.2.2 Scintillation
3.2.3 Luminescence
3.2.4 Detection mediums
3.2.5 Moderation
3.2.6 Multi-stage detectors
3.2.7 Shielding
3.3 Applications
4 THE GLOBAL MARKET FOR RADIATION DETECTION EQUIPMENT AND MATERIALS
4.1 Market trends
4.2 SWOT analysis
4.3 Equipment/devices
4.3.1 PRD/SPRDs
4.3.1.1 Proportional Radiation Detectors (PRDs)
4.3.1.2 Semiconductor Proportional Radiation Detectors (SPRD)
4.3.2 Dosimeters
4.3.2.1 Types
4.3.3 Area Monitors
4.3.4 Survey Meters
4.3.5 RIIDs
4.3.6 Portal Monitors, Fixed
4.3.7 Portal Monitors, Portable
4.3.8 Portable Backpack Systems
4.3.9 Contamination Monitors
4.3.10 Leading suppliers and market shares
4.3.11 Equipment pricing analysis
4.3.12 Emerging technologies and innovations
4.4 Materials
4.4.1 NaI scintillators
4.4.2 Cesium Iodide crystals
4.4.3 Thin film scintillators
4.4.4 Lanthanam-based materials
4.4.5 CLYC-based materials
4.4.6 Oxide-based materials
4.4.7 Silicate-based materials
4.4.8 Yittrium-based materials
4.4.9 Plastic scintillators
4.4.10 Nanomaterials
4.4.11 Material suppliers
4.4.12 Pricing analysis and cost structure
4.5 End-use markets
4.5.1 Nuclear Energy
4.5.2 Food Industry
4.5.3 Industrial Radiography
4.5.4 Oil and Mining
4.5.5 Security and Military
4.5.6 Medical Imaging
4.6 Market outlook
4.7 Global market revenues 2018-2033 (Billion USD)
4.7.1 By equipment type
4.7.2 By end-use markets
4.7.3 By region
5 COMPANY PROFILES (33 COMPANY PROFILES)
6 REFERENCES
2 ACRONYMS AND TERMS
3 INTRODUCTION
3.1 Overview of radiation types and sources
3.2 Principles of radiation detection
3.2.1 Ionization
3.2.2 Scintillation
3.2.3 Luminescence
3.2.4 Detection mediums
3.2.5 Moderation
3.2.6 Multi-stage detectors
3.2.7 Shielding
3.3 Applications
4 THE GLOBAL MARKET FOR RADIATION DETECTION EQUIPMENT AND MATERIALS
4.1 Market trends
4.2 SWOT analysis
4.3 Equipment/devices
4.3.1 PRD/SPRDs
4.3.1.1 Proportional Radiation Detectors (PRDs)
4.3.1.2 Semiconductor Proportional Radiation Detectors (SPRD)
4.3.2 Dosimeters
4.3.2.1 Types
4.3.3 Area Monitors
4.3.4 Survey Meters
4.3.5 RIIDs
4.3.6 Portal Monitors, Fixed
4.3.7 Portal Monitors, Portable
4.3.8 Portable Backpack Systems
4.3.9 Contamination Monitors
4.3.10 Leading suppliers and market shares
4.3.11 Equipment pricing analysis
4.3.12 Emerging technologies and innovations
4.4 Materials
4.4.1 NaI scintillators
4.4.2 Cesium Iodide crystals
4.4.3 Thin film scintillators
4.4.4 Lanthanam-based materials
4.4.5 CLYC-based materials
4.4.6 Oxide-based materials
4.4.7 Silicate-based materials
4.4.8 Yittrium-based materials
4.4.9 Plastic scintillators
4.4.10 Nanomaterials
4.4.11 Material suppliers
4.4.12 Pricing analysis and cost structure
4.5 End-use markets
4.5.1 Nuclear Energy
4.5.2 Food Industry
4.5.3 Industrial Radiography
4.5.4 Oil and Mining
4.5.5 Security and Military
4.5.6 Medical Imaging
4.6 Market outlook
4.7 Global market revenues 2018-2033 (Billion USD)
4.7.1 By equipment type
4.7.2 By end-use markets
4.7.3 By region
5 COMPANY PROFILES (33 COMPANY PROFILES)
6 REFERENCES
LIST OF TABLES
Table 1. Acronyms and terms: Radiation Detection Equipment and Materials.
Table 2. Overview of radiation types.
Table 3. Overview of radiation sources.
Table 4. Markets and applications for radiation detection equipment and materials.
Table 5. Market trends and drivers in radiation equipment and materials.
Table 6. Types of dosimeters.
Table 7. Leading radiation detection equipment suppliers and market shares.
Table 8. Nanomaterials utilized in radiation detection.
Table 9. Radiation detection materials suppliers.
Table 10. Pricing analysis and cost structure for radiation detection materials.
Table 11. Food radiation detection.
Table 12. Applications of radiation detection in medical imaging.
Table 13. Applications of radiation detection in environmental monitoring.
Table 14. Global market for radiation detection equipment, by type, 2018-2033 (billions USD).
Table 15. Global market for radiation detection equipment and materials, by end use market, 2018-2033 (billions USD).
Table 16. Global market for radiation detection equipment and materials, by region, 2018-2033 (billions USD).
Table 1. Acronyms and terms: Radiation Detection Equipment and Materials.
Table 2. Overview of radiation types.
Table 3. Overview of radiation sources.
Table 4. Markets and applications for radiation detection equipment and materials.
Table 5. Market trends and drivers in radiation equipment and materials.
Table 6. Types of dosimeters.
Table 7. Leading radiation detection equipment suppliers and market shares.
Table 8. Nanomaterials utilized in radiation detection.
Table 9. Radiation detection materials suppliers.
Table 10. Pricing analysis and cost structure for radiation detection materials.
Table 11. Food radiation detection.
Table 12. Applications of radiation detection in medical imaging.
Table 13. Applications of radiation detection in environmental monitoring.
Table 14. Global market for radiation detection equipment, by type, 2018-2033 (billions USD).
Table 15. Global market for radiation detection equipment and materials, by end use market, 2018-2033 (billions USD).
Table 16. Global market for radiation detection equipment and materials, by region, 2018-2033 (billions USD).
LIST OF FIGURES
Figure 1. SWOT analysis: radiation equipment and materials market.
Figure 2. Commercial Proportional Radiation Detector (PRD).
Figure 3. Commercial Semiconductor Proportional Radiation Detector (SPRD).
Figure 4. Commercial radiation detection dosimeter.
Figure 5. Commercial area monitor.
Figure 6. Commercial radiation survey meter.
Figure 7. Handheld Radiation Isotope Identifier.
Figure 8. Commercial fixed radiation portal monitor.
Figure 9. Commercial portable portal monitor.
Figure 10. SPIR-Pack Human Portable Radiation Detection and Identification System.
Figure 11. RadEye AB100 Alpha-Beta Contamination Monitor.
Figure 12. Radiation Detection Equipment (RDE) at an Integrated Check Post (ICP) at the Attari Border.
Figure 13. Global market for radiation detection equipment, by type, 2018-2033 (billions USD).
Figure 14. Global market for radiation detection equipment and materials, by end use market, 2018-2033 (billions USD).
Figure 15. Global market for radiation detection equipment and materials, by region, 2018-2033 (billions USD).
Figure 1. SWOT analysis: radiation equipment and materials market.
Figure 2. Commercial Proportional Radiation Detector (PRD).
Figure 3. Commercial Semiconductor Proportional Radiation Detector (SPRD).
Figure 4. Commercial radiation detection dosimeter.
Figure 5. Commercial area monitor.
Figure 6. Commercial radiation survey meter.
Figure 7. Handheld Radiation Isotope Identifier.
Figure 8. Commercial fixed radiation portal monitor.
Figure 9. Commercial portable portal monitor.
Figure 10. SPIR-Pack Human Portable Radiation Detection and Identification System.
Figure 11. RadEye AB100 Alpha-Beta Contamination Monitor.
Figure 12. Radiation Detection Equipment (RDE) at an Integrated Check Post (ICP) at the Attari Border.
Figure 13. Global market for radiation detection equipment, by type, 2018-2033 (billions USD).
Figure 14. Global market for radiation detection equipment and materials, by end use market, 2018-2033 (billions USD).
Figure 15. Global market for radiation detection equipment and materials, by region, 2018-2033 (billions USD).