World Smart Windows Market 2018-2027 - From Luxury Buildings to the IoT Markets
World Smart Windows Market 2018-2027 - From Luxury Buildings to the IoT Markets
DUBLIN, May 2, 2018 /PRNewswire/ --
The "Smart Windows Market 2018 - 2027" report has been added to ResearchAndMarkets.com's offering.
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Global Smart Windows Market to Reach $5.6 billion by 2023
While energy savings will remain a powerful driver for smart windows the report identifies several other technological and market drivers that are combining to make 2018 a transformatory year for the business.
This report quantifies the market for smart window based on electrochromic (EC), SPD, PDLC and passive technologies in both volume (square meters) and value ($ millions) terms. It also discusses how smart windows are being aggressively melded into the Internet-of-things (IoT) business ecosystem and how the markets for smart windows are moving beyond the luxury buildings that characterized smart windows up until now. Both smart windows for buildings and transportation (automotive, aerospace and marine) are covered.
The report provides ten-year revenue forecasts broken out by material/technology type and application. In addition, the report discusses the business models being employed by leading firms in the smart windows space including their use of automation.
Key Topics Covered:
Executive Summary
E.1 Changes Since the Last Report
E.2 Summary of Market Opportunities
E.2.1 Radiation Detection Materials
E.2.2 Medical Applications
E.2.3 National Security and Government
E.2.4 General Industrial Applications
E.2.5 The Growing Need for Portable Systems
E.3 Summary of Ten-year Forecasts of Radiation Detection Equipment and Materials
Chapter One: Introduction
1.1 Background to this Report
1.1.1 New Opportunities in the Radiation Materials Market
1.1.2 Medical Applications for Radiation Detection Equipment
1.1.3 Security Applications for Radiation Detection Equipment
1.1.4 Energy Industry Applications
1.1.5 Other Applications
1.2 Objectives and Scope of this Report
1.3 Methodology of this Report
1.3.1 Forecasting Methodology
1.4 Plan of this Report
Chapter Two: Trends in Materials for Radiation Detection
2.1 Continuing Shifts Away from Legacy Materials
2.2 Commercialization of Newer Scintillation Materials
2.3 Development of Alternative Semiconductor Radiation Detection Materials
2.4 Replacing 3-Helium for Neutron Detection
2.5 The Radiation Detection Materials Supply Chain
2.5.1 Impact of New Materials on Marketing and Production Strategies
2.5.2 Opportunities for Partnerships Between Materials Firms and Equipment Suppliers
2.5.3 Constraints on Raw Material Supply
2.6 Ten-year Forecast of Radiation Detection Materials by Type of Material
2.6.1 Forecasting Methodology
2.6.2 Forecasts of Scintillation Materials
2.6.3 Forecasts of Semiconductor Materials
2.6.4 Forecasts of Neutron Detection Materials
2.6.5 Forecasts by Radiation Detection Application
2.6.6 Forecasts by Geography
2.7 Key points from this chapter
Chapter Three: Medical Applications for Radiation Detection Equipment
3.1 Important Policy Trends
3.1.1 Requirements in Europe
3.1.2 Accreditation of Medical Facilities in the U.S.
3.1.3 Push to Digital X-ray Technology
3.1.4 Japan Established Diagnostic Reference Levels for Medical Radiation
3.2 Regulatory and Policy Changes Affecting the Market
3.2.1 Health Insurance and Healthcare Funding
3.2.2 Changing Rules in the United States
3.3 Key Equipment Suppliers of Medical Radiation Detection Equipment
3.4 Important Technology Trends
3.5 Diagnostic Equipment for Nuclear Imaging
3.6 Radiotherapy
3.6.1 Image-guided Radiotherapy
3.6.2 Linear Acclerators
3.6.3 Gamma Cameras
3.6.4 Treatment for Early Stage Cancer
3.7 X-Ray Imaging
3.7.1 3D Mammography
3.7.2 Bone Densitometry
3.7.3 CT Scanning
3.8 Pharmaceutical Industry Applications
3.8.1 Radiation Detection Needs
3.9 Prospects for Suppliers of Radiation Detection Equipment for Medical Applications
3.9.1 X-ray Imaging Continues to Dominate
3.9.2 In-Vivo Anatomy and Functional Visualization
3.9.3 The Importance of Low-Radiation Dosage
3.9.4 Changes in the PET and Nuclear Medicine Market
3.10 Key Points from this Chapter
Chapter Four: Applications Focused on National and International Security
4.1 The Landscape of Radiation Detection Equipment for Security Applications
4.1.1 Types of Radiation Detection Devices in Use
4.2 Key Equipment Suppliers
4.3 Military Markets for Radiation Detection Equipment
4.3.1 Portable Detection Devices
4.3.2 Opportunities for Larger Scale Systems
4.4 Role of Radiation Detection Equipment in Controlling Nuclear Weapons Proliferation
4.5 Domestic/Homeland Security
4.5.1 Protection of Ports and Borders
4.5.2 Protection of Cities and Buildings
4.5.3 Keeping U.S. Cities Safe
4.5.4 Addressing the needs of Police and other First Responder Services
4.6 Need for Radiation Detection by Individual Citizens
4.7 Key Points from this Chapter
Chapter Five: Energy Industry
5.1 Radiation Equipment for Nuclear Power Plants
5.1.1 Impact of National Plans for Nuclear Power
5.1.2 Safety Concerns
5.1.3 Detection Equipment Used in Nuclear Power Plants
5.1.4 Suppliers of Radiation Detection Equipment for Nuclear Power Plants
5.2 Oil and Mining Industries
5.2.1 Fracking
5.2.2 Well-logging Devices
5.2.3 Detectors and Data Collection Systems
5.2.4 Compact and Portable Systems
5.2.5 Equipment Companies
5.3 Waste Disposal
5.3.1 Detecting Radioactive Waste
5.3.2 Detecting Waste from Oil and Gas Wells
5.3.3 Measuring Radioactivity in Medical Waste
5.3.4 Measuring Radioactivity in Landfills
5.3.4 Equipment companies
5.4 Key Points from this Chapter
Chapter Six: General Industrial and Scientific Applications
6.1 Radiation Detection Needs of the Food Industry
6.1.1 Impact of Food Irradiation and Related Government Guidelines
6. 2 Scrap Metal Recycling
6.2.1 Guidelines and the Need for Monitoring
6.2.2 Response of the Recycling Industry
6.3 Industrial Radiography Markets for Radiation Detection
6.4 High-energy Physics and the Needs of Large Laboratories
6.5 Key Points from this Chapter
Chapter Seven: Ten-Year Forecasts of Radiation Detection Equipment
7.1 Forecast Methodology
7.2 Forecasts by Sector
7.3 Industrial and Scientific Applications
7.4 Forecasts by Type of Equipment
7.5 Forecasts by Geography
Chapter Eight: Profiles of Leading Companies in the Radiation Detection Market
8.1 Arktis Radiation Detectors
8.1.1 Arktis' Next-generation Radiation Detection Platform
8.2 Mirion Technologies
8.2.1 Acquisition of Canberra strengthens Mirion in the Nuclear Community
8.3 Kromek Group
8.3.1 Kromek delivered 10K D3S Detectors to DARPA's SIGMA Program
8.3.2 Kromek sees Growth with Long-term Contracts Worldwide
8.4 ORTEC
8.4.1 ORTEC Innovating Products to Support and Increase Sales of HPGe
8.5 Saint-Gobain Crystals
8.5.1 Driving Growth Through Improving Performance of Existing Materials
8.5.2 BrilLanCe Range is a Key Pathbreaker
8.6 Zecotek Photonics
8.6.1 Specialization in LFS crystals
8.7 Dynasil
8.7.1 RMD adds Value to Dynasil
Companies Mentioned
-- Argil
-- Arktis Radiation Detectors
-- Asahi Glass
-- Boeing
-- Chameleon
-- ChromoGenics
-- Daimler-Benz
-- Dynasil
-- e-Chromic
-- EControl-Glas
-- Gentex
-- Guardian
-- Kromek Group
-- Mirion Technologies
-- Pleotint
-- Polytronix
-- PPG
-- RavenWindow
-- Research Frontiers
-- SageGlass/Saint-Gobain
-- View Smart Film Glass
-- Vision Systems Aeronautics
-- Zecotek Photonics
For more information about this report visit https://www.researchandmarkets.com/research/qwpmlf/world_smart?w=5
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