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水中における微量汚染物質検出用センサー:世界市場の予測 2023年

Sensors for Trace Contaminant Detection in Water: Technologies and Global Markets

発行 BCC Research 商品コード 733542
出版日 ページ情報 英文 168 Pages
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水中における微量汚染物質検出用センサー:世界市場の予測 2023年 Sensors for Trace Contaminant Detection in Water: Technologies and Global Markets
出版日: 2018年10月22日 ページ情報: 英文 168 Pages
概要

世界の水中における微量汚染物質検出用センサー市場は、2017年の16億米ドルから2022年までに22億米ドルへ達すると予測され、この間は7.1%のCAGR (年間複合成長率) が見込まれています。

当レポートでは、世界の水中における微量汚染物質検出用センサー市場について調査し、市場の分析、市場動向・実績・予測、各セグメント・地域別の分析と予測、および主要企業のプロファイルなどをまとめています。

第1章 イントロダクション

第2章 サマリー・ハイライト

第3章 市場・技術背景

  • サプライチェーン分析
  • 水中における微量汚染物質検出用センサーのサプライヤー
  • 水中における微量汚染物質検出用センサーのメーカー
  • 水中における微量汚染物質検出用センサーの用途
  • センサー:進化と転換
  • センサーの歴史
  • 推計分析
  • 規制の枠組み
  • 市場概要
  • 用途別
  • センサー技術
  • 地域分析

第4章 市場分析:用途別

  • 概要
  • 飲料水
  • 地下水・地表水
  • 廃水
  • ラボ用途
  • その他の用途

第5章 市場分析:センサー技術別

  • 飲料水
  • 河川における化学物質漏えい検知
  • 水泳用プールの遠隔測定
  • 海洋における汚染レベル
  • 腐食・水垢沈殿防止
  • 水耕法
  • 養殖場、魚槽、孵化場、水産養殖および水産物
  • MicroChemLab (LoCセンサー技術)
  • テルル化亜鉛カドミウム検知器
  • ナノ電極アレイ

第6章 市場分析:地域別

  • 北米
  • 欧州
  • アジア太平洋
  • その他

第7章 市場成長促進要因

  • 水質汚染の広がり
  • 環境モニタリングに対する政府イニシアチブ
  • 技術進歩
  • スマートウォーターネットワークの導入

第8章 企業プロファイル

  • ANDALYZE INC.
  • AQUA METROLOGY SYSTEMS
  • ATLAS SCIENTIFIC
  • BIOSENSOR SRL
  • CHELSEA TECHNOLOGIES GROUP LTD.
  • ELECTRO-CHEMICAL DEVICES
  • FREDSENSE TECHNOLOGIES CORP.
  • GINER LABS
  • HACH COMPANY
  • HANNA INSTRUMENTS INC.
  • HORIBA LTD.
  • HYDRO INTERNATIONAL
  • INNOVATIVE SENSOR TECHNOLOGY AG
  • LIBELIUM
  • LUMENSE INC.
  • MULTISENSOR SYSTEMS LTD.
  • NANOAFFIX SCIENCE LLC
  • OAKTON INSTRUMENTS
  • OPTEX CO. LTD
  • OPTIENZ SENSORS
  • OPTIQUA TECHNOLOGIES PTE LTD.
  • SEAPOINT SENSORS INC.
  • SENSOREX CORP.
  • SORBISENSE A/S
  • TELEDYNE ANALYTICAL INSTRUMENTS
  • THERMO FISHER SCIENTIFIC
  • VAN LONDON CORP.
  • VEOLIA
  • YOKOGAWA INDIA LTD.
  • YSI INC.
図表

List of Tables

  • Summary Table: Global Market for Sensors for Trace Contamination Detection in Water, by Application, Through 2022
    • Table 1: Parameters to be Monitored in Trace Contamination Detection
    • Table 2: Global Suppliers of Raw Materials Used in the Production of Sensors for Trace Contamination Detection in Water
    • Table 3: Global Manufacturers of Sensors for Trace Contaminant Detection in Water
    • Table 4: Stimuli Commonly Measured Through Sensors
    • Table 5: Criteria for Selecting a Sensor
    • Table 6: EPA Ratings for Water Bodies Based on the Level of Total Dissolved Solids
    • Table 7: Water Quality Index (WQI) Designations
    • Table 8: Water Quality Index (WQI) Level, by Country
    • Table 9: Severity Scale of Water Stress
    • Table 10: Top 32 Water-Stressed Countries, 2040
    • Table 11: Fresh Water Pollution Sources, Effects and Concerns
    • Table 12: Inorganic and Organic Chemical Contaminants Regulated, by EPA in Drinking Water
    • Table 13: List of Contaminants Regulated in Drinking Water by the EU
    • Table 14: Drinking Water Quality Standards in Japan
    • Table 15: Australian Drinking Water Guidelines/Key Water Quality Parameters
    • Table 16: Global Market Share of Sensors for Trace Contamination Detection in Water, by Application, 2016 and 2022
    • Table 17: Global Distribution Shares of Freshwater, by Source
    • Table 18: Benefits and Drawbacks of Commercially Accessible Nutrient Sensor Technologies
    • Table 19: Global Distribution Share of Groundwater, by Use
    • Table 20: Global Distribution Share of Ground and Surface Water, by Source
    • Table 21: Negative Impact of Untreated Wastewater on the Environment, Human Health and Productive Activities
    • Table 22: Global Distribution Share of Untreated Wastewater, by Economy, 2015 vs. 2030
    • Table 23: Key Points Considered Prior to Sensor Placement in Laboratories
    • Table 24: Manufacturers of Trace Contamination Detection Sensors
    • Table 25: Global Market Share of Sensors for Trace Contamination Detection in Water, by Technology, 2016 and 2022
    • Table 26: List of Contaminants with Their Harmful Level and Impact
    • Table 27: Sensor Technologies and Detection Limits
    • Table 28: Global Market Share of Sensors for Trace Contamination Detection in Water, by Region, 2016 and 2022
    • Table 29: Global Market for Sensors for Trace Contaminant Detection in Water, by Application, Through 2022
    • Table 30: Permissible Contaminant Levels in Drinking Water
    • Table 31: Global Market for Sensors for Trace Contaminant Detection in Drinking Water, by Region, Through 2022
    • Table 32: EPA National Drinking Water Standards for Microorganisms
    • Table 33: European Standard Allowances for Chemicals in Drinking Water
    • Table 34: Global Market for Sensors for Trace Contaminant Detection for Groundwater and Surface Water, by Region, Through 2022
    • Table 35: Sources of Potential Groundwater Contamination, by Land Use Category
    • Table 36: Groundwater Contaminants Identified by Japan's Ministry of the Environment
    • Table 37: Global Distribution Share of Wastewater Treatment, by Country
    • Table 38: Typical Components of Wastewater, by Source
    • Table 39: Content of Typical Wastewater in Some Major Industries
    • Table 40: Comparison of Relative Requirements of Sensors for Different Environmental Monitoring Applications
    • Table 41: Global Market for Sensors for Trace Contaminant Detection for Wastewater, by Region, Through 2022
    • Table 42: Global Market for Sensors for Trace Contaminant Detection for Laboratory Applications, by Region, Through 2022
    • Table 43: Reagent Grade Water Specifications
    • Table 44: C3-A4 Reagent Laboratory Water
    • Table 45: Reagent Grade Water Specifications
    • Table 46: Standard Guide for Bio-Applications Grade Water
    • Table 47: Consequences of Several Water Contaminants on Various Laboratory Procedures
    • Table 48: Type of Water Used in Various Laboratory Applications
    • Table 49: Possible Environmental Impacts of Aquaculture
    • Table 50: Global Market for Sensors for Trace Contaminant Detection for Other Applications, by Region, Through 2022
    • Table 51: Global Market for Sensors for Trace Contaminant Detection, by Technology, Through 2022
    • Table 52: Sensor Technologies Used for Water Monitoring
    • Table 53: Potential Sensor Technologies of MicroChemLab
    • Table 54: Specifications for MicroChemLab (Liquid Version)
    • Table 55: Global Market for MicroChemLab, by Region, Through 2022
    • Table 56: Summary of Specifications for Radioisotope CZT Sensors T
    • Table 57: Global CZT Market, by Region, Through 2022
    • Table 58: Volume of LLW/ILW Radioactive Waste Generated by 1,000 MWe Nuclear Power Reactor
    • Table 59: Specifications of Nanoelectrode Arrays (Trace Metal Sensors)
    • Table 60: Global Market for Nanoelectrode Arrays, by Region, Through 2022
    • Table 61: Global Market for Sensors for Trace Contaminant Detection, by Region, Through 2022
    • Table 62: North American Market for Sensors for Trace Contaminant Detection, by Country, Through 2022
    • Table 63: North American Market for Sensors for Trace Contaminant Detection, by Application, Through 2022
    • Table 64: U.S. Manufacturers of Water Sensors
    • Table 65: North American Market for Sensors for Trace Contaminant Detection, by Technology, Through 2022
    • Table 66: European Drinking Water Quality Standards
    • Table 67: European Market for Sensors for Trace Contaminant Detection, by Country, Through 2022
    • Table 68: European Market for Sensors for Trace Contaminant Detection, by Technology, Through 2022
    • Table 69: U.K.-Based Chemical Standards
    • Table 70: European Market for Sensors for Trace Contaminant Detection, by Application, Through 2022
    • Table 71: Asia-Pacific Market for Sensors for Trace Contaminant Detection, by Country, Through 2022
    • Table 72: Water Quality in China, by Percentage, 2016
    • Table 73: Asia-Pacific Market for Sensors for Trace Contaminant Detection, by Application, Through 2022
    • Table 74: Asia-Pacific Market for Sensors for Trace Contaminant Detection, by Technology, Through 2022
    • Table 75: Established Water Stations
    • Table 76: ROW Market for Sensors for Trace Contaminant Detection, by Country, Through 2022
    • Table 77: ROW Market for Sensors for Trace Contaminant Detection, by Application, Through 2022
    • Table 78: Latin American Market for Sensors for Trace Contaminant Detection, by Application, Through 2022
    • Table 79: ROW Market for Sensors for Trace Contaminant Detection, by Technology, Through 2022
    • Table 80: Total Consumption of Pesticides in Brazil, by Crop, 2015
    • Table 81: Latin American Market for Sensors for Trace Contaminant Detection, by Technology, Through 2022
    • Table 82: Annually Renewable Fresh Water Available per Capita in the Middle East and North Africa (MENA)
    • Table 83: MENA Market for Sensors for Trace Contaminant Detection, by Application, Through 2022
    • Table 84: MENA Market for Sensors for Trace Contaminant Detection, by Technology, Through 2022
    • Table 85: Household Indoor Water Use in the U.S., 2016
    • Table 86: U.S. Water Consumption Share, 2016
    • Table 87: Total Water Use in New York State, by Category, 2016
    • Table 88: Total Water Use in New York State, by Other Category, 2016
    • Table 89: China's Key Policies for Water Pollution
    • Table 90: China's Key Policies for Environmental Monitoring and Testing
    • Table 91: EPA National Primary Drinking Water Standards for Inorganic Chemicals
    • Table 92: EPA National Primary Drinking Water Standards for Organic Chemicals
    • Table 93: Product Portfolio
    • Table 94: Recent Developments
    • Table 95: Product Portfolio
    • Table 96: Recent Developments
    • Table 97: Product Portfolio
    • Table 98: Product Portfolio
    • Table 99: Product Portfolio
    • Table 100: Recent Developments
    • Table 101: Product Portfolio
    • Table 102: Recent Developments
    • Table 103: Product Portfolio
    • Table 104: Recent Developments
    • Table 105: Product Portfolio
    • Table 106: Product Portfolio
    • Table 107: Recent Developments
    • Table 108: Product Portfolio
    • Table 109: Product Portfolio
    • Table 110: Recent Developments
    • Table 111: Product Portfolio
    • Table 112: Product Portfolio
    • Table 113: Recent Developments
    • Table 114: Product Portfolio
    • Table 115: Recent Developments
    • Table 116: Product Portfolio
    • Table 117: Product Portfolio
    • Table 118: Recent Developments
    • Table 119: Product Portfolio
    • Table 120: Product Portfolio
    • Table 121: Product Portfolio
    • Table 122: Product Portfolio
    • Table 123: Product Portfolio
    • Table 124: Recent Developments
    • Table 125: Product Portfolio
    • Table 126: Product Portfolio
    • Table 127: Product Portfolio
    • Table 128: Recent Development
    • Table 129: Product Portfolio
    • Table 130: Product Portfolio
    • Table 131: Product Portfolio
    • Table 132: Product Portfolio
    • Table 133: Product Portfolio
    • Table 134: Recent Developments
    • Table 135: Product Portfolio
    • Table 136: Recent Developments

List of Figures

  • Summary Figure: Global Market for Sensors for Trace Contamination Detection in Water, by Application, 2016-2022
    • Figure 1: Basic Scale-up Process for Trace Contamination Detection Sensors
    • Figure 2: Supply Chain for Sensors for Trace Contaminant Detection in Water
    • Figure 3: Working of a Sensor
    • Figure 4: Online Water Quality Monitoring
    • Figure 5: Global Market Share of Sensors for Trace Contamination Detection in Water, by Application, 2016 and 2022
    • Figure 6: Global Distribution Shares of Freshwater, by Source
    • Figure 7: Global Distribution Shares of Groundwater, by Use
    • Figure 8: Global Distribution Shares of Ground and Surface Water, by Source
    • Figure 9: Global Distribution Shares of Untreated Wastewater, by Economy, 2015 vs. 2030
    • Figure 10: Global Market Share of Sensors for Trace Contamination Detection in Water, by Technology, 2016 and 2022
    • Figure 11: Global Market Share of Sensors for Trace Contamination Detection in Water, by Region, 2016 and 2022
    • Figure 12: Global Distribution Share of Wastewater Treatment, by Country
    • Figure 13: Top Five Countries with Maximum Nuclear Power Facilities Worldwide
    • Figure 14: Water Quality in China, by Percentage, 2016
    • Figure 15: Concern About Water Pollution in the U.S.
    • Figure 16: Household Indoor Water Use in the U.S., 2016
    • Figure 17: U.S. Water Consumption Share, 2016
    • Figure 18: Total Water Use in New York State, by Category, 2016
    • Figure 19: Total Water Use in New York State, by Other Category, 2016
    • Figure 20: Overall Groundwater Quality in China, 2015
目次
Product Code: MST063A

Report Highlights:

The global market for sensors for trace contaminant detection in water is expected to increase from $1.6 billion in 2017 to $2.2 billion in 2022 at a compound annual growth rate (CAGR) of 7.1% for 2017-2022.

Groundwater and surface water market for sensors for trace contaminant detection in water is expected from $415 million in 2017 to $591 million in 2022 at a compound annual growth rate (CAGR) of 7.3% for 2017-2022.

Drinking water market for sensors for trace contaminant detection in water is expected from $373 million in 2017 to $546 million in 2022 at a compound annual growth rate (CAGR) of 7.9% for 2017-2022.

Report Scope:

The scope of this report covers the many types of sensors available and their potential applications. Revenue forecasts from 2017 to 2022 are provided by application, sensor technology segment and regional market, with estimated values derived from manufacturers' total revenues. The report covers sensors used for the detection of trace metals, biologics, volatile organic compounds (VOCs) and semi-VOCs, and radioisotopes found in water.

The report includes a discussion of the major players, by region, in the global market for trace contamination detection sensors. It also explains the major drivers, regional dynamics and current trends in the industry. The report concludes with a look at the vendor landscape, with profiles of the major vendors.

Report Includes:

  • 136 tables
  • An overview of the global markets and technologies for sensors for trace contaminant detection in water
  • Analyses of global market trends, with data from 2016, 2017, and projections of compound annual growth rates (CAGRs) through 2022
  • Coverage of type of sensor products available and their potential applications
  • Description of sensor technologies i.e nano electrode array and laser induces break down spectroscopy
  • Discussion of the major players of the industry, including Aqua Metrology Systems, Electro-Chemical Devices, Hanna Instruments, Inc., OptiEnz Sensors, Seapoint Sensors Inc., Thermo Fisher Scientific and Yokogawa India Ltd

Table of Contents

Chapter 1: Introduction

  • Study Goals and Objectives
  • Reasons for Doing This Study
  • Scope of Report
  • Methodology
  • Geographic Breakdown
  • Analyst's Credentials
  • BCC Custom Research
  • Related BCC Research Reports

Chapter 2: Summary and Highlight

Chapter 3: Market and Technology Background

  • Supply Chain Analysis
  • Suppliers of Sensors for Trace Contamination Detection in Water
  • Manufacturers of Trace Contamination Detection Sensors in Water
    • Market Factors
  • Application of Trace Contamination Detection Sensors in Water
  • Sensors: Evolution and Transition
  • History of Sensors
  • Estimation Analysis
    • High Water Pollution Levels across the Globe
    • Future Water Stress
    • Water Pollution Sources
  • Regulatory Framework
    • United States
    • European Union
    • Groundwater Directive (2006/118/EC)
    • Canada
    • China
    • Japan
    • Australia
  • Market Overview
  • By Application
    • Drinking Water
    • Groundwater and Surface Water
    • Wastewater
    • Laboratory Applications
    • Others
  • Sensor Technologies
    • Nanoelectrode Arrays
    • Laser Induced Breakdown Spectroscopy
    • MicroChemLab
    • CZT Detectors
    • Other Sensor Technologies
  • Regional Analysis
    • North America
    • Europe
    • Asia-Pacific
    • Rest of World

Chapter 4: Market Breakdown by Application

  • Overview
  • Drinking Water
    • Application of Sensor for Trace Contaminant Detection in Drinking Water
  • Ground and Surface Water
    • Sensors for Trace Contaminant Detection in Groundwater and Surface Water
  • Wastewater
    • Application
    • Temperature Sensor
    • pH
    • Conductivity
    • Biomass/Suspended Solids
    • Anaerobic Digestion
    • Sensors in Wastewater Treatment
  • Laboratory Applications
    • Sensors for Trace Contaminant Detection in Laboratory Applications
  • Other Applications
    • Aquaculture
    • Coastal/Estuarine Applications
    • Sensors Used for Trace Contaminant Detection in Coastal Waters and Estuaries

Chapter 5: Market Breakdown by Sensor Technology

  • Drinking Water
  • Chemical Leakage Detection in Rivers
  • Swimming Pool Remote Measurement
  • Pollution Levels in the Sea
  • Corrosion and Limescale Deposits Prevention
  • Hydroponics
  • Fish Farms, Fish Tanks, Hatcheries, Aquaculture and Aquaponics
  • MicroChemLab (Lab-on-a-Chip Sensor Technology)
    • Pre-concentration
    • Separation
    • Detection
    • MicroChemLab (Liquid)
  • Cadmium Zinc Telluride Detectors
  • Nanoelectrode Arrays
    • Nanostructured Gold Nanoelectrode Arrays for Ultrasensitive Detection of Heavy Metal Contamination
    • Pd-Cu Cathode Nanoelectrode Arrays for Nitrate Electroreduction
    • Mechanism and Effectiveness of Ti-based Nanoelectrodes for Electrochemical Denitrification
    • Cu- and Fe-based Nanoelectrode Arrays for Nitrate Electroreduction
    • Laser-Induced Breakdown Spectroscopy

Chapter 6: Market Breakdown by Region

  • North America
    • United States
    • Canada
    • Mexico
  • Europe
    • United Kingdom
    • France
    • Germany
    • Spain
    • Italy
    • Rest of Europe
  • Asia-Pacific
    • China
    • India
    • Japan
    • Australia
    • South Korea
    • Rest of Asia-Pacific
  • Rest of the World
    • Latin America
    • Middle East and Africa

Chapter 7: Market Drivers

  • Increasing Water Pollution
  • Government Initiatives for Environment Monitoring
  • Technological Advancements
  • Adoption of Smart Water Networks

Chapter 8: Company Profiles

  • ANDALYZE INC.
  • AQUA METROLOGY SYSTEMS
  • ATLAS SCIENTIFIC
  • BIOSENSOR SRL
  • CHELSEA TECHNOLOGIES GROUP LTD.
  • ELECTRO-CHEMICAL DEVICES
  • FREDSENSE TECHNOLOGIES CORP.
  • GINER LABS
  • HACH COMPANY
  • HANNA INSTRUMENTS INC.
  • HORIBA LTD.
  • HYDRO INTERNATIONAL
  • INNOVATIVE SENSOR TECHNOLOGY AG
  • LIBELIUM
  • LUMENSE INC.
  • MULTISENSOR SYSTEMS LTD.
  • NANOAFFIX SCIENCE LLC
  • OAKTON INSTRUMENTS
  • OPTEX CO. LTD
  • OPTIENZ SENSORS
  • OPTIQUA TECHNOLOGIES PTE LTD.
  • SEAPOINT SENSORS INC.
  • SENSOREX CORP.
  • SORBISENSE A/S
  • TELEDYNE ANALYTICAL INSTRUMENTS
  • THERMO FISHER SCIENTIFIC
  • VAN LONDON CORP.
  • VEOLIA
  • YOKOGAWA INDIA LTD.
  • YSI INC.
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