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Society is reliant upon water for drinking and other applications in all regions of the world. The quality and availability of water resources, including surface water, ground water, streams, lakes, oceans, wastewater, and other water resources, varies globally. Human industrial and economic history, global climate, and the quality and distribution of global water resources are intimately connected. Current trends in the water testing industry tend to follow regional economic priorities related to industry, agriculture, and utility regulations. Water testing is necessary to determine water quality, but application and technology specifics of the testing market differ markedly between urban and rural, and between high- and low-income regions. According to UN metrics, water scarcity continues to increase in multiple regions of the world. There are also intensifying water-related crises globally over the last several years, especially in countries historically lagging in water infrastructure investments and in extreme-climate-prone regions. Water quality requirements are often subject to regulations that range dramatically based on legislation, applications, and end markets. Major uses of water testing globally include contaminant and pollutant detection in agricultural irrigation water, drinking water, ultrapure water for semiconductors or pharmaceuticals, and water recycling, including industrial and utility wastewater treatment before, during, and after treatments.
The "Water Testing Instrument 2024" report evaluates the global market for analytical instruments used to test water across 21 different techniques and 5 technology categories. The form-factor of these technologies within each technique includes process/on-line instruments used in continuous water monitoring to laboratory and in-field instruments such as benchtop and portable testing devices. The goal of this report is to assess and forecast the potential for analytical techniques used for water analysis applications in global industries and utilities.
Major trends include rising global demand for drinking water PFAS testing (and increasing scope of the PFAS species regulated) and for water microplastics testing, a young field whose current, early phase of ongoing research is reliant on difficult to automate methods, unlike more mature techniques for water testing.