It has been well recognised that water is a valuable resource and the quality of our water systems require sampling at a higher temporal and spatial frequency than is currently taking place. The AQUAWARN project aims to meet this challenge through the development of commercially competitive water quality monitoring devices. These will be capable of performing analytical measurements in situ - primarily aimed at freshwater and wastewater systems. The analytes of interest are mainly phosphate, nitrite, nitrate, and pH.ududThe initial focus of this project is the assessment and optimisation of appropriate colorimetric chemistries for each sensing target. These chemistries have been developed and optimised using bench-top instrumentation. Integration within microfluidic chips followed to reduce the per sample costs.ududMicrofluidic technology uses minute amounts of reagent per sample measurement, allowing for a dramatic increase in the number of potential assays per unit volume of reagent. Moreover, the integration of LEDs and photodiodes as light sources and detectors, coupled with syringe pumps, opens the way to new generations of low-cost, portable, and autonomous devices, capable of performing multiple in-situ measurements. For example, an analysis requiring 50 uL of reagent implies 2,000 measurements are possible per 100 mL of reagent.
展开▼
机译:众所周知,水是一种宝贵的资源,我们水系统的质量需要以比目前更高的时空频率进行采样。 AQUAWARN项目旨在通过开发具有商业竞争力的水质监测设备来应对这一挑战。它们将能够进行原位分析测量-主要针对淡水和废水系统。感兴趣的分析物主要是磷酸盐,亚硝酸盐,硝酸盐和pH。 ud ud该项目的最初重点是针对每个感测目标评估和优化合适的比色化学。这些化学物质已经使用台式仪器进行了开发和优化。微流体芯片内的集成随后降低了每样品成本。 ud ud微流体技术在每次样品测量中使用微量的试剂,从而极大地增加了单位体积试剂的潜在测定数量。此外,将LED和光电二极管集成为光源和检测器,再加上注射泵,为通向能够执行多个原位测量的新一代低成本,便携式和自主设备的方式开辟了道路。例如,需要50 uL试剂的分析意味着每100 mL试剂可以进行2,000次测量。
展开▼
