We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Coating-Based Quartz Crystal Microbalance Detection Methods of Environmentally Relevant Volatile Organic Compounds
Summary
This review described quartz crystal microbalance sensor platforms coated with selective materials for detecting volatile organic compounds in air, comparing different coating chemistries and highlighting their potential for low-cost, portable environmental monitoring.
Volatile organic compounds (VOCs) that evaporate under standard atmospheric conditions are of growing concern. This is because it is well established that VOCs represent major contamination risks since release of these compounds into the atmosphere can contribute to global warming, and thus, can also be detrimental to the overall health of worldwide populations including plants, animals, and humans. Consequently, the detection, discrimination, and quantification of VOCs have become highly relevant areas of research over the past few decades. One method that has been and continues to be creatively developed for analyses of VOCs is the Quartz Crystal Microbalance (QCM). In this review, we summarize and analyze applications of QCM devices for the development of sensor arrays aimed at the detection of environmentally relevant VOCs. Herein, we also summarize applications of a variety of coatings, e.g., polymers, macrocycles, and ionic liquids that have been used and reported in the literature for surface modification in order to enhance sensing and selective detection of VOCs using quartz crystal resonators (QCRs) and thus QCM. In this review, we also summarize novel electronic systems that have been developed for improved QCM measurements.
Sign in to start a discussion.
More Papers Like This
Detection and binding interactions of pharmaceutical contaminants using quartz crystal microbalance - Role of adsorbate structure and surface functional group on adsorption.
This study used quartz crystal microbalance measurements to examine how pharmaceutical contaminants adsorb onto microplastic and organic matter surfaces in water, finding that specific chemical interactions between the contaminants and surface functional groups controlled uptake. The results provide mechanistic insight into how microplastics can accumulate pharmaceutical pollutants and potentially deliver them to organisms.
Evaluation of calibration techniques in low-cost air quality sensing
This study evaluated calibration techniques for improving the accuracy of low-cost air quality sensors, which are being deployed to expand pollution monitoring networks. As airborne microplastics become a recognized health concern, affordable and accurate monitoring tools will be important for tracking human exposure.
RF MEMS Resonance Sensor for Measuring Microplastics Concentration
Researchers designed an RF MEMS resonance sensor capable of detecting microplastics in water at low cost, offering a practical alternative to expensive conventional particle analyzers for environmental monitoring.
Biochar-based electrochemical sensors: a tailored approach to environmental monitoring
This review covers the development of biochar-based electrochemical sensors for detecting environmental pollutants including microplastics, pharmaceuticals, pesticides, and heavy metals. Biochar, made from plant waste through heat treatment, offers a sustainable and low-cost alternative to expensive sensor materials while maintaining good sensitivity and selectivity. These sensors could provide affordable, portable tools for monitoring microplastic and chemical contamination in water and soil.
Advances in the Development of Innovative Sensor Platforms for Field Analysis
This review examined advances in innovative sensor platforms for field environmental analysis, covering technologies for monitoring inorganic and organic air and water pollutants. The authors identified integration of sensing technologies with robotics and the Internet of Things as key future directions for enabling diffuse, real-time environmental monitoring campaigns.