Microclimate monitoring of indoor environments using piezoelectric quartz crystal humidity sensors

Abstract: The aim of this paper is to describe indoor microclimate monitoring at two different locations, Sandham Memorial Chapel, in Hampshire, England, and the castle El Alcázar, in Segovia, Spain. Piezoelectric quartz crystal sensors with novel humidity sensitive poly(ethyleneimine) coatings and Pt resistance thermometers were used to measure the relative humidity (RH) and temperature gradients across one of the paintings of the British artist, Stanley Spencer, housed in Sandham Memorial Chapel. The measurement perio… Show more

“…The evaluation of indoor air quality is presently a widespread environmental issue. , Indoor pollutants consisting of VOCs may cause environmental illness. , The effect of VOCs on human health was brought to the fore during 2007–2009, due to illnesses caused by poorly made residential/commercial dry walls. − However, the presence of low concentrations and the large diversity of VOCs has made their detection a challenging task. , Thus, there is increased demand for the development of a continuous real-time technique to monitor indoor VOCs. Recently, nanocomposites fabricated using electrochemical or self-assembly of metal/metal oxide nanoparticles on top of functionalized conducting polymer film surfaces, has enabled the selective sensing of VOCs .…”

“…Rapidly increasing environmental pollution has been recognized as a major concern, and its monitoring has become a priority area for human health. − This fact has led efforts to find new and user-friendly techniques for the detection of gases hazardous to the environment and human health . Gas sensors (Figure ) have become one of the key technologies for rapid, selective, sensitive, and efficient detection of gases (at ppt level), chemical vapors (at ∼1 ppb), and explosives (at ∼5 ppm). , The commercialization of gas sensors for environmental and personalized health monitoring is growing rapidly .…”

Organic–Inorganic Hybrid Nanocomposite-Based Gas Sensors for Environmental Monitoring

“…The evaluation of indoor air quality is presently a widespread environmental issue. , Indoor pollutants consisting of VOCs may cause environmental illness. , The effect of VOCs on human health was brought to the fore during 2007–2009, due to illnesses caused by poorly made residential/commercial dry walls. − However, the presence of low concentrations and the large diversity of VOCs has made their detection a challenging task. , Thus, there is increased demand for the development of a continuous real-time technique to monitor indoor VOCs. Recently, nanocomposites fabricated using electrochemical or self-assembly of metal/metal oxide nanoparticles on top of functionalized conducting polymer film surfaces, has enabled the selective sensing of VOCs .…”

“…Rapidly increasing environmental pollution has been recognized as a major concern, and its monitoring has become a priority area for human health. − This fact has led efforts to find new and user-friendly techniques for the detection of gases hazardous to the environment and human health . Gas sensors (Figure ) have become one of the key technologies for rapid, selective, sensitive, and efficient detection of gases (at ppt level), chemical vapors (at ∼1 ppb), and explosives (at ∼5 ppm). , The commercialization of gas sensors for environmental and personalized health monitoring is growing rapidly .…”

Organic–Inorganic Hybrid Nanocomposite-Based Gas Sensors for Environmental Monitoring

“…The VOCs have been identied to be the causes of a disease called building-related illness. [1][2][3][4] The sensing of VOCs is also important for early detection of diseases by breath analysis. The practically feasible devices for sensing VOCs should consist of a low cost sensing element with tunable properties.…”

Enhanced sensitivity and selectivity of brush-like SnO₂nanowire/ZnO nanorod heterostructure based sensors for volatile organic compounds

“…There have been some reports on the monitoring of indoor air quality (IAQ) [1][2][3][4], human activity [5], and the chemcomposed of the tight binding molecular networks by means of the intermolecular interactions between amino, carboxyl, and hydroxyl groups. This structural characteristic makes biomaterials possible for sputtering process.…”

Classification and characterization of atmospheric VOCs based on sorption/desorption behaviors of plasma polymer films