Your search keyword '"plant electronics"' showing total 5 results

1. Recent advances in breathable electronics.

Author

Yan, Zhuocheng, Xiong, Jian, Wang, Bin, Gao, Min, Yin, Guangqiang, Hu, Tao, Pan, Taisong, Wang, Xinzhong, and Lin, Yuan

Subjects

POLYDIMETHYLSILOXANE, ARTIFICIAL implants, NANOSTRUCTURED materials, MEDICAL electronics, POROSITY

Abstract

The successful implementation of bioelectronic devices attached to living organism hinges on a number of material and device characteristics, including not only electrical and mechanical performances to gather physiological signals from living organism thus enabling status monitoring, but also permeability or breathability for gas/nutrient exchange between living organisms and surroundings to ensure minimum perturbation of the intrinsic biological function. However, most bioelectronic devices built on planar polymeric substrates, such as polydimethylsiloxane (PDMS), polyurethane (PU), and polyimide (PI), lack efficient gas permeability, which may hinder the emission of volatile compounds from the surface of living organism, affecting the natural metabolism and reducing the comfort of wearing. Thus, achieving permeability or breathability in bioelectronic devices is a significant challenge. Currently, the devices made of gas-permeable materials with porous structures, that combine electronic components with daily garments, such as fibric and textile, offer exciting opportunities for breathable electronics. In this review, several types of gas-permeable materials with their synthesis and processing routes are outlines. Then, two methods for measuring water vapor transmission rate of materials are discussed in depth. Finally, recent progress in the use of gas-permeable materials for the applications of plant- and skin-attached electronics is summarized systematically. [ABSTRACT FROM AUTHOR]

Published

2023

2. Real-time and noninvasive detection of UV-Induced deep tissue damage using electrical tattoos.

Author

Kim, Jae Joon and Andrew, Trisha L.

Subjects

*ULTRAVIOLET radiation, *IONIZING radiation, *CONDUCTING polymers, *RADIATION sources, *RADIATION damage, *TATTOOING

Abstract

Understanding longterm deep tissue damage caused by UV radiation is imperative for ensuring the health and safety of living organisms that are regularly exposed to radiation sources. While existing UV dosimeters can quantify the cumulative amount of radiation to which an organism is exposed, these sensors cannot reveal the presence and extent of internal tissue damage caused by such exposure. Here we describe a method that uses conducting polymer tattoos to detect UV radiation-induced deep tissue damage in living organisms using bioimpedance analysis (BIA), which allows for noninvasive, real-time measurements of body composition and point-of-care assessment of clinical condition. To establish a performance baseline for this method, we quantify the effects of UVA radiation on live plant leaves. Low-energy UVA waves penetrate further into biological tissue, as compared to UVB, UVC and ionizing radiation, and cause longlasting deep tissue damage that cannot be immediately and readily detected using surface-sensitive techniques, such as photogrammetry and epidermal sensors. We show that single-frequency bioimpedance analysis allows for sensitive, real-time monitoring of UVA damage: as UVA dose increases, the bioimpedance of a plant leaf measured at a frequency of 1 kHz linearly decreases until the extent of radiation damage saturates and the specimen is effectively necrotized. We establish a strong correlation between radiation fluence, internal biological damage and the bioimpedance signal measured using our conducting polymer tattoos, which supports the efficacy of our method as a new type of internal biodosimetry. • Vapor-printed conducting polymer tattoos allow for noninvasive bioimpedance measurements on living plants. • Single-frequency bioimpedance analysis quantitatively reveals the extent of deep tissue damage caused by UVA exposure. • A linear correlation between internal biological damage and the bioimpedance signal from vapor-printed tattoos is proven. [ABSTRACT FROM AUTHOR]

Published

2020

3. Dynamic Stability of Organic Conducting Polymers and Its Replication in Electrical Conduction and Degradation Mechanisms

Author

Roland Hauert, Andreas Schilling, Thomas Schweizer, José M.F. Ferreira, Emmanuel F.C. Chimamkpam, and University of Zurich

Subjects

composite materials, Nanoparticle, 02 engineering and technology, 01 natural sciences, Electrochemistry, plant electronics, conducting polymer, nanomaterials, chemistry.chemical_classification, Conductive polymer, nanotechnology, Statistics, Polymer, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, organic electronics, microscopy, measurement and evaluation, 0210 nano-technology, Hybrid material, thermal analysis, energy, land chaos, spectroscopy, 3104 Condensed Matter Physics, Materials science, 530 Physics, sensors and sensing, 1600 General Chemistry, statistical physics, Nanotechnology, 10192 Physics Institute, Ion, Biomaterials, Fragility, nanocomposites, 0103 physical sciences, magnetism and magnetic materials, 010306 general physics, Dopant, land stability, polymer chemistry, 2500 General Materials Science, chemistry, electrical properties, temperature dependent, Degradation (geology), nanoparticles, stability and chaos

Abstract

The evolving usefulness of organic conducting polymers, of metallic or semiconducting type, is primarily dependent on their mechanisms of electrical conduction and degradation. Understanding these mechanisms is crucial for improving the effi ciency and lifetime of technologies derived from this class of polymers. There is demand for a model that provides a vivid and more precise evaluation of the electrical conduction mechanism in these polymers – especially when they act as hosts to guest species, such as acid dopant ions and nanoparticles. If, for example, the motional behavior of a host–guest organic conducting polymer structure, as related to dynamic stability, is either asynchronous or synchronous, is this refl ected in the mechanism of electrical conduction and does it account for the pace of material’s degradation? Here, we demonstrate that the answer is affi rmative: asynchronous structural motions arising due to loosely bound or free guest species within the host polymer lead to anomalous electrical conduction mechanisms, increased fragility and short lifetime, at odds with the synchronous behavior.

Published

2011

4. Synthesis and characterization of hybrid materials derived from polyaniline and lacunary Keggin-type polyoxotungstates

Author

Firasat Hussain, Andreas Engel, Andreas Schilling, Emmanuel F.C. Chimamkpam, Greta R. Patzke, and University of Zurich

Subjects

optical properties, 10120 Department of Chemistry, spectroscopy, Nanostructure, 530 Physics, Heteroatom, Nanotechnology, 10192 Physics Institute, Inorganic Chemistry, chemistry.chemical_compound, polymer nanocomposites, Polyaniline, nanocomposites, 540 Chemistry, polyoxometalates, conducting polymer, plant electronics, Lacunary function, Lone pair, nanomaterials, Conductive polymer, nanotechnology, Chemistry, 1604 Inorganic Chemistry, Characterization (materials science), organic electronics, Chemical engineering, electrical properties, microscopy, Hybrid material, energy

Abstract

Organic-inorganic hybrid materials are an upcoming class of materials that attract increasing research interest. In the present manuscript, we report on the combination of a particularly versatile organic matrix – the conductive polymer polyaniline (PAni) – with a special type of polyoxometalates (POMs), namely a lacunary Keggin anion, [AsW9O33]9–. Although the high application potential and the manifold structural motifs of POMs provide an almost infinite number of options for composite materials, up to now, only few POM-polymer combinations have been explored in more detail. Thus, we have investigated the interaction of PAni with the unique reactivity of [AsW9O33]9– that combines building-block facilities with the presence of a lone pair on the heteroatom. The resulting composite material was characterized with a wide spectrum of analytical techniques and the effect on the reaction conditions on the nanoscale structuring was investigated. Furthermore, the newly synthesized POM-PAni composites display a stable temperature-dependent resistivity that renders them promising for further applications.

Published

2009

5. Rapid one-step chemical synthesis of polyaniline-manganese ferrite nanocomposites without external initiator and mechanical agitation

Author

Chimamkpam, Emmanuel F.C., Schweizer, Thomas, Schilling, Andreas, and Ferreira, Jose M.F.

Subjects

optical properties, energy harvesting, magnetic nanoparticles and nanostructures, 7. Clean energy, biomaterial applications, renewable energy, thermal stability, organic electronics, lifetime of organic electronics, nanocomposites, electrical properties, nanoparticles, magnetism and magnetic Materials, conducting polymers and their nanocomposites, plant electronics, UV/Vis spectroscopy, conducting polymers, calorimetry, nanomaterials, thermal analysis, energy

Abstract

We describe a rapid one-step, room temperature method to chemically synthesize bulk quantities of nanocomposites comprising specifically of manganese ferrite (MnFe2O4) and polyaniline (conductive form). Typically a chemical agent, for example ammonium peroxydisulfate, is used to start the polymerization of aniline in the presence of ferrites, and stirring of the reaction system for several hours is also very common. Our approach allows for the nanocomposites to be formed in less than thirty minutes without adding an external polymerization initiator/surfactant and applying any form of mechanical agitation. This process affords the possibility to grow thin films of polyaniline-MnFe2O4 directly on device substrates. Structural, thermal, magnetic and electrical studies did reveal significant chemical interactions between MnFe2O4 and polyaniline matrix. The nanocomposites are magnetic semiconductors with long rod-shaped structures of average diameter in the nanometer scale range and optical properties resembling that of conductive polyaniline. They exhibit a positive magnetoresistance across all temperature ranges with a minimum at around 250 K, corresponding to the temperature for their uniform-to-irregular transition in dynamic stability behavior and likewise coinciding with a minimum in their profile of electrical conduction mechanism (one-dimensional variable range hopping below 250 K) – these complementarities are important for hybrid spintronic applications., Swiss National Science Foundation SNSF PP002–114711/1; Portuguese Foundation for Science and Technology FCT PTDC/CTM/099489/2008 ISBN: 978-1-4398-7142-3