Your search keyword '"M. Imani"' showing total 6 results

1. Fabrication of Superamphiphobic Surfaces via Spray Coating; a Review

Author

Noor Abu Jarad, Hiba Imran, Sara M. Imani, Tohid F. Didar, and Leyla Soleymani

Subjects

Mechanics of Materials, General Materials Science, Industrial and Manufacturing Engineering

Published

2022

2. Printed Humidity Sensors from Renewable and Biodegradable Materials.

Author

Aeby, Xavier, Bourely, James, Poulin, Alexandre, Siqueira, Gilberto, Nyström, Gustav, and Briand, Danick

Subjects

CAPACITIVE sensors, TEMPERATURE detectors, HUMIDITY, ELECTRONIC waste, DETECTORS, BIODEGRADABLE materials

Abstract

Increasing environmental concerns raised by the accumulation of electronic waste draws attention to the development of sustainable materials for short‐lived electronics. In this framework, printed capacitive humidity sensors and temperature resistive detectors composed exclusively of biodegradable materials: shellac, carbon‐derived particles, and egg‐albumin are reported. The sensor platform comprises interdigitated electrodes serving as a capacitive transducer for humidity sensing, and a serpentine used as a resistive temperature detector. Both the interdigitated and serpentine electrodes are manufactured by screen‐printing carbon ink on a shellac substrate. The humidity sensors are constructed by drop‐coating egg albumin on the interdigitated carbon electrodes and the temperature detector is prepared by encapsulating the serpentine design with shellac. Shellac is shown to be a biodegradable alternative to hydrophilic cellulose‐derived substrates, with the capacitive humidity sensors demonstrating a sensitivity of 0.011% RH−1. The response and recovery times on shellac are 12 and 20 times faster than on cellulose‐based substrate, and the serpentine resistive temperature detectors have a temperature coefficient of 5300 ppm K−1. At the end of their service‐life, the sensors produced are home compostable and can be environmentally friendly disposed, potentially enabling their future use for sustainable and environmentally friendly smart‐packaging, agricultural sensing, or point‐of‐care testing. [ABSTRACT FROM AUTHOR]

Published

2023

3. 3D Printing of Mechanically Elastic, Self‐Adhesive, and Biocompatible Organohydrogels for Wearable and Breathable Strain Sensors.

Author

Guo, Binbin, Zhong, Yukun, Song, Xiaoxia, Chen, Xiaoteng, Zhou, Peng, Zhao, Fuxin, and Bai, Jiaming

Subjects

STRAIN sensors, THREE-dimensional printing, FATIGUE limit, FLEXIBLE electronics, IONIC conductivity, ETHYLENE glycol, GLYCERIN, HYDROGELS

Abstract

Organohydrogel‐based strain sensors have gained increasing attention in the fields of real‐time healthcare and motion detection due to their excellent flexibility, stretchability, and skin‐like compliance. However, the fundamental attributes, such as mechanical elasticity, self‐adhesiveness, and biocompatibility, are challenging to be simultaneously obtained in organohydrogels, limiting their applications in wearable electronics. Additionally, traditional organohydrogels need to be fixed to the surface of the human skin and suffer from inferior breathability, resulting in complicated operations and severe uncomfortableness, respectively. Herein, a multifunctional organohydrogel is designed for wearable strain sensor by a facile digital light processing (DLP) 3D printing technology. By rationally tailoring the chemical (poly(N‐acryloylmorpholine)/poly(ethylene glycol) diacrylate) and physical (poly(N‐acryloylmorpholine)/poly(ethylene glycol) diacrylate and glycerin/water) cross‐linking networks, the organohydrogel exhibits promising water absorption/retention, high stretchability, impressive elasticity, and promising fatigue resistance. Additionally, good ionic conductivity, inherent self‐adhesiveness, and biocompatibility are simultaneously achieved. On the basis of the multifunctionalities, 3D multihole organohydrogels are designated as wearable and breathable strain sensors, facilitating the manipulation without any fixation and increasing the wear comfortableness. It is believed that 3D printed multihole organohydrogels show great potential in wearable flexible electronics. [ABSTRACT FROM AUTHOR]

Published

2023

4. Conducting Polymer Based Ammonia and Hydrogen Sulfide Chemical Sensors and Their Suitability for Detecting Food Spoilage.

Author

Preethichandra, D. M. G., Gholami, Mahnaz D., Izake, Emad L., O'Mullane, Anthony P., and Sonar, Prashant

Subjects

CHEMICAL detectors, FOOD spoilage, CONDUCTING polymers, HYDROGEN sulfide, GAS detectors, ELECTRONIC equipment

Abstract

Food security is critical for the sustainability of society. The spoilage of stocked food is an ongoing problem that causes significant losses to the global economy. Novel portable analytical platforms that provide timely information on the condition of food stock can support informed decision‐making on the safety of food consumption as well as on maximization of food storage lifetime. Ammonia (NH3) and hydrogen sulfide (H2S) are two of the major harmful gases that are produced due to bacteria activity during the food spoilage process. The timely detection of these gases in food stocks has vital importance to human health. In this review article, the recent progress of conducting polymer based NH3 and H2S gas sensors including sensor device prototypes, their sensing mechanisms, materials and methodologies for sensor fabrication, and their suitability for the development of consumer electronic devices for food spoilage detection are highlighted. [ABSTRACT FROM AUTHOR]

Published

2023

5. Fabrication of Superamphiphobic Surfaces via Spray Coating; a Review.

Author

Abu Jarad, Noor, Imran, Hiba, Imani, Sara M., Didar, Tohid F., and Soleymani, Leyla

Subjects

TECHNOLOGICAL innovations, METALLIC oxides, CONSTRUCTION materials, SURFACE coatings, METALLIC composites, SPRAYING, PLASMA sprayed coatings

Abstract

Superamphiphobic coatings that simultaneously repel both water and oil and are applicable to a wide range of surfaces are needed for use in self‐cleaning, anti‐icing, and antimicrobial coatings. Spray coating is a method that can be used to apply such coatings to a wide range of surfaces in a scalable and high throughput manner. This review presents a comprehensive overview of the materials architecture, synthesis, applications, and figures‐of‐merit of superamphiphobic surfaces that are deposited using spray coating. The design requirements of superamphiphobic surfaces—surface roughness and wettability, re‐entrant topographic features, and chemical composition—are initially introduced. Based on the material, different synthesis techniques are then discussed with a focus on metal oxides and metal oxide composites, polymers, emerging, and green materials. The areas of application of superamphiphobic coatings are also presented. Finally, the main hurdles in using such coatings in real‐life applications are discussed in depth, and emerging technologies for overcoming these challenges are presented. [ABSTRACT FROM AUTHOR]

Published

2022

6. Cortical‐Folding‐Inspired Multifunctional Reduced Graphene Oxide Microarchitecture Arrays on Curved Substrates.

Author

Tan, Yinlong, Hu, Biru, Kang, Yan, Jiang, Tian, Li, Guochen, Dong, Qichao, Wu, Wenjian, and Chu, Zengyong

Subjects

WRINKLE patterns, GRAPHENE oxide, STRAIN sensors, MASS production, WEARABLE technology, CURVED surfaces

Abstract

Although controlled wrinkling is demonstrated to be a powerful tool for micro/nanofabrication, large‐area fabrication of microarchitecture arrays on curved substrates by surface wrinkling still remains challenging. Inspired by the cortical folding, a facile method for transforming graphene oxide (GO) patterns into multiscale microarchitecture arrays on curved substrates is developed. Mass production of hierarchical GO papillae arrays can be realized by homogeneous compression of patterned GO/rubber bilayers. The reduced GO (rGO) papillae arrays show superhydrophobicity with tunable adhesion to water, enabling good performance in microdroplet manipulation. Besides, the papillae are capable of regulating the formation of microcracks in the rGO films upon stretching. Similar to the mechanical sensing system of spiders, a crack‐based strain sensor with high gauge factor (≈81), good linearity (0–15%), and fast responding speed (<40 ms) is demonstrated. In addition, the strain sensor is capable of detecting and recognizing multiple deformation modes including stretching, poking, and touching. This work reveals novel cortical folding morphology and provides a simple fabrication method for multifunctional hierarchical microarchitectures on curved substrates, which may find applications in biomimetic microstructures, smart wetting surfaces, and wearable electronics. [ABSTRACT FROM AUTHOR]

Published

2022