Functional Polymers in Sensors and Actuators: Fabrication and Analysis (original) (raw)

Chemosensors

This review illustrates various types of polymer and nanocomposite polymeric based sensors used in a wide variety of devices. Moreover, it provides an overview of the trends and challenges in sensor research. As fundamental components of new devices, polymers play an important role in sensing applications. Indeed, polymers offer many advantages for sensor technologies: their manufacturing methods are pretty simple, they are relatively low-cost materials, and they can be functionalized and placed on different substrates. Polymers can participate in sensing mechanisms or act as supports for the sensing units. Another good quality of polymer-based materials is that their chemical structure can be modified to enhance their reactivity, biocompatibility, resistance to degradation, and flexibility.

Recent Progress, Challenges, and Trends in Polymer-Based Sensors: A Review

Polymers

Polymers are long-chain, highly molecular weight molecules containing large numbers of repeating units within their backbone derived from the product of polymerization of monomeric units. The materials exhibit unique properties based on the types of bonds that exist within their structures. Among these, some behave as rubbers because of their excellent bending ability, lightweight nature, and shape memory. Moreover, their tunable chemical, structural, and electrical properties make them promising candidates for their use as sensing materials. Polymer-based sensors are highly utilized in the current scenario in the public health sector and environment control due to their rapid detection, small size, high sensitivity, and suitability in atmospheric conditions. Therefore, the aim of this review article is to highlight the current progress in polymer-based sensors. More importantly, this review provides general trends and challenges in sensor technology based on polymer materials.

Smart Polymers for Advanced Applications: A Mechanical Perspective Review

Frontiers in Materials, 2020

Responsive materials, as well as active structural systems, are today widely used to develop unprecedented smart devices, sensors, or actuators; their functionalities come from the ability to respond to environmental stimuli with a detectable reaction. Depending on the responsive material under study, the triggering stimuli can have a different nature, ranging from physical (temperature, light, electric or magnetic field, mechanical stress, etc.), chemical (pH, ligands, etc.), or biological (enzymes, etc.) type. Such a responsiveness can be obtained by properly designing the meso-or macroscopic arrangement of the constitutive elements, as occurs in metamaterials, or can be obtained by using responsive materials per se, whose responsiveness comes from the chemistry underlying their microstructure. In fact, when the responsiveness at the molecular level is properly organized, the nanoscale response can be collectively detected at the macroscale, leading to a responsive material. In the present article, we review the enormous world of responsive polymers, by outlining the main features, characteristics, and responsive mechanisms of smart polymers and by providing a mechanical modeling perspective, both at the molecular as well as at the continuum scale level. We aim at providing a comprehensive overview of the main features and modeling aspects of the most diffused smart polymers. The quantitative mechanical description of active materials plays a key role in their development and use, enabling the design of advanced devices as well as to engineer the materials' microstructure according to the desired functionality.

The Development of Wearable Polymer-Based Sensors: Perspectives

2020

The development of smart polymer materials is reviewed and illustrated. Important examples of these polymers include conducting polymers, ionic gels, stimulus-response be used polymers, liquid crystalline polymers and piezoelectric materials, which have desirable properties for use in wearable sensors. This review outlines the mode of action in these types of smart polymers systems for utilisation as wearable sensors. Categories of wearable sensors are considered as tattoo-like designs, patch-like, textile-based, and contact lens-based sensors. The advantages and disadvantages of each sensor types are considered together with information on the typical performance. The research gap linking smart polymer materials to wearable sensors with integrated power systems is highlighted. Smart polymer systems may be used as part of a holistic approach to improve wearable devices and accelerate the integration of wearable sensors and power systems, particularly in health care.

Review-The Development of Wearable Polymer-Based Sensors: Perspectives

Journal of The Electrochemical Society, 2020

Functional Polymers Structures for (Bio)Sensing Application—A Review

Polymers, 2020

In this review we present polymeric materials for (bio)sensor technology development. We focused on conductive polymers (conjugated microporous polymer, polymer gels), composites, molecularly imprinted polymers and their influence on the design and fabrication of bio(sensors), which in the future could act as lab-on-a-chip (LOC) devices. LOC instruments enable us to perform a wide range of analysis away from the stationary laboratory. Characterized polymeric species represent promising candidates in biosensor or sensor technology for LOC development, not only for manufacturing these devices, but also as a surface for biologically active materials’ immobilization. The presence of biological compounds can improve the sensitivity and selectivity of analytical tools, which in the case of medical diagnostics is extremely important. The described materials are biocompatible, cost-effective, flexible and are an excellent platform for the anchoring of specific compounds.

Design and fabrication of a largely deformable sensorized polymer actuator

Biosensors and Bioelectronics, 2005

Polypyrrole (PPy), with its biomimetic properties such as high power density, large strain, and biocompatibility, is an excellent candidate for a biomimetic microactuator in microrobotics and bioengineering. A polyvinylidene fluorid (PVDF) sensor is also biocompatible, flexible, and chemically stable. Therefore, a PPy actuator is integrated with a PVDF sensor to realize a sensorized polymer actuator. A novel sensorized polymer actuator can accurately measure its bending motion precisely with real time. Experimental results demonstrate the feasibility of the sensorized polymer actuator. The polymer actuator can be actuated while it senses signals induced from the bending motion. In addition, the position of the sensorized polymer actuator can be controlled and adjusted precisely with feedback signals from its embedded sensor at the time of operation. If this system becomes more robust and reliable, its applications are promising and can be realized in cell handling, microrobotics, and microsurgery with the integration of standard microfabrication techniques.

Design and fabrication of a large-deformed smart sensorized polymer actuator

2004 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) (IEEE Cat. No.04CH37566), 2004

The demands for actuators featuring biomimetic properties, such as high power density, large strain, and biocompatibility are growing in microrobotics and bioengieering. PPy is one candidate for biomimetic actuator since it is biocompatible, easy to be fabricated by MEMS technique, has large strain, and consumes low energy. In this paper, a novel sensorized polymer actuator which can measure its bending motion precisely with real-time is presented. It is fabricated by integrating polypyrrole(PPy) actuator with polyvinylidenefluorid(PVDF) sensor. Since PVDF is also biocompatible, stable to chemical, flexible, and polymer senor, it could be well combined with PPy actuator. In experimental results, the proposed actuator shows the feasibility which can not only be actuated with large strain (a few mm) but also produce meaningful signals which made from bending motion and vice versa.

Flexible Sensors Based on Conductive Polymers

Chemosensors, 2022

Conductive polymers have attracted wide attention since their discovery due to their unique properties such as good electrical conductivity, thermal and chemical stability, and low cost. With different possibilities of preparation and deposition on surfaces, they present unique and tunable structures. Because of the ease of incorporating different elements to form composite materials, conductive polymers have been widely used in a plethora of applications. Their inherent mechanical tolerance limit makes them ideal for flexible devices, such as electrodes for batteries, artificial muscles, organic electronics, and sensors. As the demand for the next generation of (wearable) personal and flexible sensing devices is increasing, this review aims to discuss and summarize the recent manufacturing advances made on flexible electrochemical sensors

Functional Polymers in Sensors and Actuators: Fabrication and Analysis (original) (raw)

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