Showing papers by "Muhammad Mustafa Hussain published in 2022"

The 2021 flexible and printed electronics roadmap

Abstract: Author(s): Bonnassieux, Y; Brabec, CJ; Cao, Y; Carmichael, TB; Chabinyc, ML; Cheng, KT; Cho, G; Chung, A; Cobb, CL; Distler, A; Egelhaaf, HJ; Grau, G; Guo, X; Haghiashtiani, G; Huang, TC; Hussain, MM; Iniguez, B; Lee, TM; Li, L; Ma, Y; Ma, D; McAlpine, MC; Ng, TN; Osterbacka, R; Patel, SN; Peng, J; Peng, H; Rivnay, J; Shao, L; Steingart, D; Street, RA; Subramanian, V; Torsi, L; Wu, Y | Abstract: This roadmap includes the perspectives and visions of leading researchers in the key areas of flexible and printable electronics. The covered topics are broadly organized by the device technologies (sections 1–9), fabrication techniques (sections 10–12), and design and modeling approaches (sections 13 and 14) essential to the future development of new applications leveraging flexible electronics (FE). The interdisciplinary nature of this field involves everything from fundamental scientific discoveries to engineering challenges; from design and synthesis of new materials via novel device design to modelling and digital manufacturing of integrated systems. As such, this roadmap aims to serve as a resource on the current status and future challenges in the areas covered by the roadmap and to highlight the breadth and wide-ranging opportunities made available by FE technologies.

Toward nanotechnology-enabled face masks against SARS-CoV-2 and pandemic respiratory diseases.

Abstract: Wearing a face mask has become a necessity following the outbreak of the coronavirus (COVID-19) disease, where its effectiveness in containing the pandemic has been confirmed. Nevertheless, the pandemic has revealed major deficiencies in the ability to manufacture and ramp up worldwide production of efficient surgical-grade face masks. As a result, many researchers have focused their efforts on the development of low cost, smart and effective face covers. In this article, following a short introduction concerning face mask requirements, the different nanotechnology-enabled techniques for achieving better protection against the SARS-CoV-2 virus are reviewed, including the development of nanoporous and nanofibrous membranes in addition to triboelectric nanogenerators based masks, which can filter the virus using various mechanisms such as straining, electrostatic attraction and electrocution. The development of nanomaterials-based mask coatings to achieve virus repellent and sterilizing capabilities, including antiviral, hydrophobic and photothermal features are also discussed. Finally, the usability of nanotechnology-enabled face masks is discussed and compared with that of current commercial-grade N95 masks. To conclude, we highlight the challenges associated with the quick transfer of nanomaterials-enabled face masks and provide an overall outlook of the importance of nanotechnology in counteracting the COVID-19 and future pandemics.

Graphene and Liquid Metal Integrated Multifunctional Wearable Platform for Monitoring Motion and Human-Machine Interfacing.

Abstract: Motion sensors are an essential component of many electronic systems. However, the development of inertial motion sensors based on fatigue-free soft proof mass has not been explored extensively in the field of soft electronics. Nontoxic gallium-based liquid metals are an emerging class of material that exhibit attractive electromechanical properties, making them excellent proof mass materials for inertial sensors. Here, we propose and demonstrate a fully soft laser-induced graphene (LIG) and liquid metal-based inertial sensor integrated with temperature, humidity, and breathing sensors. The inertial sensor design confines a graphene-coated liquid metal droplet inside a fluidic channel, rolling over LIG resistive electrode. The proposed sensor architecture and material realize a highly mobile proof mass and a vibrational space for its oscillation. The inertial sensor exhibits a high sensitivity of 6.52% m-1 s2 and excellent repeatability (over 12 500 cycles). The platform is fabricated using a scalable, rapid laser writing technique and integrated with a programmable system on a chip (PSoC) to function as a stand-alone system for real-time wireless monitoring of movement patterns and the control of a robotic arm. The developed printed inertial platform is an excellent candidate for the next-generation of wearables motion tracking platforms and soft human-machine interfaces.

Graphene Coated Liquid Metal Droplet‐Enabled Dual‐Axis Integrated Accelerometer

Abstract: This paper presents the design, optimization, fabrication, and characterization of a novel accelerometer consisting of a graphene‐coated liquid metal proof mass integrated with laser‐induced graphene (LIG) resistive sensing elements. The sensor utilizes the unique electromechanical properties of eutectic gallium‐indium (EGaIn) liquid metal by confining an EGaIn droplet within a graphene‐patterned 3D pyramid cavity. The pyramid base structure imposes a restoring force on the droplet enabling continuous and simultaneous sensing in two directions using a single proof mass. Coating EGaIn droplet with graphene forms an interpenetrated protective shell around the droplet, enhancing its mobility and mechanical robustness. Design optimization of the sensing microelectrodes is performed to improve the sensor performance. The accelerometer performance is evaluated and characterized, demonstrating a sensitivity of ≈9.5 kΩ g−1 (978 Ω m−1 s2) and a cross‐axis sensitivity of ≈3 % with excellent repeatability (over 120 000 cycles). The sensor is fabricated using a scalable laser writing technique and integrated with a programmable system on a chip (PSoC) to function as a stand‐alone system for real‐time wireless motion monitoring and virtual game control. The developed Graphene/Liquid metal droplet‐based sensor is promising for applications of inertial sensors, inertial switches, and soft liquid metal robots with attractive electromechanical properties.