Your search keyword '"Sohini Kar‐Narayan"' showing total 8 results

1. Surface potential tailoring of PMMA fibers by electrospinning for enhanced triboelectric performance

Author

Andrzej Bernasik, Daniel P. Ura, Mateusz M. Marzec, Tommaso Busolo, Urszula Stachewicz, Sung Kyun Kim, Sohini Kar-Narayan, Busolo, T [0000-0003-1815-9557], and Apollo - University of Cambridge Repository

Subjects

Poly(methyl methacrylate), Materials science, Fabrication, Nanotechnology, 02 engineering and technology, Kelvin probe force microscopy, 010402 general chemistry, 01 natural sciences, 7. Clean energy, chemistry.chemical_compound, X-ray photoelectron spectroscopy, Microscopy, General Materials Science, Surface charge, Electrical and Electronic Engineering, Methyl methacrylate, Triboelectric effect, Kelvin probe force microscope, Electrospinning, Energy harvesting, Renewable Energy, Sustainability and the Environment, Triboelectric generator, 021001 nanoscience & nanotechnology, Surface chemistry, 0104 chemical sciences, chemistry, 0210 nano-technology

Abstract

Triboelectric generators rely on contact-generated surface charge transfer between materials with different electron affinities to convert mechanical energy into useful electricity. The ability to modify the surface chemistry of polymeric materials can therefore lead to significant enhancement of the triboelectric performance. Poly(methyl methacrylate) (PMMA) is a biocompatible polymer commonly used in medical applications, but its central position on the triboelectric series, which empirically ranks materials according to their electron-donating or electron accepting tendencies, renders it unsuitable for application in triboelectric generators. Here, we show that the surface potential of PMMA fibers produced by electrospinning can be tailored through the polarity of the voltage used during the fabrication process, thereby improving its triboelectric performance, as compared to typically spin-coated PMMA films. The change in surface chemistry of the electrospun PMMA fibers is verified using X-ray photoelectron spectroscopy, and this is directly correlated to the changes in surface potential observed by Kelvin probe force microscopy. We demonstrate the enhancement of triboelectric energy harvesting capability of the electrospun PMMA fibers, suggesting that this surface potential modification approach can be more widely applied to other materials as well, for improved triboelectric performance.

Published

2019

2. Aerosol-jet-printed, conformable microfluidic force sensors

Author

Qingshen Jing, Anke Husmann, Vikas Khanduja, Nordin Ćatić, Liam Ives, Alizée Pace, Sohini Kar-Narayan, Jehangir Cama, Jing, Qingshen [0000-0002-8147-2047], Ives, Liam [0000-0001-8705-7269], Khanduja, Vikas [0000-0001-9454-3978], Kar-Narayan, Sohini [0000-0002-8151-1616], and Apollo - University of Cambridge Repository

Subjects

interdigitated electrodes, soft robotics, Materials science, aerosol-jet printing, business.industry, Capacitive sensing, Microfluidics, capacitance, General Engineering, Soft robotics, microfluidics, General Physics and Astronomy, General Chemistry, conformable force sensor, Conformable matrix, Capacitance, flexible electronics, Article, Flexible electronics, General Energy, Optoelectronics, Microelectronics, General Materials Science, business, Layer (electronics)

Abstract

Summary Force sensors that are thin, low-cost, flexible, and compatible with commercial microelectronic chips are of great interest for use in biomedical sensing, precision surgery, and robotics. By leveraging a combination of microfluidics and capacitive sensing, we develop a thin, flexible force sensor that is conformable and robust. The sensor consists of a partially filled microfluidic channel made from a deformable material, with the channel overlaying a series of interdigitated electrodes coated with a thin, insulating polymer layer. When a force is applied to the microfluidic channel reservoir, the fluid is displaced along the channel over the electrodes, thus inducing a capacitance change proportional to the applied force. The microfluidic molds themselves are made of low-cost sacrificial materials deposited via aerosol-jet printing, which is also used to print the electrode layer. We envisage a large range of industrial and biomedical applications for this force sensor., Graphical abstract, Highlights Highly flexible, capacitive force sensors based on microfluidics Linear capacitance response to applied force Rapid prototyping of low-cost and robust force sensors via aerosol-jet printing Tunable design for various sensitivities and force measurement ranges, Jing et al. report a thin, conformable force sensor based on a combination of microfluidics and capacitive sensing. The low-cost sensor is fabricated via aerosol-jet printing and shows a highly linear response with adjustable design parameters for tunable sensitivities and force ranges.

Published

2021

3. Conformable and robust microfluidic force sensors to enable precision joint replacement surgery

Author

Liam Ives, Alizée Pace, Fabian Bor, Qingshen Jing, Tom Wade, Jehangir Cama, Vikas Khanduja, Sohini Kar-Narayan, Ives, Liam [0000-0001-8705-7269], Khanduja, Vikas [0000-0001-9454-3978], Kar-Narayan, Sohini [0000-0002-8151-1616], and Apollo - University of Cambridge Repository

Subjects

Force sensor, Additive manufacturing, Mechanics of Materials, Mechanical Engineering, Microfluidics, Orthopaedic surgery, Total hip replacement, General Materials Science

Abstract

Balancing forces within weight-bearing joints such as the hip during joint replacement surgeries is essential for implant longevity. Minimising implant failure and the corresponding need for expensive and difficult revision surgery is vital to both improve patient quality of life and lighten the burden on overstretched healthcare systems. However, force balancing during total hip replacements is presently entirely dependent on surgical skill, as there are no sensors capable of providing quantitative force feedback within the small and complex geometry of the hip joint. Here, we solve this unmet clinical need by presenting a thin and conformable microfluidic force sensor, which is compatible with the standard surgical process. The sensors are fabricated via additive manufacturing, using a combination of 3D and aerosol-jet printing. We optimised the design using finite element modelling, then incorporated and calibrated our sensors in a 3D printed model hip implant. Using a bespoke testing rig, we demonstrated high sensitivity at typical forces experienced during hip replacements. We anticipate that these sensors will aid implant positioning, increasing the lifetime of hip replacements, and represent a powerful new surgical tool for a range of orthopaedic procedures where force balancing is crucial.

Published

2022

4. Electro-responsive surfaces with controllable wrinkling patterns for switchable light reflection–diffusion–grating devices

Author

Casey Wojcik, Yeon Sik Choi, Tiesheng Wang, Sohini Kar-Narayan, I-Ting Lin, Stoyan K. Smoukov, Kar-Narayan, Sohini [0000-0002-8151-1616], and Apollo - University of Cambridge Repository

Subjects

Materials science, 02 engineering and technology, Deformation (meteorology), engineering.material, Grating, 010402 general chemistry, 01 natural sciences, Tortuosity, 4016 Materials Engineering, Coating, General Materials Science, Anisotropy, Microscale chemistry, 40 Engineering, 3403 Macromolecular and Materials Chemistry, 34 Chemical Sciences, business.industry, Mechanical Engineering, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0104 chemical sciences, Mechanics of Materials, Electrode, engineering, Optoelectronics, Wetting, 0210 nano-technology, business

Abstract

Dynamic microscale surface topographies are desired in smart optics, controlling surface wettability and preventing marine biofouling. Voltage-controlled reversible responses have demonstrated potential for reliable reproducibility and stability, fast response, and for actuating thin films fixed over large solid surfaces. To obtain reversible deformation with regular geometric patterns, however, electrical methods have had to be coupled with mechanical stretching/bending and other ways to induce anisotropy. There is a great need and potential for on-demand electrical generation of programmable complex responsive surface patterns. Here we demonstrate a responsive polymer coating over an underlying pattern of counter electrodes which can be activated selectively. We present a patternable electrode printing method to achieve localized and structured wrinkling deformation without mechanical pre-force deformation. We discover that below a minimal separation distance, electrodes below the polymer act as a single electrode. We establish parameters that govern the alignment of wrinkles and quantify the regularity and direction of the new patterns between electrodes separated by larger than this distance. We analyze and quantify the regularity of the formed wrinkling patterns by four disorder metrics: box-counting fractal dimension, tortuosity, angle distribution, and branch number. We demonstrate the application of such electrode/wrinkles-on-demand patterning with a working multi-state light reflection–diffusion–grating device.

Published

2020

5. Aerosol-Jet Printed Conformable Microfluidic Force Sensors

Author

Vikas Khanduja, Alizée Pace, Sohini Kar-Narayan, Jehangir Cama, Anke Husmann, Liam Ives, Qingshen Jing, and Nordin Ćatić

Subjects

Permittivity, Fabrication, Materials science, business.industry, Capacitive sensing, Microfluidics, Hardware_INTEGRATEDCIRCUITS, Microelectronics, Optoelectronics, Conformable matrix, business, Layer (electronics), Capacitance

Abstract

Force sensors that are thin, low cost, flexible and compatible with commercial microelectronic chips are of great interest for use in biomedical sensing, precision surgery, robotics and in various “smart control” technologies. By leveraging a novel combination of microfluidics and capacitive sensing we have developed a thin, flexible force sensor that is conformable and robust. The sensor consists of a partially filled microfluidic channel made from a deformable material, with the channel overlaying a series of interdigitated electrodes that are coated with a thin polymer layer for insulation. When a force is applied to a fluid reservoir at the base of the channel, the fluid is displaced along the channel, passing over the electrodes and thus inducing a capacitance change, which is proportional to the amount of force applied. The microfluidic molds themselves are made of low-cost sacrificial material inks deposited via aerosol-jet printing, which is also used to print the electrode layer. The sensors exhibit a nearly linear change in capacitance in response to external load, with a sensitivity of up to 3.8 pF/N and a force range of up to 9 N achieved with the present design. We quantify the effects of changing the electrode morphology, liquid permittivity, sensor thickness and geometry, as well as the thickness of the insulation layer over the electrodes, on sensor range and sensitivity, using a combination of experiments and finite element analysis simulations. We further demonstrate how the sensor can be used to remotely control a robotic clamp. The conformable force sensors developed here are thin, flexible and facilitate easy signal processing. The fabrication processes are low-cost, amenable to fast prototyping and mass manufacturing. We envisage a large range of industrial and biomedical applications for this novel force sensor.

Published

2020

6. Enhanced piezoelectricity and electromechanical efficiency in semiconducting GaN due to nanoscale porosity

Author

Yonatan Calahorra, Tongtong Zhu, Peter Griffin, Tommaso Busolo, Sohini Kar-Narayan, Adina Wineman, Piotr K. Szewczyk, Qingshen Jing, Rachel A. Oliver, Bogdan F. Spiridon, Calahorra, Yonatan [0000-0001-9530-1006], Busolo, Tommaso [0000-0003-1815-9557], Jing, Qingshen [0000-0002-8147-2047], Oliver, Rachel [0000-0003-0029-3993], Kar-Narayan, Sohini [0000-0002-8151-1616], and Apollo - University of Cambridge Repository

Subjects

Materials science, 02 engineering and technology, 010402 general chemistry, 7. Clean energy, 01 natural sciences, GaN, Stress (mechanics), Atomic force microscopy, chemistry.chemical_compound, Figure of merit, Porous materials, General Materials Science, Polarization (electrochemistry), Porosity, Mechanical energy, Energy harvesting, business.industry, 021001 nanoscience & nanotechnology, Piezoelectricity, 0104 chemical sciences, Piezoresponse force microscopy, chemistry, Barium titanate, Optoelectronics, Piezoelectric, 0210 nano-technology, business

Abstract

Electrical polarization phenomena in GaN are important as they have significant impact on the operation of modern day energy efficient lighting and are fundamental to GaN-based high power and high frequency electronics. Controlling polarization is beneficial for the optimization of these applications. GaN is also piezoelectric, and therefore mechanical stress and strain are possible handles to control its polarization. Nonetheless, polar semiconductors in general, and GaN in particular, are weak piezoelectric materials when compared to ceramics, and are therefore not considered for characteristic electromechanical applications such as sensing, actuation and mechanical energy harvesting. Here, we examine the effect of nanoscale porosity on the piezoelectricity of initially conductive GaN. We find that for 40% porosity, the previously conductive GaN layer becomes depleted, and exhibits enhanced piezoelectricity as measured using piezoresponse force microscopy, as well as by using a mechanical energy harvesting setup. The effective piezoelectric charge coefficient of the porous GaN, d33,eff, is found to be about 8 pm/V which is 2-3 times larger than bulk GaN. A macroscale device comprising a porous GaN layer delivered 100 nW/cm2 across a resistive load under a 150 kPa mechanical excitation. We performed finite element simulations to analyze the evolution of the piezoelectric properties with porosity. The simulations suggest that increased mechanical compliance due to porosity gives rise to the observed enhanced piezoelectricity in GaN. Furthermore, the simulations show that for stress-based excitations, the porous GaN electromechanical figure of merit is increased by an order of magnitude and becomes comparable to that of barium titanate piezoceramics. In addition, considering the central role played by GaN in modern electronics and optoelectronics, our study validates a very promising research direction when considering stress-based electromechanical applications which combine GaN's semiconducting and piezoelectric properties.

Published

2020

7. Surface potential and roughness controlled cell adhesion and collagen formation in electrospun PCL fibers for bone regeneration

Author

Urszula Stachewicz, Mateusz M. Marzec, Sung Kyun Kim, Sara Ferraris, Piotr K. Szewczyk, Magdalena Wytrwal-Sarna, Andrzej Bernasik, Łukasz Kaniuk, Sohini Kar-Narayan, Zuzanna J. Krysiak, Silvia Maria Spriano, Adam Gruszczyński, Joanna E. Karbowniczek, and Sara Metwally

Subjects

Mineralization, Materials science, Scanning electron microscope, Cells, 02 engineering and technology, Kelvin probe force microscopy, 010402 general chemistry, 01 natural sciences, Microscopy, lcsh:TA401-492, Zeta potential, General Materials Science, Cell adhesion, Bone regeneration, Kelvin probe force microscope, Mechanical Engineering, Surface potential, technology, industry, and agriculture, Adhesion, 021001 nanoscience & nanotechnology, Electrospinning, 0104 chemical sciences, Mechanics of Materials, Biophysics, lcsh:Materials of engineering and construction. Mechanics of materials, 0210 nano-technology

Abstract

Surface potential of biomaterials is a key factor regulating cell responses, driving their adhesion and signaling in tissue regeneration. In this study we compared the surface and zeta potential of smooth and porous electrospun polycaprolactone (PCL) fibers, as well as PCL films, to evaluate their significance in bone regeneration. The ’ surface potential of the fibers was controlled by applying positive and negative voltage polarities during the electrospinning. The surface properties of the different PCL fibers and films were measured using X-ray photoelectron spectroscopy (XPS) and Kelvin probe force microscopy (KPFM), and the zeta potential was measured using the electrokinetic technique. The effect of surface potential on the morphology of bone cells was examined using advanced microcopy, including 3D reconstruction based on a scanning electron microscope with a focused ion beam (FIB-SEM). Initial cell adhesion and collagen formation were studied using fluorescence microscopy and Sirius Red assay respectively, while calcium mineralization was confirmed with energy-dispersive x-ray (EDX) and Alzarin Red staining. These studies revealed that cell adhesion is driven by both the surface potential and morphology of PCL fibers. Furthermore, the ability to tune the surface potential of electrospun PCL scaffolds provides an essential electrostatic handle to enhance cell-material interaction and cellular activity, leading to controllable morphological changes.

Published

2020

8. A fluctuation-based characterization of athermal phase transitions: Application to shape memory alloys

Author

U. Chandni, Sohini Kar-Narayan, H. S. Vijaya, Sangeneni Mohan, and Arindam Ghosh

Subjects

Phase transition, Materials science, Polymers and Plastics, Condensed matter physics, Metals and Alloys, Shape-memory alloy, Noise (electronics), Electronic, Optical and Magnetic Materials, Characterization (materials science), Electrical resistivity and conductivity, Nickel titanium, Martensite, Ceramics and Composites, Forensic engineering, Thin film

Abstract

We employ a fluctuation-based technique to investigate the athermal component associated with martensite phase transition, which is a prototype of temperature-driven structural transformation. Statistically, when the phase transition is purely athermal, we find that the temporal sequence of avalanches under constant drive is insensitive to the drive rate. We have used fluctuations in electrical resistivity or noise in nickel titanium shape memory alloys in three different forms: a thin film exhibiting well-defined transition temperatures,a highly disordered film, and a bulk wire of rectangular cross-section. Noise is studied in the realm of dynamic transition,viz.while the temperature is being ramped, which probes into the kinetics of the transformation at real time scales,and could probably stand out as a promising tool for material testing in various other systems, including nanoscale devices.

Published

2009