Mark Ciappesoni scite author profile

Plasmon based field effect transistors (FETs) can be used to convert energy induced by incident optical radiation to electrical energy. Plasmonic FETs can efficiently detect incident light and amplify it by coupling to resonant plasmonic modes thus improving selectivity and signal to noise ratio. The spectral responses can be tailored both through optimization of nanostructure geometry as well as constitutive materials. In this paper, we studied various plasmonic nanostructures using gold for a wideband spectral response from visible to near-infrared. We show, using empirical data and simulation results, that detection loss exponentially increases as the volume of metal nanostructure increases and also a limited spectral response is possible using gold nanostructures in a plasmon to electric conversion device. Finally, we demonstrate a plasmon FET that offers a broadband spectral response from visible to telecommunication wavelengths.

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Computational study for optimization of a plasmon FET as a molecular biosensor

Ciappesoni

Cho

Tian

et al. 2018

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Localized surface plasmon resonance sensor for magnetic field detection

Ciappesoni

Tian

Iftekhar

et al. 2021

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Fabrication and characterization of titanium-alloy 3D printed solenoid inductors and their sensor applications

et al. 2021

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Recent progress in 3D printing has brought many interests in developing functional devices in various applications by enabling the exploration of complex 3D structures. This paper presents the first fully metal printed standalone 3D solenoid microinductors using a high-power laser with a biocompatible Ti-alloy. Fine powder-based 6AL-4V Eli Titanium was directly printed using an automated gantry laser system with 60 μm resolution to form the inductors without any substrate. A substrate-less 10-turn solenoid as a testbed was printed out and characterized, and additional designs of 20 and 40 turn inductors were further explored. The wire of the inductor was designed to have a 700-micron square cross-section and a winding gap of 300 microns. The successfully fabricated 10-turn titanium-alloy solenoid inductor showed an average inductance of 130 nH, a low-frequency resistance of 0.8 ohms at 0.3 MHz, and a quality factor of 10.5 at 30 MHz respectively. Additional electrodeposition of copper to the 10-turn inductor demonstrated process compatibility with the conventional micromachining process. The standalone inductor printing method saves a significant volume from where the conventional substrate dimensions often take more than the volume of the device. Also, the standalone inductor can directly be used as a sensor device. Examples of force-displacement sensing applications were presented using the 10-turn and 19-turn round edge solenoid inductors.

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Mark Ciappesoni

All 3D printed energy harvester for autonomous and sustainable resource utilization

Efficient broadband energy detection from the visible to near-infrared using a plasmon FET

Computational study for optimization of a plasmon FET as a molecular biosensor

Localized surface plasmon resonance sensor for magnetic field detection

Fabrication and characterization of titanium-alloy 3D printed solenoid inductors and their sensor applications

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