TY - JOUR
T1 - Engineered design and fabrication of long lifetime multifunctional devices based on electrically conductive diamond ultrananowire multifinger integrated cathodes
AU - Saravanan, Adhimoorthy
AU - Huang, Bohr Ran
AU - Manoharan, Divinah
AU - Kathiravan, Deepa
AU - Lin, I. Nan
N1 - Publisher Copyright:
© The Royal Society of Chemistry 2016.
PY - 2016
Y1 - 2016
N2 - Multi-functional vacuum electron field emission (VEFE) devices were developed using a laterally arranged multi-finger configuration with negative biased ultrananocrystalline-diamond graphite (NBG-UNDG) cathode/anode materials. The NBG-UNDG based multifinger lateral electron field emitter (ML-EFE) devices were fabricated using micropatterning and a simple lift-off process. The fabrication process of ML-EFE devices is observed to markedly enhance the electron field emission (EFE) properties of NBG-UNDG materials. The EFE investigations of ML-EFE devices revealed a low turn-on field for EFE at a voltage as low as 2.02 V μm-1 with a high current density of 1.51 mA at an electric field of 2.6 V μm-1. The presence of multi-layer nanographite (ng) in NBG-UNDG diamond nanowires and a Au interlayer at the film-to-substrate interface are presumed to be the main factors, which result in superior EFE properties for NBG-UNDG ML-EFE devices. The enhanced properties of NBG-UNDG based multifinger integrated cathodes have noteworthy potential for the generation of new display panel applications. Using NBG-UNDG ML-EFE devices as cathodes, a microplasma device was fabricated that can generate plasma at a low voltage of 260 V. Also, a photodetector, which provides an excellent photoresponsivity of 1.7 A W-1, was demonstrated using NBG-UNDG ML-EFE devices as sensing materials. Moreover, a NBG-UNDG based self-aligned cathode and gate VEFE transistor was fabricated, which exhibits enhanced transistor characteristics with a low turn-on gate voltage of 320 V. The fabrication of these NBG-UNDG devices, which can be operated at high power and under various vacuum conditions with long lifetime, demonstrates a practical approach in diamond based vacuum microelectronics and integrated circuits.
AB - Multi-functional vacuum electron field emission (VEFE) devices were developed using a laterally arranged multi-finger configuration with negative biased ultrananocrystalline-diamond graphite (NBG-UNDG) cathode/anode materials. The NBG-UNDG based multifinger lateral electron field emitter (ML-EFE) devices were fabricated using micropatterning and a simple lift-off process. The fabrication process of ML-EFE devices is observed to markedly enhance the electron field emission (EFE) properties of NBG-UNDG materials. The EFE investigations of ML-EFE devices revealed a low turn-on field for EFE at a voltage as low as 2.02 V μm-1 with a high current density of 1.51 mA at an electric field of 2.6 V μm-1. The presence of multi-layer nanographite (ng) in NBG-UNDG diamond nanowires and a Au interlayer at the film-to-substrate interface are presumed to be the main factors, which result in superior EFE properties for NBG-UNDG ML-EFE devices. The enhanced properties of NBG-UNDG based multifinger integrated cathodes have noteworthy potential for the generation of new display panel applications. Using NBG-UNDG ML-EFE devices as cathodes, a microplasma device was fabricated that can generate plasma at a low voltage of 260 V. Also, a photodetector, which provides an excellent photoresponsivity of 1.7 A W-1, was demonstrated using NBG-UNDG ML-EFE devices as sensing materials. Moreover, a NBG-UNDG based self-aligned cathode and gate VEFE transistor was fabricated, which exhibits enhanced transistor characteristics with a low turn-on gate voltage of 320 V. The fabrication of these NBG-UNDG devices, which can be operated at high power and under various vacuum conditions with long lifetime, demonstrates a practical approach in diamond based vacuum microelectronics and integrated circuits.
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U2 - 10.1039/c6tc03340g
DO - 10.1039/c6tc03340g
M3 - Article
AN - SCOPUS:84992317268
SN - 2050-7534
VL - 4
SP - 9727
EP - 9737
JO - Journal of Materials Chemistry C
JF - Journal of Materials Chemistry C
IS - 41
ER -