High Performance Multiwall Carbon Nanotube–Insulator–Metal Tunnel Diode Arrays for Optical Rectification

Abstract: The operating regime of MIM diodes is governed by its cutoff frequency. High frequency operation requires ultralow diode capacitance, C D , and low diode resistance, R D . Capacitance can be lowered by fabricating structures with minimal diode area or using a thick dielectric. However, increasing the dielectric thickness will exponentially increase diode resistance by hindering electron tunneling probability through a wider energy barrier. [13] In addition to the barrier width, the height of the tunneling barr… Show more

“…Among the fundamental parameters determining the actual photocurrent generated by the nanorectenna device, we shall recognize the barrier height, barrier thickness, and tunneling area. In this regard, as demonstrated in previous theoretical and experimental studies, [17,[22][23][24]55] studies, when a tunnel junction is illuminated with radiation of energy ℏω ph , an AC voltage of the form V opt • cos(ω ph • t) develops across the junction which leads to a net DC current component. This DC component, following Tien-Gordon and Tucker formulation, is described by the time-averaged Photon-Assisted Tunneling (PAT) theory: [56][57][58]…”

“…In this respect, the tables in Figure 6c,d show three different efficiencies obtained for both λ = 1064 nm and λ = 780 nm, respectively. In particular, the full cone-geometrical efficiency aims at a straight comparison to the works of Sharma et al and Anderson et al, [22][23][24] which report the best to date efficiencies of ≈10 -6 % (for λ = 532, 638, and 1064 nm). Our configuration provides an improved efficiency 2.3 × 10 -4 % at λ = 1064 nm and FF = 0.25 (as resulting from the triangle shape of Figure 3a).…”

“…Apart from these futuristic and fascinating scenarios, the rectenna concept has been demonstrated in the infrared range [13][14][15][16][17][18][19][20] also by employing 2D materials, [20,21] while in the visible range an interesting solution relying on carbon nanotubes (CNTs) was introduced, reaching conversion efficiency up to ≈10 -6 %. [22][23][24] The limited efficiency values obtained at high-frequencies are attributed to non-optimal geometry of CNTs and fabrication challenges inherent to the bottom-up fabrication process.…”

High‐Frequency Light Rectification by Nanoscale Plasmonic Conical Antenna in Point‐Contact‐Insulator‐Metal Architecture

“…Among the fundamental parameters determining the actual photocurrent generated by the nanorectenna device, we shall recognize the barrier height, barrier thickness, and tunneling area. In this regard, as demonstrated in previous theoretical and experimental studies, [17,[22][23][24]55] studies, when a tunnel junction is illuminated with radiation of energy ℏω ph , an AC voltage of the form V opt • cos(ω ph • t) develops across the junction which leads to a net DC current component. This DC component, following Tien-Gordon and Tucker formulation, is described by the time-averaged Photon-Assisted Tunneling (PAT) theory: [56][57][58]…”

“…In this respect, the tables in Figure 6c,d show three different efficiencies obtained for both λ = 1064 nm and λ = 780 nm, respectively. In particular, the full cone-geometrical efficiency aims at a straight comparison to the works of Sharma et al and Anderson et al, [22][23][24] which report the best to date efficiencies of ≈10 -6 % (for λ = 532, 638, and 1064 nm). Our configuration provides an improved efficiency 2.3 × 10 -4 % at λ = 1064 nm and FF = 0.25 (as resulting from the triangle shape of Figure 3a).…”

“…Apart from these futuristic and fascinating scenarios, the rectenna concept has been demonstrated in the infrared range [13][14][15][16][17][18][19][20] also by employing 2D materials, [20,21] while in the visible range an interesting solution relying on carbon nanotubes (CNTs) was introduced, reaching conversion efficiency up to ≈10 -6 %. [22][23][24] The limited efficiency values obtained at high-frequencies are attributed to non-optimal geometry of CNTs and fabrication challenges inherent to the bottom-up fabrication process.…”

High‐Frequency Light Rectification by Nanoscale Plasmonic Conical Antenna in Point‐Contact‐Insulator‐Metal Architecture

“…These components, combining an antenna and a diode, are called rectenna for "rectifying antenna" (see schematic on figure 3a). It is possible to use Metal -Insulator -Metal (MIM) diodes [13] or even molecular diodes which rectifiying properties are obtained by the asymmetry of the molecule for example with ferrocenyl alkane thiol, which ferrocenyl group is placed either on one side or the other of the molecule [14][15][16]. Figure 3b presents nanopyramids periodically positioned in order to be a set of resonant antennae.…”

From classical optics to nanophotonics

“…Optical rectennas, combining nanoantennas with ultrafast rectifiers, were proposed 4 as an extrapolation of the radio frequency rectennas to enhance conversion efficiency of solar photovoltaic technologies over 80%. 5,6 However, only a few experimental realizations have been reported until now, 7,8 due to the lack of efficiency of actual electron devices in rectifying currents oscillating at hundreds of terahertz. On the other hand, the dimensions of a rectenna are mainly limited by the antenna component, which in a classical radioelectric configuration will always be a fraction of the radiation wavelength (k) and will be related to the radiation frequency (f) through k ¼ c/f (with c being the speed of light).…”

A microcantilever mechanical antenna