Charging and discharging characteristics of a single gold nanoparticle embedded in Al2O3 thin films

Abstract: We demonstrate a metal-oxide-semiconductor based nonvolatile memory element structure with a single isolated gold nanoparticle (Au-NP) acting as the storage site. The Au-NPs are sandwiched between amorphous Al2O3 thin films, deposited using the atomic layer deposition method to form the blocking and tunneling layers. The current voltage characteristics of the fabricated structure during write/erase cycles are obtained using conductive mode atomic force microscopy (C-AFM) by probing a single isolated NP at a ti… Show more

“…Due to the enhancement of the electric field at the nano-probe, the electric field on the probe is quite relatively high at this threshold voltage. This results in a thin tunneling barrier, 43 which allows electrons to tunnel through the CuO into Cu bulk, as shown the Fig. 6(b) and evident in the experimental data in Fig.…”

Single wall carbon nanotube based optical rectenna

“…Due to the enhancement of the electric field at the nano-probe, the electric field on the probe is quite relatively high at this threshold voltage. This results in a thin tunneling barrier, 43 which allows electrons to tunnel through the CuO into Cu bulk, as shown the Fig. 6(b) and evident in the experimental data in Fig.…”

Single wall carbon nanotube based optical rectenna

“…[4][5][6] Several approaches and materials are being intensively investigated to develop small-scale devices, like carbon nanotubes, nanowires, nanoparticles, and graphene-based devices. [7][8][9][10][11] Understanding the electronic structure at the nanoscale is crucial for applications in nano-electronic device design and fabrication, where the electrical characteristics are signicantly dominated by the size of metal-semiconductor interfaces. [12][13][14][15] Quantum dots have emerged as a viable technique for semiconductor devices, notably in memory technology.…”

Physical probing of quantum energy levels in a single indium arsenide (InAs) quantum dot

“…The chemical and physical characteristics of self-assembled nanoparticles (NPs) vary significantly from those of bulk materials, , or even from the corresponding individual NPs. , Considering this fact, NPs have been classified as a new class of functional materials and have found widespread applications in various fields, including electronics, optics, catalysis, and sensing. , Therefore, a precisely controlled method of these NPs in terms of size, shape, and interparticle spacing is essential for fully utilizing their new collective and synergistic features. , NPs, both in colloidal and powdered form, have unique and significant applications in medicine, nanoelectronics, − nanosensors, fundamental research, and other industrial applications. − The uniform size and shape of NPs achieved through various types of synthesis have been overwhelmingly improved to increase the efficiency of NP-based devices in terms of their conductivity, sensitivity, selectivity, etc. However, multiple hurdles have been posed to nanotechnology researchers when it comes to forming NP monolayers on substrates .…”

Electric Field-Driven Self-Assembly of Gold Nanoparticle Monolayers on Silicon Substrates