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Beilstein J. Nanotechnol. 2023, 14, 683–691, doi:10.3762/bjnano.14.54
Figure 1: Scanning electron microscopy: (a) CuO nanowires grown on Cu substrate by thermal oxidation; (b) sys...
Figure 2: Impedance spectra measured for the system of CuO nanowire networks on microelectrodes at fixed T (3...
Figure 3: (a) Impedance magnitude |Z| vs relative humidity RH (dashed line is a guide to the eyes) at various ...
Figure 4: Normalized equivalent circuit parameters as functions of RH: (a) resistances R1 and R2 and (b) the ...
Beilstein J. Nanotechnol. 2018, 9, 271–300, doi:10.3762/bjnano.9.29
Figure 1: Schematics of electrostatically actuated 2T NEM nanobeam-based switches. Top panel: single-clamped ...
Figure 2: a) Plots of total energy ET calculated for a Ge nanowire-based NEM device at different electrostati...
Figure 3: Operation of a 2T switch with a semi-paddle configuration. a) Image of the fabricated switch and sc...
Figure 4: a) Example of 2T nanowire-based NEM switching between two symmetrically located drain electrodes an...
Figure 5: Schematics of electrostatically actuated 3T NEM nanobeam-based switches. Top panel: single-clamped ...
Figure 6: Resonant oscillations of the switching element as an effective solution to overcome on-state adhesi...
Figure 7: Switching cycles of Mo6S3I6 nanowire-based NEM switch illustrating the impact of the contact area o...
Figure 8: Size-dependent tuning of the mechanism of electrical conduction through a nanocontact. a) Experimen...
Figure 9: a) Experimental setup for in situ SEM investigation of processes occurring in nanocontacts. b) Grap...
Figure 10: a) NEM switch with graphene sheet as the active element. Reprinted with permission from [25], copyright...
Figure 11: a) Schematics and design of U-shaped dual Si beam NEM switch. Reprinted with permission from [20], copy...
Figure 12: Different jump-in I(V) characteristics of a) bare, thin SiC beams (SiC–SiC contact) showing gradual...
Figure 13: Materials properties for NEM switching elements. Marker coordinates correspond to the electrical co...
Figure 14: Quality factor as a function of air pressure showing the transition from molecular (solid lines) to...
Figure 15: Scaling impact on the capillary/elastic force ratio. The impact of reducing the length of the switc...
Figure 16: I(V) characteristics of Ge nanowire with and without an oxide layer. Reprinted with permission from ...
Figure 17: Temperature impact on NEM switch hysteresis. Hysteresis I(V) loops of a SiGe–TiN NEM relay measured...
Figure 18: Electrical burn-out induced failure of the NEM switching element. a) Ball formation at the end of a...
Figure 19: a) Breakdown I(V) characteristics of two individual Bi2Se3 nanobelts. 1-2-3 – The step-like breakdo...
Beilstein J. Nanotechnol. 2016, 7, 278–283, doi:10.3762/bjnano.7.25
Figure 1: In situ resonance excitation of Sb2S3 NW. SEM images of NW with dimensions: length L = 10 μm and ra...
Figure 2: SEM images of resonantly excited Sb2S3 NW with rectangular cross-section, showing two mutually orth...
Figure 3: Young’s modulus of Sb2S3 NWs as a function of their size. Data points represent the measured Young’...
Figure 4: a) Schematic of the static bending of a single Sb2S3 NW. SEM images of the NW b) in a relaxed state...