Assessment of a nanoparticle bridge platform for molecular electronics measurements

• A combination of electron beam lithography, photolithography and focused ion beam milling was used to create a nanogap platform, which was bridged by gold nanoparticles in order to make electrical measurements and assess the platform under ambient conditions. Non-functionalized electrodes were tested to determine the intrinsic response of the platform and it was found that creating devices in ambient conditions requires careful cleaning and awareness of the contributions contaminants may make to measurements. The platform was then used to make measurements on octanethiol (OT) and biphenyldithiol (BPDT) molecules by functionalizing the nanoelectrodes with the molecules prior to bridging the nanogap with nanoparticles. Measurements on OT show that it is possible to make measurements on relatively small numbers of molecules, but that a large variation in response can be expected when one of the metal-molecule junctions is physisorbed, which was partially explained by attachment of OT molecules to different sites on the surface of the Au electrode using a density functional theory calculation. On the other hand, when dealing with BPDT, high yields for device creation are very difficult to achieve under ambient conditions. Significant hysteresis in the I-V curves of BPDT was also observed, which was attributed primarily to voltage induced changes at the interface between the molecule and the metal.

Nyckelord

A-density

Ambient conditions

Au electrodes

Electrical measurement

Focused ion beam milling

Functionalized electrodes

Gold Nanoparticles

High yield

I - V curve

Intrinsic response

Nano-electrodes

Nano-gap

Nanoparticle bridges

Octanethiol

Physisorbed

Cable stayed bridges

Density functional theory

Electron beams

Molecular electronics

Nanoparticles

Photolithography

TECHNOLOGY

TEKNIKVETENSKAP

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