Organic semiconductors are usually not thought to show outstanding performance in highlyintegrated, sub 100 nm transistors. Consequently, single-crystalline materials such as SWCNTs, MoS2 or inorganic semiconductors are the material of choice at these nanoscopic dimensions. Here, we show that using a novel vertical field-effect transistor design with a channel length of only 40 nm and a footprint of 2 x 80 x 80 nm², high electrical performance with organic polymers can be realized when using electrolyte gating. Our organic transistors combine high on-state current densities of above 3 MA/cm², on/off current modulation ratios of up to 10 8 and large transconductances of up to 5000 S/m. Given the high on-state currents at yet large on/off ratios, our novel structures also show promise for use in artificial neural networks, where they could operate as memristive devices with sub 100 fJ energy usage.
Optothermal control of fluid motion has been suggested as a powerful way of controlling nanomaterials in micro- or nanofluidic samples. Methods based on merely thermal convection, however, often rely on high temperature for achieving fluid velocities suitable for most practical uses. Here, we demonstrate an optofluidic approach based on Marangoni or thermocapillary convection to steer and manipulate nano-objects with high accuracy at an air/liquid interface. By experiments and numerical simulations, we show that the fluid velocities achieved by this approach are more than three orders of magnitude stronger compared to natural convection and that it is possible to control the transport and position of single plasmonic nanoparticles over micrometer distances with high accuracy.
The crystal structure of solid-state matter greatly affects its electronic properties. For example in multilayer graphene, precise knowledge of the lateral layer arrangement is crucial, since the most stable configurations, Bernal and rhombohedral stacking, exhibit very different electronic properties.Nevertheless, both stacking orders can coexist within one flake, separated by a strain soliton that can host topologically protected states. Clearly, accessing the transport properties of the two stackings and the soliton is of high interest. However, the stacking orders can transform into one another and therefore, the seemingly trivial question how reliable electrical contact can be made to either stacking order can a priori not be answered easily. Here, we show that manufacturing metal contacts to multilayer graphene can move solitons by several µm, unidirectionally enlarging Bernal domains due to arising mechanical strain. Furthermore, we also find that during dry transfer of multilayer graphene onto hexagonal Boron Nitride, such a transformation can happen. Using density functional theory modeling, we corroborate that anisotropic deformations of the multilayer graphene lattice decrease the rhombohedral stacking stability. Finally, we have devised systematics to avoid soliton movement, and how to reliably realize contacts to both stacking configurations.
Miniaturization
of electronic circuits increases their overall
performance. So far, electronics based on organic semiconductors has
not played an important role in the miniaturization race. Here, we
show the fabrication of liquid electrolyte gated vertical organic
field effect transistors with channel lengths down to 2.4 nm. These
ultrashort channel lengths are enabled by using insulating hexagonal
boron nitride with atomically precise thickness and flatness as a
spacer separating the vertically aligned source and drain electrodes.
The transistors reveal promising electrical characteristics with output
current densities of up to 2.95 MA cm–2 at −0.4
V bias, on–off ratios of up to 106, a steep subthreshold
swing of down to 65 mV dec–1 and a transconductance
of up to 714 S m–1. Realizing channel lengths in
the sub-5 nm regime and operation voltages down to 100 μV proves
the potential of organic semiconductors for future highly integrated
or low power electronics.
Optomechanical manipulation of plasmonic nanoparticles is an area of current interest, both fundamental and applied. However, no experimental method is available to determine the forward-directed scattering force that dominates for incident light of a wavelength close to the plasmon resonance. Here, we demonstrate how the scattering force acting on a single gold nanoparticle in solution can be measured. An optically trapped 80 nm particle was repetitively pushed from the side with laser light resonant to the particle plasmon frequency. A lock-in analysis of the particle movement provides a measured value for the scattering force. We obtain a resolution of less than 3 femtonewtons which is an order of magnitude smaller than any measurement of switchable forces performed on nanoparticles in solution with single beam optical tweezers to date. We compared the results of the force measurement with Mie simulations of the optical scattering force on a gold nanoparticle and found good agreement between experiment and theory within a few fN.
Bernal-stacked multilayer graphene
is a versatile platform to explore
quantum transport phenomena and interaction physics due to its exceptional
tunability via electrostatic gating. For instance, upon applying a
perpendicular electric field, its band structure exhibits several
off-center Dirac points (so-called Dirac gullies) in each valley.
Here, the formation of Dirac gullies and the interaction-induced breakdown
of gully coherence is explored via magnetotransport measurements in
high-quality Bernal-stacked (ABA) trilayer graphene. At zero magnetic
field, multiple Lifshitz transitions indicating the formation of Dirac
gullies are identified. In the quantum Hall regime, the emergence
of Dirac gullies is evident as an increase in Landau level degeneracy.
When tuning both electric and magnetic fields, electron–electron
interactions can be controllably enhanced until, beyond critical electric
and magnetic fields, the gully degeneracy is eventually lifted. The
arising correlated ground state is consistent with a previously predicted
nematic phase that spontaneously breaks the rotational gully symmetry.
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