Ultrasmooth and Photoresist‐Free Micropore‐Based EGaIn Molecular Junctions: Fabrication and How Roughness Determines Voltage Response

Karuppannan, Senthil Kumar; Hu, Hongting; Troadec, Cedric; Vilan, Ayelet; Nijhuis, Christian A.

doi:10.1002/adfm.201904452

Cited by 36 publications

(56 citation statements)

References 84 publications

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“…69 In this framework, the distance dependence of the conductance is related to a thickness-dependent barrier akin to the one inherent to the Simmons model. 68,70 In their model, however, the barrier arises from the presence of localized charge traps along the path of charge migration leading to a non-linear potential drop between the macroscopic leads. Figure 6f shows the linear relation of the double-log plot of β vs. ' with a slope of -0.82 which is lower than the expected -0.5 from the model by Berlin et al 69 , but note that a change in the contact resistance or further changes in the barrier shape are not taken into consideration in this model.…”

Section: Resultsmentioning

confidence: 99%

A Single Atom Change Turns Insulating Saturated Wires into Molecular Conductors

Chen

Kretz

Adoah

et al. 2020

Preprint

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We present an efficient strategy to modulate tunnelling in molecular junctions by changing the tunnelling decay coefficient, β, by terminal-atom substitution which avoids altering the molecular backbone. By varying X = H, F, Cl, Br, I in junctions with S(CH2)(10−18)X, current densities (J) increases > 4 orders of magnitude, creating molecular conductors via reduction of β from 0.75 to 0.25 Å−1. Impedance measurements shows tripled dielectric constants (εr) with X = I, reduced HOMO-LUMO gaps and tunnelling-barrier heights, and 5-times reduced contact resistance. These effects alone cannot explain the large change in β. Density-functional theory shows highly localized, X-dependent potential drop at the S(CH2)nX//electrode interface that modifies the tunnelling barrier shape. Commonly-used tunnelling models neglect localized potential drops and changes in εr. We demonstrate experimentally that β ∝1/√εr, suggesting highly-polarizable terminal-atom sites act as charge traps as proposed by Berlin and Ratner. Our work shows the need for new charge transport models that account for dielectric effects in molecular tunnelling junctions.

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Section: Resultsmentioning

confidence: 99%

A Single Atom Change Turns Insulating Saturated Wires into Molecular Conductors

Chen

Kretz

Adoah

et al. 2020

Preprint

Self Cite

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“…Finally, the sample is placed in a vacuum chamber to thermally deposit the bottom metal (Au) electrode. Recently, large-area junctions based on SAMs deposited in AlO x micropores fabricated on ultraflat template stripped bottom electrodes of gold (Au TS ) have been fabricated with high mechanical stability [378]. The construction of a nanowell is more simplified, and occurs in a planar device in contrast with the nanopore.…”

Section: Fabrication Of the Top Contact Electrodementioning

confidence: 99%

Nanofabrication Techniques in Large-Area Molecular Electronic Devices

2020

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The societal impact of the electronics industry is enormous—not to mention how this industry impinges on the global economy. The foreseen limits of the current technology—technical, economic, and sustainability issues—open the door to the search for successor technologies. In this context, molecular electronics has emerged as a promising candidate that, at least in the short-term, will not likely replace our silicon-based electronics, but improve its performance through a nascent hybrid technology. Such technology will take advantage of both the small dimensions of the molecules and new functionalities resulting from the quantum effects that govern the properties at the molecular scale. An optimization of interface engineering and integration of molecules to form densely integrated individually addressable arrays of molecules are two crucial aspects in the molecular electronics field. These challenges should be met to establish the bridge between organic functional materials and hard electronics required for the incorporation of such hybrid technology in the market. In this review, the most advanced methods for fabricating large-area molecular electronic devices are presented, highlighting their advantages and limitations. Special emphasis is focused on bottom-up methodologies for the fabrication of well-ordered and tightly-packed monolayers onto the bottom electrode, followed by a description of the top-contact deposition methods so far used.

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“…The construction of ensemble molecular junctions is more robust for ensuring well‐defined electrical conductance because of the nature of ensembled molecules; furthermore, it is more practical in terms of reproducibility, yield, and mass production because of the large‐scale bottom and top configuration. To construct ensemble molecular junctions, large‐area junctions, [48–51] conductive atomic force microscopy (C‐AFM) junctions, [52–54] liquid metal junctions, [46,72–74] crosswire junctions, [75,76] and nanoparticle network junctions [34,55] have been proposed. In contrast to the single molecule junctions, ensemble molecule junctions with well‐ordered self‐assembled monolayers (SAMs) offer a more robust electrical conductance and a more straightforward junction fabrication process.…”

Section: Platforms Of Molecular Junctionsmentioning

confidence: 99%

“…However, it is challenging to control the number of molecules at the contact because of the curvature of the wires. Liquid metal junctions have been exploited extensively in the area of molecular electronics because of their high device yield and easy settlement of junctions [46,72–74] . In addition, the liquid metal technique is unlikely to create defects in the SAMs.…”

Section: Platforms Of Molecular Junctionsmentioning

confidence: 99%

Photoswitching Molecular Junctions: Platforms and Electrical Properties

Kim

2020

ChemPhysChem

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Remarkable advances in technology have enabled the manipulation of individual molecules and the creation of molecular electronic devices utilizing single and ensemble molecules. Maturing the field of molecular electronics has led to the development of functional molecular devices, especially photoswitching or photochromic molecular junctions, which switch electronic properties under external light irradiation. This review introduces and summarizes the platforms for investigating the charge transport in single and ensemble photoswitching molecular junctions as well as the electronic properties of diverse photoswitching molecules such as diarylethene, azobenzene, dihydropyrene, and spiropyran. Furthermore, the article discusses the remaining challenges and the direction for moving forward in this area for future photoswitching molecular devices.

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Ultrasmooth and Photoresist‐Free Micropore‐Based EGaIn Molecular Junctions: Fabrication and How Roughness Determines Voltage Response

Cited by 36 publications

References 84 publications

A Single Atom Change Turns Insulating Saturated Wires into Molecular Conductors

A Single Atom Change Turns Insulating Saturated Wires into Molecular Conductors

Nanofabrication Techniques in Large-Area Molecular Electronic Devices

Photoswitching Molecular Junctions: Platforms and Electrical Properties

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