Massively parallel fabrication of crack-defined gold break junctions featuring sub-3 nm gaps for molecular devices

Dubois, Valentin; Raja, Shyamprasad N.; Gehring, Pascal; Caneva, Sabina; Zant, Herre S. J. van der; Niklaus, Frank; Stemme, Göran

doi:10.1038/s41467-018-05785-2

Cited by 59 publications

(71 citation statements)

References 41 publications

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“…In addition, as shown in Table , only a few methods can be used to fabricate multiple nanogap devices in a parallel manner. However, the production yields of nanogaps with the desired width are still very low, although the fabrication densities of nanogaps have reached a high level. In the application aspect, the nanogaps fabricated by physical methods can be used in various regimes ranging from molecular electronics to sensing and optical devices, whereas the sub‐5 nm nanogaps formed by nanoparticles are mostly limited to the regime of sensing and biomedicine devices based on the SERS technique.…”

Section: Discussionmentioning

confidence: 99%

Section: Fabrication Methods For Sub‐5 Nm Nanogapsmentioning

confidence: 99%

“…However, TiN is brittle, and its conductivity is much lower than that of metal, limiting its application in electronic devices. Recently, their group introduced a true parallel fabrication method for gold break junctions with sub‐3 nm gaps on the wafer scale by relying on a self‐breaking mechanism based on controlled crack formation in notched bridge structures . The fabrication densities were reported to be as high as 7 million junctions cm −2 , with fabrication yields for sub‐3 nm junctions of ≈7%.…”

Section: Fabrication Methods For Sub‐5 Nm Nanogapsmentioning

confidence: 99%

“…Furthermore, in recent years, insertion of an ultrathin layer has proven to be a promising technical strategy for creating sub‐5 nm nanogaps with wafer‐scale throughput via atomic layer deposition (ALD) or 2D materials with a precise control of the gap width . Another noteworthy fabrication method for sub‐5 nm nanogaps produces the so‐called breaking‐/cracking‐defined nanogaps, formed by imposing external stimuli, such as an electric current, a mechanical force, or a strain, has been widely employed in single‐molecule devices …”

Section: Introductionmentioning

confidence: 99%

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Sub‐5 nm Metal Nanogaps: Physical Properties, Fabrication Methods, and Device Applications

Yang

2018

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Sub‐5 nm metal nanogaps have attracted widespread attention in physics, chemistry, material sciences, and biology due to their physical properties, including great plasmon‐enhanced effects in light–matter interactions and charge tunneling, Coulomb blockade, and the Kondo effect under an electrical stimulus. These properties especially meet the needs of many cutting‐edge devices, such as sensing, optical, molecular, and electronic devices. However, fabricating sub‐5 nm nanogaps is still challenging at the present, and scaled and reliable fabrication, improved addressability, and multifunction integration are desired for further applications in commercial devices. The aim of this work is to provide a comprehensive overview of sub‐5 nm nanogaps and to present recent advancements in metal nanogaps, including their physical properties, fabrication methods, and device applications, with the ultimate aim to further inspire scientists and engineers in their research.

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Section: Discussionmentioning

confidence: 99%

Section: Fabrication Methods For Sub‐5 Nm Nanogapsmentioning

confidence: 99%

Section: Fabrication Methods For Sub‐5 Nm Nanogapsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Sub‐5 nm Metal Nanogaps: Physical Properties, Fabrication Methods, and Device Applications

Yang

2018

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“…There have been several experimental reports about R tunnel . R tunnel was reported to be about 10 5 Ω when the gap distance was about 3 nm39 and no tunneling took place when the gap distance was larger than 5 nm 40. The small gap distance (≈5 nm) can be reached even at a small applied strain in this study (ε < 0.002), which is a negligible strain in the sensor.…”

Section: Resultsmentioning

confidence: 99%

2D Percolation Design with Conductive Microparticles for Low‐Strain Detection in a Stretchable Sensor

Hwang

Kim

Park

et al. 2020

Adv Funct Materials

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Although a variety of stretchable strain sensors based on electrical percolation have been reported, stretchable sensors detecting low strains have been rarely demonstrated. This is because large stretchability of a strain sensor conflicts with high strain resolution at low strains. Here, the electrical percolation into 2D is confined and a strain sensor that is highly sensitive at low strains and simultaneously highly stretchable is presented. The 2D confinement of the electrical percolation is accomplished by a close‐packed monolayer assembly of conductive microparticles (MPs) on an elastomer substrate. The current profiles of the MP monolayer at low strains are in situ visualized using conductive atomic force microscopy. When the lattice of the MP monolayer is aligned vertically to the strain direction, the resistance is highly sensitive to low‐strain deformations (ε = 0 – 0.05), but the sensor has reasonable stretchability (ε = 0.3). The simultaneous achievement of the high sensitivity at low strains and the reasonable stretchability is explained by the relationship between the strain‐dependent current profile and the relative position changes of the MPs. A high‐precision pulse sensor clearly showing the representative peaks is demonstrated.

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Molecular/Nanostructured Functional Metal Oxide Stacks for Nanoscale Nanosecond Information Storage

Balliou

Skarlatos

Papadimitropoulos

et al. 2019

Adv Funct Materials

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The metal oxide heterostructures market is exponentially growing, adhering to the trend of achieving fabrication versatility on a vast range of nonconventional electromagnetic and optical properties. A high degree of substrate tolerance and solution‐phase growth potential promise low‐cost flexible electronics and silicon‐based process compatibility. A molecule‐based complex oxide nanostructured stack integrated in an electro‐optically operable nonvolatile two‐terminal capacitive memory element is proposed. The cell demonstrates a remarkably high > 7 V memory window and write–read times down to 10 ns, promising for reliable high‐speed storage. Molecular orbital occupancy through broadband optical stimulus enables simultaneous phononic addressing and boosts the written information amount by up to 37%, achieving 10+ years storage duration. The resulting nonvolatile memories are the first‐documented complementary metal oxide semiconductor (CMOS)‐compatible long‐term‐retention molecular capacitive cell of its kind, implementing inherent structure‐emerging heat management. Great potential emerges for numerous energy‐inspired innovations, enabling functional oxide–molecular hybrids exploitation as high‐end nonvolatile memory products.

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Massively parallel fabrication of crack-defined gold break junctions featuring sub-3 nm gaps for molecular devices

Cited by 59 publications

References 41 publications

Sub‐5 nm Metal Nanogaps: Physical Properties, Fabrication Methods, and Device Applications

Sub‐5 nm Metal Nanogaps: Physical Properties, Fabrication Methods, and Device Applications

2D Percolation Design with Conductive Microparticles for Low‐Strain Detection in a Stretchable Sensor

Molecular/Nanostructured Functional Metal Oxide Stacks for Nanoscale Nanosecond Information Storage

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