Patterning Gradient Properties from Sub-Micrometers to Millimeters by Magnetolithography

Kumar, Tatikonda Anand; Bardea, Amos; Shai, Yechiel; Yoffe, Alexander; Naaman, Ron

doi:10.1021/nl1013635

Cited by 22 publications

(14 citation statements)

References 33 publications

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“…However, this also carries a severe difficulty in how to combine different items together in a pre-determined manner. 291 Attempts in this direction mostly employ scanning tips, using dip pen lithography 292 or tip-induced oxidation. 226 Examples of overcoming the next challenge of integrating a few molecular junctions into operational electronics are extremely scarce.…”

Section: Gating and External Stimulimentioning

confidence: 99%

Large-Area, Ensemble Molecular Electronics: Motivation and Challenges

2017

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We review charge transport across molecular monolayers, which is central to molecular electronics (MolEl), using large-area junctions (NmJ). We strive to provide a wide conceptual overview of three main subtopics. First, a broad introduction places NmJ in perspective to related fields of research and to single-molecule junctions (1mJ) in addition to a brief historical account. As charge transport presents an ultrasensitive probe for the electronic perfection of interfaces, in the second part ways to form both the monolayer and the contacts are described to construct reliable, defect-free interfaces. The last part is dedicated to understanding and analyses of current-voltage (I-V) traces across molecular junctions. Notwithstanding the original motivation of MolEl, I-V traces are often not very sensitive to molecular details and then provide a poor probe for chemical information. Instead, we focus on how to analyze the net electrical performance of molecular junctions, from a functional device perspective. Finally, we point to creation of a built-in electric field as a key to achieve functionality, including nonlinear current-voltage characteristics that originate in the molecules or their contacts to the electrodes. This review is complemented by a another review that covers metal-molecule-semiconductor junctions and their unique hybrid effects.

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Section: Gating and External Stimulimentioning

confidence: 99%

Large-Area, Ensemble Molecular Electronics: Motivation and Challenges

2017

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“…In addition, electrochemistry has also been applied to fabricate morphology gradients, where in-plane potential gradients are utilized to generate progressively varied nanopores 26 . Many other approaches based on magnetic 27 , thermal [28][29][30] , and humidity 31 gradients have also been used to fabricate gradient topography surfaces.…”

Section: Introductionmentioning

confidence: 99%

Gradient wettability induced by deterministically patterned nanostructures

Min

Zhu

et al. 2020

Microsyst Nanoeng

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We report a large-scale surface with continuously varying wettability induced by ordered gradient nanostructures. The gradient pattern is generated from nonuniform interference lithography by utilizing the Gaussian-shaped intensity distribution of two coherent laser beams. We also develop a facile fabrication method to directly transfer a photoresist pattern into an ultraviolet (UV)-cured high-strength replication molding material, which eliminates the need for high-cost reactive ion etching and e-beam evaporation during the mold fabrication process. This facile mold is then used for the reproducible production of surfaces with gradient wettability using thermal-nanoimprint lithography (NIL). In addition, the wetting behavior of water droplets on the surface with the gradient nanostructures and therefore gradient wettability is investigated. A hybrid wetting model is proposed and theoretically captures the contact angle measurement results, shedding light on the wetting behavior of a liquid on structures patterned at the nanoscale.

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“…Possessing inherently favorable superparamagnetic properties, magnetite nanoparticles (MNPs, <20 nm) have attracted much research interest over recent years for extensive applications, e.g., magnetic resonance imaging, drug delivery, tumor treatment, catalysis, magnetolithography, and water purification . In biological systems, dispersibility, the arrangement, and the interaction between MNPs play an essential role for general performances .…”

Section: Introductionmentioning

confidence: 99%

Silica‐Coated Magnetite Nanoparticles Carrying a High‐Density Polymer Brush Shell of Hydrophilic Polymer

Cai

Peng

Demeshko

et al. 2018

Macromol. Rapid Commun.

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Integrating the properties of magnetite nanoparticles (MNPs) and high-density polymer brushes in one structure requires sophisticated synthetic designs and effective chemical approaches. A simple and versatile strategy for the fabrication of hydrophilic-polymer-capped magnetite-core-silica-shell nanohybrids with well-defined structure employing reverse microemulsion technique and reversible addition-fragmentation chain transfer (RAFT) polymerization is presented. The high-density polymer brush allows precise patterning of the magnetic nanohybrids with a tunable interparticle distance ranging from 20 nm to 80 nm by controlling the polymer size. The high structural precision provides a near stand-alone state of the MNPs in the nanohybrids with effectively inhibited magnetic interaction, as shown by superconducting quantum interference device (SQUID) measurements.

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Patterning Gradient Properties from Sub-Micrometers to Millimeters by Magnetolithography

Cited by 22 publications

References 33 publications

Large-Area, Ensemble Molecular Electronics: Motivation and Challenges

Large-Area, Ensemble Molecular Electronics: Motivation and Challenges

Gradient wettability induced by deterministically patterned nanostructures

Silica‐Coated Magnetite Nanoparticles Carrying a High‐Density Polymer Brush Shell of Hydrophilic Polymer

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