Nano-bioelectronics via dip-pen nanolithography

O’Connell, Cathal; Higgins, Michael J.; Moulton, Simon E.; Wallace, Gordon G.

doi:10.1039/c5tc00186b

Cited by 27 publications

(21 citation statements)

References 152 publications

(198 reference statements)

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“…Protein chips haves also attracted interest in diagnostics, biosensor applications and library screening [157,158]. Recently, the two branches of patterning merged with the invention of massively parallel DPN and polymer-pen lithography [155,159]. In the field of nanotechnology, biocompatibility and low environmental impact of the byproducts are desired because of the increasing awareness of global environmental issues.…”

Section: Resultsmentioning

confidence: 99%

Biodegradable Polymers: Recent Developments and New Perspectives

Carrasco¹,

Pérez²,

Cailloux³

et al. 2017

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Section: Resultsmentioning

confidence: 99%

Biodegradable Polymers: Recent Developments and New Perspectives

Carrasco¹,

Pérez²,

Cailloux³

et al. 2017

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“…Since the first scanning probe microscope (SPM) [1,2] was introduced in the 1980s, it became clear a great potential of SPM for the direct surface modification [3][4][5] apart of versatile diagnostics of surface physical properties. Application of SPM for nano-lithography, nano-manipulations [6,7] and nano-preparations [8] is not limited by the type of material (mineral, organic, biological) or environment (ambient, vacuum, liquid) or type of physical interactions (mechanical, electrical, magnetic, thermal, chemical) [9][10][11][12][13]. Depending on the hardware implementation, SPM could be effective starting from the atomic level surface modification up to the surface patterning over hundred microns areas.…”

Section: Introductionmentioning

confidence: 99%

Features of mechanical scanning probe lithography on graphene oxide and As(Ge)Se chalcogenide resist

Lytvyn¹

2018

Semicond. Phys. Quantum Electron. Optoelectron.

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Combined mechanical scanning probe lithography (SPL) approach applied for the direct mask-less modification of graphene oxide (GO) flakes and the mask patterns engraving in layers of chalcogenide resist with a nanometer scale resolution have been implemented in this work. It was compared the dynamics of mechanical modification of chalcogenide films and multilayer GO flakes deposited from an aqueous suspension. The double-layer As 40 Se 60 /As 4 Ge 30 S 66 chalcogenide resist developed for mechanical SPL and pattern formation processes have optimized. The resist with the thickness close to 100 nm provides formation of minimal pattern elements with the size of several tens nanometers. The SPL approach was realized on the basis of serial NanoScope IIIa Dimension 3000 TM scanning probe microscope, and original software utilities were developed. These mechanical SPL could be intended for the verification of innovative ideas in academic researches, the laboratory-level device prototyping, developing the functional prototypes of new devices in bio/nanosensorics, plasmonics, 2D electronics and other modern technology branches.

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“…The common examples are the capabilities of the semiconductor industry to produce large arrays of patterns with nanometric resolution in parallel. These advances were all based on the top down photolithography approach, which has the advantage of parallelism but suffers from the lack of simplicity, placement flexibility for additive corrections to already written arrays of nanometric patterns, and very high cost of prototype development . Soft lithography methods, which are low‐price top‐down or bottom‐up approaches, also lack flexible printing .…”

Section: Introductionmentioning

confidence: 99%

“…These advances were all based on the top down photolithography approach, [16] which has the advantage of parallelism but suffers from the lack of simplicity, placement flexibility for additive corrections to already written arrays of nanometric patterns, and very high cost of prototype development. [17] Soft lithography methods, which are low-price top-down or bottomup approaches, also lack flexible printing. [18] A bottom up technique of considerable significance that includes placement flexibility is ion beam [19] or electron beam [20] induced deposition lithography.…”

Section: Introductionmentioning

confidence: 99%

Micrometer to 15 nm Printing of Metallic Inks with Fountain Pen Nanolithography

Yeshua

Layani

Dekhter

et al. 2017

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The field of printed electronics is continually trying to reduce the dimensions of the electrical components. Here, a method of printing metallic lines with widths as small as 15 nm and up to a few micrometers using fountain pen nanolithography (FPN) is shown. The FPN technique is based on a bent nanopipette with atomic force feedback that acts similar to a nanopen. The geometry of the nanopen allows for rapid placement accuracy of the printing tip, on any desired location, with the highest of optical sub‐micrometer resolution. Using this nanopen, investigations of various inks are undertaken together with instrumental and script‐tool development that allows accurate printing of multiple layers. This has led to the printing of conductive lines using inks composed of silver nanoparticles and salt solutions of silver and copper. In addition, it is shown that the method can be applied to substrates of various materials with minimal effect on the dimension of the line. The line widths are varied by using nanopens with different orifices or by tailoring the wetting properties of the ink on the substrate. Metallic interconnections of conducting lines are reported.

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Nano-bioelectronics via dip-pen nanolithography

Cited by 27 publications

References 152 publications

Biodegradable Polymers: Recent Developments and New Perspectives

Biodegradable Polymers: Recent Developments and New Perspectives

Features of mechanical scanning probe lithography on graphene oxide and As(Ge)Se chalcogenide resist

Micrometer to 15 nm Printing of Metallic Inks with Fountain Pen Nanolithography

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