Colloidal Lithography

Yu, Yi; Zhang, Gang

doi:10.5772/56576

Cited by 12 publications

(14 citation statements)

References 94 publications

(119 reference statements)

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“…For a particle-laden liquid, a supplementary length − the particle diameter d − is introduced and different rheology (Guazzelli & Pouliquen 2018) and surface conditions (Kralchevsky & Nagayama 1994) are expected. Motivated by film deposition and selfassembly of colloids for surface patterning, lithography or optical applications (Yu & Zhang 2013) much attention has been devoted to colloidal particles suspended in a volatile liquid, for which evaporation is often a dominant factor (Dimitrov & Nagayama 1996;Ghosh et al 2007;Buchanan et al 2007;Le Berre et al 2009;Faustini et al 2010;Jing et al 2010;Brewer et al 2011;Berteloot et al 2013;Jung & Ahn 2013). However, much fewer studies have considered suspensions of larger particles (∼ 100 µm) or low volatility liquids (Kao & Hosoi 2012;Colosqui et al 2013;Gans et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Dip-coating with a particulate suspension

Palma

Lhuissier

2019

J. Fluid Mech.

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The coating of a plate withdrawn from a bath of a suspension of non-Brownian, monodisperse and neutrally buoyant spherical particles suspended in a Newtonian liquid has been studied. Using laser profilometry, particle tracking and local sample weighing we have quantified the thickness $h$ and the particle content of the film for various particle diameters $d$ and volume fractions ($0.10\leqslant \unicode[STIX]{x1D719}\leqslant 0.50$). Three coating regimes have been observed as the withdrawal velocity is increased: (i) no particle entrainment ($h\lesssim d$), (ii) a monolayer of particles ($h\sim d$), and (iii) a thick film ($h\gtrsim d$), where the suspension behaves as an effective viscous fluid following the Landau–Levich–Derjaguin law. We discuss the boundaries between these regimes, as well as the evolution of the liquid and solid content of the coating over the whole range of withdrawal capillary number and volume fractions.

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Section: Introductionmentioning

confidence: 99%

Dip-coating with a particulate suspension

Palma

Lhuissier

2019

J. Fluid Mech.

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“…In these unorthodox cases, process steps as spin-coating of spheres on nanocrystalline diamond films, modification in linear antenna plasma (combined RF and microwave (MW) plasma) system of the PS mono-and double layers (with hcp or square arrangement), and Au evaporation were employed [25]. For multilayers (3D colloidal crystals), the upper layers act as a shadow mask for the etching of the lower layer [20,36]. In our case, a gold layer was deposited over the non-close-packed monolayers ( Figure 5, PS_1.5 μm after 2 min etching) at a normal angle (in order to achieve round holes after the lift-off process).…”

Section: Periodic Holesmentioning

confidence: 99%

“…After the CVD diamond growth, PS spheres (with a With angle-resolved evaporation, it is possible to achieve even more complex nanostructures (rings, crescents, split-rings, asymmetric double split-rings, dimers, etc. ), which have a great potential for numerous applications (e.g., metamaterials, plasmonics, photonics, bioscience) [18,20,26,37,38].…”

Section: Periodic Holesmentioning

confidence: 99%

“…Ordered monolayers or multilayers of submicron-sized spheres (e.g., polystyrene-PS, silicon dioxide-SiO 2 , and polymethyl methacrylate-PMMA spheres with a diameter of 200 nm to 2 µm) are the most commonly utilized particles because of their easy synthesis and processing (commercial availability, controlled reduction of diameter by plasma etching, simple lift-off) [18,19]. In the past three decades, various methods have been developed to deposit them onto the desired substrate (e.g., spin-coating, dip-coating, drag-coating, convective-coating, Langmuir-Blodgett method, template-directed assembly), all aimed at attaining high uniformity and low defect density over a large area [13,[20][21][22]. The nanosphere assembly is followed by various post-processing steps, which can be modified on demand [23].…”

Section: Introductionmentioning

confidence: 99%

“…The nanosphere assembly is followed by various post-processing steps, which can be modified on demand [23]. The most common step is plasma etching, which is used to alter the size and geometry of the spheres in the close-packed array without changing their relative placement [20,24,25]. Furthermore, deposition (e.g., metal evaporation, sputtering, pulsed laser deposition, electrochemical deposition), thermal annealing, lift-off techniques, and 3D printing are used to obtain the most common features, such as triangular, honeycomb, pyramid structures, holes, pillars, rods, rings, and cones [11,14,18,21,22,26].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Nanosphere Lithography for Structuring Polycrystalline Diamond Films

2020

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This paper deals with the structuring of polycrystalline diamond thin films using the technique of nanosphere lithography. The presented multistep approaches relied on a spin-coated self-assembled monolayer of polystyrene spheres, which served as a lithographic mask for the further custom nanofabrication steps. Various arrays of diamond nanostructures-close-packed and non-close-packed monolayers over substrates with various levels of surface roughness, noble metal films over nanosphere arrays, ordered arrays of holes, and unordered pores-were created using reactive ion etching, chemical vapour deposition, metallization, and/or lift-off processes. The size and shape of the lithographic mask was altered using oxygen plasma etching. The periodicity of the final structure was defined by the initial diameter of the spheres. The surface morphology of the samples was characterized using scanning electron microscopy. The advantages and limitations of the fabrication technique are discussed. Finally, the potential applications (e.g., photonics, plasmonics) of the obtained nanostructures are reviewed.

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Plasmonic Nanostructure Engineering with Shadow Growth

Han

Kim

et al. 2022

Advanced Materials

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Physical shadow growth is a vacuum deposition technique that permits a wide variety of 3D‐shaped nanoparticles and structures to be fabricated from a large library of materials. Recent advances in the control of the shadow effect at the nanoscale expand the scope of nanomaterials from spherical nanoparticles to complex 3D shaped hybrid nanoparticles and structures. In particular, plasmonically active nanomaterials can be engineered in their shape and material composition so that they exhibit unique physical and chemical properties. Here, the recent progress in the development of shadow growth techniques to realize hybrid plasmonic nanomaterials is discussed. The review describes how fabrication permits the material response to be engineered and highlights novel functions. Potential fields of application with a focus on photonic devices, biomedical, and chiral spectroscopic applications are discussed.

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Colloidal Lithography

Cited by 12 publications

References 94 publications

Dip-coating with a particulate suspension

Dip-coating with a particulate suspension

Nanosphere Lithography for Structuring Polycrystalline Diamond Films

Plasmonic Nanostructure Engineering with Shadow Growth

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