Assembled Monolayers of Hydrophilic Particles on Water Surfaces

Moon, Geon Dae; Lee, Tae Il; Kim, Bongsoo; Chae, Gee Sung; Kim, Jinook; Kim, Sunghee; Myoung, Jae Min; Jeong, Unyong

doi:10.1021/nn202733f

Cited by 171 publications

(187 citation statements)

References 54 publications

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“…Graphene fl akes would collide and bind with each other via π-π interactions as ethanol evaporated. [36][37][38] Then, the "fi sh scale" like assembled graphene fl akes were pushed forward quickly to the bare surface of DI water with the increasing loading of the graphene dispersion. Finally, the assembled graphene fi lms were self-compressed and packed tightly, forming large area UGF on the surface of DI water.…”

Section: Self-assembly Processes Of Ultrathin Graphene Filmsmentioning

confidence: 99%

Large‐Area Ultrathin Graphene Films by Single‐Step Marangoni Self‐Assembly for Highly Sensitive Strain Sensing Application

Yang

et al. 2016

Adv Funct Materials

350

259

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1322 wileyonlinelibrary.com applications in fi elds of healthcare monitoring, human-computer interaction, and electronic skin. [ 12 ] The relative resistance Δ R normalized by the initial resistance R 0 depends on Poisson's ratio ( ν ) and resistivity variation (Δ ρ ) normalized by its initial resistivity ρ 0 through the expression ΔR / R 0 = (1 + 2ν) ε + Δ ρ / ρ 0.[ 13 ] The sensitivity revealed by gauge factor (GF, defi ned as ( ΔR / R 0 )/ ε ) depends on both intrinsic property and structural feature. According to this formula, graphene-based strain sensors have shown low sensitivities due to the rigid and stable structure of intrinsic graphene. [ 14 ] With hardly opened band gap, the GF of a suspended graphene is only about 1.9 under moderate uniaxial strains. [ 15 ] Therefore, structural engineering of graphene is needed to boost the sensitivity of graphene-based strain sensors.Adjustment of the connection channels in graphene is an effective way to alter its resistivity for improved sensitivity in strain sensors. Two common methods for the structural construction of graphene include high temperature processing based chemical vapor deposition (CVD) and solution processing based sheets/fl akes assembly. As for CVD, the resistivity of graphene would be affected by its grain boundary, grain size, and the defect density. [16][17][18] Continuous graphene fi lms grown by CVD could sustain 1% strain with a GF of only 6.1, [ 19 ] and the GF increases to 151 for a 5% strain due to the morphological Large-Area Ultrathin Graphene Films by Single-Step Marangoni Self-Assembly for Highly Sensitive Strain Sensing ApplicationXinming Li , Tingting Yang , Yao Yang , Jia Zhu , Li Li , Fakhr E. Alam , Xiao Li , Kunlin Wang , Huanyu Cheng , Cheng-Te Lin , * Ying Fang , * and Hongwei Zhu * Promoted by the demand for wearable devices, graphene has been proved to be a promising material for potential applications in fl exible and highly sensitive strain sensors. However, low sensitivity and complex processing of graphene retard the development toward the practical applications. Here, an environment-friendly and cost-effective method to fabricate large-area ultrathin graphene fi lms is proposed for highly sensitive fl exible strain sensor. The assembled graphene fi lms are derived rapidly at the liquid/air interface by Marangoni effect and the area can be scaled up. These graphene-based strain sensors exhibit extremely high sensitivity with gauge factor of 1037 at 2% strain, which represents the highest value for graphene platelets at this small deformation so far. This simple fabrication for strain sensors with highly sensitive performance of strain sensor makes it a novel approach to applications in electronic skin, wearable sensors, and health monitoring platforms.

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Section: Self-assembly Processes Of Ultrathin Graphene Filmsmentioning

confidence: 99%

Large‐Area Ultrathin Graphene Films by Single‐Step Marangoni Self‐Assembly for Highly Sensitive Strain Sensing Application

Yang

et al. 2016

Adv Funct Materials

350

259

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“…The energy in the resonant modes can leak into the solar cells if the spheres are placed in close proximity [15]. Additionally, the dielectric sphere arrays have other advantages [15,[19][20][21][22][23][24]: 1) dielectric materials are optically lossless, the concern of parasitic absorption is not necessary; 2) the geometry of the spheres is symmetric, which allows a broader acceptance angle of incident light; 3) the sphere array can be fabricated by the simple and cheap self-assembly method rather than complicated and expensive lithography technologies; 4) the inorganic dielectric materials are thermally stable compared to metallic materials, which makes them compatible to the deposition of the CIGSe layer at high substrate temperatures.…”

Section: Introductionmentioning

confidence: 99%

Light absorption enhancement for ultra-thin Cu(In1−xGax)Se2 solar cells using closely packed 2-D SiO2 nanosphere arrays

Yin

Manley

Schmid

2016

Solar Energy Materials and Solar Cells

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“…As recently reviewed in detail by Jonas et al [6], MCC templates can be achieved by a variety of methods, including dip-coating, spin-coating, slope self-assembly, etc. [7][8][9][10][11][12]. Regarding infiltration and replication strategies, evaporation deposition, electrochemical deposition, and solution/sol-based infiltration methods are mainly included [13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Fabrication and Photo-Detecting Performance of 2D ZnO Inverse Opal Films

Lin

Chen

2016

Applied Sciences

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Two-dimensional (2D) ZnO inverse opal (IO) films were fabricated by co-assembly of sacrificed polystyrene (PS) microspheres and citric acid/zinc acetate (CA/ZA) aqueous solution at an oil-water interface followed by calcination. Their morphologies could be controlled by the surface property of polymer templates and CA/ZA molar ratio. Moreover, photo-detecting devices based on such films were constructed, which showed high photocurrent (up to 4.6 µA), excellent spectral selectivity, and reversible response to optical switch.

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Assembled Monolayers of Hydrophilic Particles on Water Surfaces

Cited by 171 publications

References 54 publications

Large‐Area Ultrathin Graphene Films by Single‐Step Marangoni Self‐Assembly for Highly Sensitive Strain Sensing Application

Large‐Area Ultrathin Graphene Films by Single‐Step Marangoni Self‐Assembly for Highly Sensitive Strain Sensing Application

Light absorption enhancement for ultra-thin Cu(In1−xGax)Se2 solar cells using closely packed 2-D SiO2 nanosphere arrays

Fabrication and Photo-Detecting Performance of 2D ZnO Inverse Opal Films

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