Epitaxial lift-off of electrodeposited single-crystal gold foils for flexible electronics

Mahenderkar, Naveen K.; Chen, Qingzhi; Liu, Ying-Chau; Duchild, Alexander R.; Hofheins, Seth; Chason, Eric; Switzer, Jay A.

doi:10.1126/science.aam5830

Cited by 115 publications

(132 citation statements)

References 37 publications

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“…Behavior at a substrate surface represents an active area of research in both atomic and PAE systems due to the unique properties that arise from interfacial interactions, as well as potential applications that thin film materials enable . In this regard, a number of studies have explored the thermodynamics and kinetics of PAE adsorption to a functionalized surface.…”

Section: Directly Analogizing Colloidal Pae Assembly To Atomic Crystamentioning

confidence: 99%

Programmable Atom Equivalents: Atomic Crystallization as a Framework for Synthesizing Nanoparticle Superlattices

Gabrys

Zornberg

Macfarlane

2019

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Decades of research efforts into atomic crystallization phenomenon have led to a comprehensive understanding of the pathways through which atoms form different crystal structures. With the onset of nanotechnology, methods that use colloidal nanoparticles (NPs) as nanoscale “artificial atoms” to generate hierarchically ordered materials are being developed as an alternative strategy for materials synthesis. However, the assembly mechanisms of NP‐based crystals are not always as well‐understood as their atomic counterparts. The creation of a tunable nanoscale synthon whose assembly can be explained using the context of extensively examined atomic crystallization will therefore provide significant advancement in nanomaterials synthesis. DNA‐grafted NPs have emerged as a strong candidate for such a “programmable atom equivalent” (PAE), because the predictable nature of DNA base‐pairing allows for complex yet easily controlled assembly. This Review highlights the characteristics of these PAEs that enable controlled assembly behaviors analogous to atomic phenomena, which allows for rational material design well beyond what can be achieved with other crystallization techniques.

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Section: Directly Analogizing Colloidal Pae Assembly To Atomic Crystamentioning

confidence: 99%

Programmable Atom Equivalents: Atomic Crystallization as a Framework for Synthesizing Nanoparticle Superlattices

Gabrys

Zornberg

Macfarlane

2019

Small

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“…For miniaturization of functional devices and flourishing development of nano‐optics, nanometal thin films serving as a typical building block play more and more important roles in boosting performances . For example, with ultrasmooth surface morphology, excellent stability, superior densification, and good adhesion to substrates, Al‐doped silver films have significantly improved efficiency of solar cells, photothermal conversion coatings, optical waveguide structures, and electromagnetic metamaterials .…”

Section: Introductionmentioning

confidence: 99%

On‐Demand Preparation of α‐Phase‐Dominated Tungsten Films for Highly Qualified Thermal Reflectors

Wang

Zang

Gao

et al. 2019

Adv Materials Inter

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Phase‐structure diversity affords tungsten thin films with fascinating physical/chemical properties for varied applications. However, the on‐demand preparation of W films with specific phase is still an important but unmet scientific issue. In this report, an easy‐to‐achieve preparation recipe is implemented for addressing the phase tailoring of tungsten films. The phase transformation evolution during deposition is governed by enhanced diffusion of W adatoms and selective atomic etching on the crystal planes. It is experimentally demonstrated that the orientation relation between {210}β and {110}α planes plays a vital role in coupling with the competitive growth behaviors between β‐ and α‐W. The phase‐dependent electrical/optical properties of W films are experimentally observed and unambiguously figured out by theoretical simulations. Alpha‐phase‐dominated W films are prepared successfully under relatively tolerant conditions, demonstrating a low resistivity of ≈13.6 µΩ cm and a high infrared reflectance larger than 93%. Alpha‐W also serves as thermal reflector to construct a solar absorber, exhibiting a low thermal emissivity of ≈9.8%@500 °C. Understanding the (α, β) phase transformation mechanism means a big step forward in the development of the on‐demand preparation, which allows to build a scalable platform for making W films with specific phase in a more controllable way.

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“…However, transferring techniques have relatively long history and are well developed from late 1980s to nowadays . Especially, in the past years transfer print techniques have improved rapidly . Many of these techniques have provided a pathway to scientific and technological breakthroughs, including creating large‐area metamaterials, transferring crystalline gold films, stacking micro‐structures and depositing diodes on desired surfaces .…”

Section: Introductionmentioning

confidence: 99%

“…Especially, in the past years transfer print techniques have improved rapidly . Many of these techniques have provided a pathway to scientific and technological breakthroughs, including creating large‐area metamaterials, transferring crystalline gold films, stacking micro‐structures and depositing diodes on desired surfaces . Since transfer print technology can be used in various experimental studies and since it provides a powerful tool for many applications, this indicates that there is a need to develop this technology further.…”

Section: Introductionmentioning

confidence: 99%

Micro Grating Deposition on Non‐Planar Surfaces by Polymer‐Assisted Transfer Printing

Balogun

Pekkarinen

Saarinen

et al. 2019

Physica Status Solidi (b)

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By spin‐coating a few hundred of nanometer thick poly(methyl methacrylate) (PMMA) film on a micron or a sub‐micron scale structure, the structure can be transferred on an arbitrary substrate. More precisely, by using a thin PMMA support layer and releasing the structure from the transient substrate into water, the PMMA with the structure can be collected on a desired substrate. Here, this technique is demonstrated to be suitable for transferring metallic binary grating and few‐layer Bragg gratings from flat substrates onto 3D‐printed convex lenses. Moreover, the thin PMMA film is sufficiently strong to support centimeter size free‐standing areas. This enables fabrication of 1.5 μm thick, free‐standing structure of a Bragg‐grating with PMMA. Thus, the presented technique provides a powerful tool for transfer printing of micron scale structures.

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Epitaxial lift-off of electrodeposited single-crystal gold foils for flexible electronics

Cited by 115 publications

References 37 publications

Programmable Atom Equivalents: Atomic Crystallization as a Framework for Synthesizing Nanoparticle Superlattices

Programmable Atom Equivalents: Atomic Crystallization as a Framework for Synthesizing Nanoparticle Superlattices

On‐Demand Preparation of α‐Phase‐Dominated Tungsten Films for Highly Qualified Thermal Reflectors

Micro Grating Deposition on Non‐Planar Surfaces by Polymer‐Assisted Transfer Printing

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