The Promise of Soft‐Matter‐Enabled Quantum Materials

Thedford, R. Paxton; Yu, Fei; Tait, William R. T.; Shastri, Kunal; Monticone, Francesco; Wiesner, Ulrich

doi:10.1002/adma.202203908

Cited by 4 publications

(5 citation statements)

References 379 publications

(612 reference statements)

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“…Understanding the principles governing the formation of different ordered phases from polymeric systems containing block copolymers has been an active research topic in polymer science for the past several decades . Besides providing a platform for studying fundamental principles of self-assembly, block copolymers have found applications in a wide range of technologies such as lithography, − photonics, − and soft-matter enabled quantum materials …”

Section: Introductionmentioning

confidence: 99%

“…1 Besides providing a platform for studying fundamental principles of self-assembly, block copolymers have found applications in a wide range of technologies such as lithography, 5−8 photonics, 9−13 and soft-matter enabled quantum materials. 14 An extensively studied system of block copolymers is monodisperse AB diblock copolymers composed of the simplest block copolymer obtained by covalently linking two homopolymers, A and B, through their ends. Due to the tremendous efforts by experimenters and theorists over the past several decades, the phase behavior of AB diblock copolymers is well understood.…”

Section: ■ Introductionmentioning

confidence: 99%

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Phase Behavior of Binary Blends of Diblock Copolymers: Progress and Opportunities

Xie

Shi

2023

Langmuir

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The phase behavior of binary blends of diblock copolymers has been examined extensively in the past decades.Experimental and theoretical studies have demonstrated that mixing two different block copolymers provides an efficient and versatile route to regulate their self-assembled morphologies. A good understanding of the principles governing the self-assembly of block copolymer blends has been obtained from the study of A 1 B 1 / A 2 B 2 diblock copolymer blends. The second (A 2 B 2 ) diblocks could act synergistically as fillers and cosurfactants to regulate the domain size and interfacial properties, resulting in the formation of ordered phases not found in the parent (A 1 B 1 or A 2 B 2 ) diblock copolymer melts. The study of A 1 B 1 /A 2 B 2 block copolymer blends further provides a solid foundation for future research on more complex block copolymer blends.

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Section: Introductionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

Phase Behavior of Binary Blends of Diblock Copolymers: Progress and Opportunities

Xie

Shi

2023

Langmuir

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“…2 Block copolymers alleviate this frustration by microphase separation into polymeric domains, which in turn pack to form ordered structures at 10-100 nanometer scale. 3,4 The spontaneous emergence of long-range ordered structures in block copolymers not only leads to potential technological applications, [5][6][7][8][9] but also offers an ideal platform to study the spontaneous emergence of structured matter.…”

Section: Introductionmentioning

confidence: 99%

Regulating the self‐assembly of AB/CD diblock copolymer blends via secondary interactions

Xie

Lai

Shi

2023

Journal of Polymer Science

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Designed multiblock copolymers with complex architectures offer unlimited opportunities to obtain novel nanostructured phases, however, their synthesis could be challenging and expensive. An alternative approach to access desired nanostructures is to use blends of block copolymers with simple chain architectures and designed block‐block interactions. We use binary blends composed of AB and CD diblock copolymers as a model system to establish design principles of polymeric blends containing block copolymers. Specifically, we explore the phase behavior of AB/CD blends by using the polymeric self‐consistent field theory to construct phase diagrams of the blends focusing on the sphere‐forming regions in the phase space. We predict the formation of various spherical packing phases composed of either core‐shell‐structured spheres or binary spheres resembling metallic alloys. We demonstrate that the equilibrium morphology can be regulated by adjusting the blend composition and molecular parameters such as block fractions, conformational asymmetry, and segment‐segment interactions. The strategy of using secondary interaction in polymeric blends to control the phase behavior explored in the current study can also be generalized to other soft matter systems.

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“…This scenario requires nanomaterials with sufficient mechanical integrity to withstand the devices’ manufacturing and integration processes, as well as durability and good adhesion in in-operando conditions. Template-assisted self-assembly, a settled strategy for fabricating ordered porous thin films, is recognized as a breakthrough in material nanoengineering. , Nanoporous materials built with this technique exhibit a very high surface area, controlled thickness, and accessible porosity, enabling applications in catalysis, optical sensors, , photovoltaic devices, microfluidics, microelectronics , and quantum materials . Furthermore, recent investigations into the acoustic response (hypersound) of nanoporous oxides in the GHz range , have opened the doors to applications in the fields of acoustic and optomechanical nanodevices.…”

Section: Introductionmentioning

confidence: 99%

“…1,2 Nanoporous materials built with this technique exhibit a very high surface area, controlled thickness, and accessible porosity, enabling applications in catalysis, 3 optical sensors, 4,5 photovoltaic devices, 6 microfluidics, 7 microelectronics 8,9 and quantum materials. 10 Furthermore, recent investigations into the acoustic response (hypersound) of nanoporous oxides in the GHz range 11,12 have opened the doors to applications in the fields of acoustic and optomechanical nanodevices.…”

Section: ■ Introductionmentioning

confidence: 99%

Optical Readout of the Mechanical Properties of Silica Mesoporous Thin Films Using Plasmonic Nanoantennas

Boggiano,

Ramallo,

Nan

et al. 2023

ACS Photonics

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In this work, we apply the recently developed frequency shift of nanoantennas (FRESA) technique to measure the Young's modulus of thin mesoporous films at GHz frequencies as a function of porosity with local precision. The method measures changes in the mechanical oscillation frequency of optically excited plasmonic nanoantennas with modification of their surrounding medium. The values obtained range from 4 to 10 GPa for porosities extending from 35 to 4%, compatible with reports on films grown under similar conditions. We further find comparable results when using the well-established nanoindentation (NI) technique, validating the new method. By analysis of the nanoresonator's quality factor, the measurement reveals an excellent interfacial adhesion of the films to the nanoantennas. Different from most other characterization techniques, FRESA provides elastic modulus determination at GHz frequencies, relevant for the operation of current devices. Furthermore, FRESA exhibits, in principle, no limitations in terms of film thickness, in contrast to the NI, which is strongly affected by the stiffness of the substrate for ultrathin films.

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The Promise of Soft‐Matter‐Enabled Quantum Materials

Cited by 4 publications

References 379 publications

Phase Behavior of Binary Blends of Diblock Copolymers: Progress and Opportunities

Phase Behavior of Binary Blends of Diblock Copolymers: Progress and Opportunities

Regulating the self‐assembly of AB/CD diblock copolymer blends via secondary interactions

Optical Readout of the Mechanical Properties of Silica Mesoporous Thin Films Using Plasmonic Nanoantennas

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