Unusual packing of soft-shelled nanocubes

Lu, Fang; Vo, Thi; Zhang, Yugang; Frenkel, Alex; Yager, Kevin G.; Kumar, Sanat K.; Gang, Oleg

doi:10.1126/sciadv.aaw2399

Cited by 56 publications

(104 citation statements)

References 52 publications

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“…From the selfassembly perspective, the challenge of creating structurally robust and ratio nally organized complex 3D nanomaterials is well recognized. For example, a comprehensive strategy for the assembly of designed NP lattices using polyhedral DNA origami constructs of different shapes (26)(27)(28)(29) and particles of different geometries (30,31) for the forma tion of diverse types of lattice symmetries has been demonstrated. Given the exquisite structural control offered by DNA in creating complex 3D structures with integrated functional nanoobjects (13,16,(32)(33)(34)(35), it is increasingly important to have the ability to translate the assembly methodology into a generation of materials that are not limited by the environmental requirements of DNA.…”

Section: Introductionmentioning

confidence: 99%

Resilient three-dimensional ordered architectures assembled from nanoparticles by DNA

et al. 2021

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Rapid developments of DNA-based assembly methods provide versatile capabilities in organizing nanoparticles (NPs) in three-dimensional (3D) organized nanomaterials, which is important for optics, catalysis, mechanics, and beyond. However, the use of these nanomaterials is often limited by the narrow range of conditions in which DNA lattices are stable. We demonstrate here an approach to creating an inorganic, silica-based replica of 3D periodic DNA-NP structures with different lattice symmetries. The created ordered nanomaterials, through the precise 3D mineralization, maintain the spatial topology of connections between NPs by DNA struts and exhibit a controllable degree of the porosity. The formed silicated DNA-NP lattices exhibit excellent resiliency. They are stable when exposed to extreme temperatures (>1000°C), pressures (8 GPa), and harsh radiation conditions and can be processed by the conventional nanolithography methods. The presented approach allows the use of a DNA assembly strategy to create organized nanomaterials for a broad range of operational conditions.

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Section: Introductionmentioning

confidence: 99%

Resilient three-dimensional ordered architectures assembled from nanoparticles by DNA

et al. 2021

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“…Our capability to measure facet-dependent interfacial stiffness and our demonstration on their role in shaping the supracrystals can advance crystal design at the nanoscale. For example, one can control the interfacial stiffness and crystal habit by utilizing the toolkits of both intrinsic parameters of NP shape and surface chemistry 41 , 54 – 56 as well as extrinsic parameters, such as temperature, pH, and ionic strength 57 – 59 . Previously reports have shown that changing the length of DNA ligands on the same gold NPs has led to tunability in the lattice symmetry of the interior structure and exposed facets of the supracrystal 17 , 55 , 60 .…”

Section: Discussionmentioning

confidence: 99%

Imaging how thermal capillary waves and anisotropic interfacial stiffness shape nanoparticle supracrystals

Yao

et al. 2020

Nat Commun

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Development of the surface morphology and shape of crystalline nanostructures governs the functionality of various materials, ranging from phonon transport to biocompatibility. However, the kinetic pathways, following which such development occurs, have been largely unexplored due to the lack of real-space imaging at single particle resolution. Here, we use colloidal nanoparticles assembling into supracrystals as a model system, and pinpoint the key role of surface fluctuation in shaping supracrystals. Utilizing liquid-phase transmission electron microscopy, we map the spatiotemporal surface profiles of supracrystals, which follow a capillary wave theory. Based on this theory, we measure otherwise elusive interfacial properties such as interfacial stiffness and mobility, the former of which demonstrates a remarkable dependence on the exposed facet of the supracrystal. The facet of lower surface energy is favored, consistent with the Wulff construction rule. Our imaging–analysis framework can be applicable to other phenomena, such as electrodeposition, nucleation, and membrane deformation.

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“…Through the programmable base-pairing interactions, highly ordered crystalline assemblies are extensively explored in recent years by Mirkin, Gang, and others. [9,42,[104][105][106][107][108][109][110] For the monary particle self-assembly, Mirkin and co-workers assembled triangular bipyramids (TBPs) into clathrate architectures (Figure 3a-g). [106] In their work, the uniform TBPs with ≈250 nm long edge and ≈177 nm short edge was first synthesized and then modified with 28-base hexylthiol-DNA strands.…”

Section: Nanoparticle Superlatticesmentioning

confidence: 99%

Rationally Programming Nanomaterials with DNA for Biomedical Applications

Gang

et al. 2021

Advanced Science

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DNA is not only a carrier of genetic information, but also a versatile structural tool for the engineering and self-assembling of nanostructures. In this regard, the DNA template has dramatically enhanced the scalability, programmability, and functionality of the self-assembled DNA nanostructures. These capabilities provide opportunities for a wide range of biomedical applications in biosensing, bioimaging, drug delivery, and disease therapy. In this review, the importance and advantages of DNA for programming and fabricating of DNA nanostructures are first highlighted. The recent progress in design and construction of DNA nanostructures are then summarized, including DNA conjugated nanoparticle systems, DNA-based clusters and extended organizations, and DNA origami-templated assemblies. An overview on biomedical applications of the self-assembled DNA nanostructures is provided. Finally, the conclusion and perspectives on the self-assembled DNA nanostructures are presented.

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Unusual packing of soft-shelled nanocubes

Cited by 56 publications

References 52 publications

Resilient three-dimensional ordered architectures assembled from nanoparticles by DNA

Resilient three-dimensional ordered architectures assembled from nanoparticles by DNA

Imaging how thermal capillary waves and anisotropic interfacial stiffness shape nanoparticle supracrystals

Rationally Programming Nanomaterials with DNA for Biomedical Applications

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