Methods, systems, and devices are disclosed for performing mechanosynthesis, including those that involve bulk chemical preparation of tips, multiple tips for supplying feedstock, and use of sequential tips such as in a thermodynamic cascade; such features may simplify starting requirements, increase versatility, and/or reduce complexity in the mechanosynthesis equipment and/or process.

A porous composite structure including a substrate including a plurality of nanostructures; a particle layer disposed on a surface of the substrate; and a liquid, a method of preparing the porous composite structure, an article including the porous composite structure, and an air purifier including the porous composite structure.

Graphene-carbon nanotube multi-stack three-dimensional architectures (graphene-CNT stacks) are formed by a “popcorn-like” growth method, in which carbon nanotubes are grown throughout the architecture in a continuous step. Alternating layers of graphene and a transition metal are grown by a vapor deposition process. The metal is fragmented and etched to form an array of catalytic sites. Carbon nanotubes grow from the catalytic sites in a vapor-solid-liquid process. The graphene-CNT stacks have applications in electrical energy storage devices, such as supercapacitors and batteries. The directly grown carbon nanotube array between graphene layers provides ease of ion diffusion and electron transfer, in addition to being an active material, spacer and electron pathway.

Metallic nanorods are welded together in a controllable fashion. A suspension of metallic nanorods coated with an anionic polymer is contracted with linking molecules each comprising a liquid crystal with at least two available carboxylic acid moieties. The nanoparticles to self-assemble into dimers. Irradiation of the dimers with femtosecond radiation forms a metallic junction between them and welds the dimers into fused dimers.

The present invention generally relates to nanofabrication and, in some embodiments, to methods of synthesizing selectively binding patched nanoparticles and the devices that can be made from them. In some embodiments, the invention relates to methods of assembling arbitrarily shaped structures from patched nanocubes and the devices and uses that follow. For example, nanocube building blocks may be patched by stamping their faces with a selectively binding chemical species (e.g. DNA, antibody-antigen pairs, etc.), or by using self-assembly to attach to the nanocubes multiple selectively binding patch species whose immiscibility can be preprogrammed. Arbitrarily shaped structures can then be designed and assembled by deciding which faces will be bonded to each other in some target structure and combining nanocubes that have selectively binding patches on those faces. Other aspects of the invention are also directed to methods of making such nanocubes or other nanoparticles, methods of forming such nanocubes or other nanoparticles into devices, devices formed from such nanocubes or other nanoparticles, kits including such nanocubes, nanoparticles, or devices, or the like.

Methods, systems, and devices are disclosed for performing mechanosynthesis, including those that involve bulk chemical preparation of tips, multiple tips for supplying feedstock, and use of sequential tips such as in a thermodynamic cascade; such features may simplify starting requirements, increase versatility, and/or reduce complexity in the mechanosynthesis equipment and/or process.

A microrobot and manufacturing method thereof are provided. The microrobot includes a first block, a second block, and a third block connected with each other. The first block is disposed between the second block and the third block. The first block includes polydimethylsiloxane. The second block and the third block include a mixture, and the mixture includes polydimethylsiloxane and neodymium magnet particles. The manufacturing method of the microrobot includes the steps of providing a first acrylic mold with an accommodating space and a second acrylic mold with a U-shaped groove; injecting polydimethylsiloxane into the accommodating space; placing the second acrylic mold in the accommodating space; taking out the second acrylic mold and injecting the mixture into the accommodating space to obtain a microrobot. Placing the microrobot on an electromagnet platform can achieve an object of mixing and dissolving an embolism in a flow channel.

The invention relates to a novel method of producing hetero-oligomeric pores. The invention also relates to hetero-oligomeric pores produced using the method and polynucleotide characterisation using the hetero-oligomeric pores.

The invention relates to a novel method of producing hetero-oligomeric pores. The invention also relates to hetero-oligomeric pores produced using the method and polynucleotide characterisation using the hetero-oligomeric pores.

According to embodiments of the present invention, a method of interconnecting nanowires is provided. The method includes providing a plurality of nanowires, providing a plurality of nanoparticles, and fusing the plurality of nanoparticles to the plurality of nanowires to interconnect the plurality of nanowires to each other via the plurality of nanoparticles. According to further embodiments of the present invention, a nanowire network and a transparent conductive electrode are also provided.