Abstract: Black phosphorous (BP) flakes are nanostructured via electrochemical intercalation of Na+ ions into bundles of phosphorene nanoribbons (PNRs). The large diffusion barrier of Na+ ions along the armchair direction leads to a well-defined columnar intercalation of Na+ ions in BP, resulting in the long zigzag-oriented columns of disordered material. The sonication of the bundles is then used to separate the PNRs.

Abstract: An anode material for lithium-ion batteries is provided that comprises an elongated core structure capable of forming an alloy with lithium; and a plurality of nanostructures placed on a surface of the core structure, with each nanostructure being capable of forming an alloy with lithium and spaced at a predetermined distance from adjacent nanostructures.

Abstract: The presently-disclosed subject matter provides microfluidic devices comprised of two or more carbon nanotube membranes disposed at predetermined intervals within a microchannel. Further provided are methods of using the same for the electrokinetic separation of one or more molecules of interest from a sample.

Abstract: An anode material for lithium-ion batteries is provided that comprises an elongated core structure capable of forming an alloy with lithium; and a plurality of nanostructures placed on a surface of the core structure, with each nanostructure being capable of forming an alloy with lithium and spaced at a predetermined distance from adjacent nanostructures.

Abstract: The presently-disclosed subject matter provides microfluidic devices comprised of two or more carbon nanotube membranes disposed at predetermined intervals within a microchannel. Further provided are methods of using the same for the electrokinetic separation of one or more molecules of interest from a sample.

Abstract: A method for fabricating graphene nanoribbons comprises the steps of providing a chamber with a first and a second cavity, which are separated by a divider that defines an opening to place the first cavity in fluid communication with the second cavity; positioning a graphite sample in the first cavity; positioning a container with a metal disposed therein in the second cavity; heating the container to expel a cloud of metal; injecting a gas into the second cavity to propel the cloud of metal through the opening and into the first cavity where it contacts the graphite sample to produce dislocation bands; removing the graphite sample from the chamber; and electrostatically depositing the dislocation bands on a substrate as graphene nanoribbons.

Abstract: A method for electrostatic deposition of graphene on a substrate comprises the steps of securing a graphite sample to a first electrode; electrically connecting the first electrode to a positive terminal of a power source; electrically connecting a second electrode to a ground terminal of the power source; placing the substrate over the second electrode; and using the power source to apply a voltage, such that graphene is removed from the graphite sample and deposited on the substrate.

Abstract: A method for electrostatic deposition of graphene on a substrate comprises the steps of securing a graphite sample to a first electrode; electrically connecting the first electrode to a positive terminal of a power source; electrically connecting a second electrode to a ground terminal of the power source; placing the substrate over the second electrode; and using the power source to apply a voltage, such that graphene is removed from the graphite sample and deposited on the substrate.