Abstract: A method for producing carbon nanotubes having specific lengths, said method comprising: producing carbon nanotubes having at least two types of zones along their lengths, wherein each zone type has a characteristic structure that confers specific properties; and processing said carbon nanotubes to selectively attack one zone type more aggressively than another zone type.

Abstract: A method for performing a calculation operation to grade and catalog the repeatability of an author's technical or instructional publication or some sub-portion thereof, comprising: a first step of collecting data from a user or users with experience in said publication's replication; a second step of converting the elements of the data to numerical quantities; a third step of calculating a weighting function for that user or users and a weighting function for the author; a fourth step of multiplying elements or subsets of the data by a weighting function that may amplify or diminish the value of the data; a fifth step of aggregating the weighted subsets of data into one or more values; and a sixth step of weighting and averaging the data with historical data, if any.

Abstract: Painless, non-invasive nanofluidic delivery systems useful for the delivery of therapeutically active agents, GRAS agents, sterile fluids and inert fillers through epithelial membranes are described. The painless, non-invasive delivery system delivers a therapeutic agent via a micro-syringe-based assembly. The painless, non-invasive delivery system may also have a vehicle, which facilitates the absorption of the therapeutic agents by altering its absorption rate at the site of administration. Also disclosed is a method and components of the delivery system to administer therapeutic agents in a consistent, predictable and reproducible manner. Certain compositions may facilitate the delivery of different agents without altering the agents from their current or previous form.

Abstract: Apparatus for subcutaneously delivering a substance to a patient, said apparatus comprising: a carrier comprising a flexible body, wherein said flexible body comprises a reservoir, and further wherein said reservoir contains the substance which is to be delivered to the patient; a nanoneedle assembly comprising: a tubular body having a distal end and a proximal end; a base plate movably mounted intermediate said distal end and said proximal end of said tubular body, said base plate comprising a distal surface and a proximal surface, with a plurality of through-holes extending between said distal surface and said proximal surface of said base plate, said proximal surface of said base plate being in fluid communication with said reservoir; a plurality of nanoneedles, wherein each of said plurality of nanoneedles comprises a distal end, a proximal end, and a lumen extending therebetween, said proximal end of each of said plurality of nanoneedles being mounted to said base plate such that said lumen of each o

Abstract: A method for the production of a transparent conductor deposit on a substrate, the method comprising: providing a substrate formed from a first material; depositing a film of a second material on the substrate; causing the film to crack so as to provide a plurality of recesses; depositing a conductive material in the recesses; and removing the film from the substrate so as to yield a transparent conductive deposit on the substrate.

Abstract: A method for producing carbon nanotubes having specific lengths, said method comprising: producing carbon nanotubes having at least two types of zones along their lengths, wherein each zone type has a characteristic structure that confers specific properties; and processing said carbon nanotubes to selectively attack one zone type more aggressively than another zone type.

Abstract: Disclosed herein are embodiments of an electrochemical device comprising graphene material made using embodiments of the method disclosed herein. Also disclosed is a graphene electrode comprising the graphene material made using embodiments of the method disclosed herein. The graphene material disclosed herein for use in the disclosed electrochemical devices has superior properties and activity compared to carbon-based materials known and used in the art. The disclosed graphene material can be used in multiple different technologies, such as water treatment, batteries, fuel cells, electrochemical sensors, solar cells, and ultracapacitors (both aqueous and non-aqueous).

Abstract: A method is disclosed for producing graphenic materials by templated growth along a preformed graphenic material lattice edge, wherein at least one of the graphenic material or template is translated during growth of the graphenic material. A method for preparing CNTs from preformed CNT substrates in the presence of cylindrical templating structures and a reactive carbon source in a fluid phase is also disclosed, wherein at least one of the CNT substrate or the cylindrical templating structure is translated during addition of carbon atoms to the CNT substrate. A method is also disclosed for preparing CNTs from preformed CNT substrates in the presence of cylindrical templating structures and a carbon source in a fluid phase, wherein non-thermalized excited states are produced on the CNT substrate and at least one of the CNT substrate or the cylindrical templating structure is translated during addition of carbon atoms to the CNT substrate.

Abstract: A method is disclosed for producing graphenic materials by templated growth along a preformed graphenic material lattice edge, wherein at least one of the graphenic material or template is translated during growth of the graphenic material. A method for preparing CNTs from preformed CNT substrates in the presence of cylindrical templating structures and a reactive carbon source in a fluid phase is also disclosed, wherein at least one of the CNT substrate or the cylindrical templating structure is translated during addition of carbon atoms to the CNT substrate. A method is also disclosed for preparing CNTs from preformed CNT substrates in the presence of cylindrical templating structures and a carbon source in a fluid phase, wherein non-thermalized excited states are produced on the CNT substrate and at least one of the CNT substrate or the cylindrical templating structure is translated during addition of carbon atoms to the CNT substrate.

Abstract: A method is disclosed for producing graphenic materials by templated growth along a preformed graphenic material lattice edge, wherein at least one of the graphenic material or template is translated during growth of the graphenic material. A method for preparing CNTs from preformed CNT substrates in the presence of cylindrical templating structures and a reactive carbon source in a fluid phase is also disclosed, wherein at least one of the CNT substrate or the cylindrical templating structure is translated during addition of carbon atoms to the CNT substrate. A method is also disclosed for preparing CNTs from preformed CNT substrates in the presence of cylindrical templating structures and a carbon source in a fluid phase, wherein non-thermalized excited states are produced on the CNT substrate and at least one of the CNT substrate or the cylindrical templating structure is translated during addition of carbon atoms to the CNT substrate.