Abstract: A reduced pressure treatment appliance is provided for treating a wound on the body of a patient. In some embodiments, the appliance comprises an overlay, which is further comprised of cup members that may be detached or cut away from the overlay so that the overlay can be adjusted in size and shape. Also, in some embodiments, the overlay is further comprised of a pressure venting valve to maintain a predetermined level of reduced pressure at the site of the wound. In other embodiments, the wound treatment appliance also includes a vacuum system to supply reduced pressure to the site of the wound in the volume under the overlay. In yet other embodiments, the treatment appliance also includes wound packing means to prevent overgrowth of the wound or to encourage growth of wound tissue into an absorbable matrix comprising the wound packing means. In still other embodiments, a suction bulb may be used to provide a source of reduced pressure to an overlay that covers the wound.

Abstract: Coatings configured to change between a relatively higher reflectivity state and a relatively lower reflectivity state depending at least partially upon temperature are generally disclosed. Some example coatings may include a selectively reflective layer including a plurality of microcapsules, which may include an ionic liquid and/or a surfactant within a shell. The microcapsules may have a relatively higher reflectively when at temperatures above a cloud transition temperature and/or a relatively lower reflectivity when at temperatures below the cloud transition temperature. When at temperatures above the cloud transition temperature, the selectively reflective layer may reflect a first fraction of the incident light When at temperatures below the cloud transition temperature, the selectively reflective layer may reflect a second fraction of the incident light. The first fraction of the incident light may be greater than the second fraction of the incident light.

Abstract: A solvent composition comprising an organic solvent; dispersed nanoparticles; and a non-volatile electrolyte is provided. A method of forming a liquid composite composition is provided.

Abstract: A stand-off is necessary to separate two glass lites (panes of glass) in a vacuum insulated glazing system. This stand-off must provide sufficient mechanical support to keep the lites apart despite one atmosphere pressure pushing the lites together. For systems that are designed with flexible edge seals, there will be movement of one lite relative to the other during diurnal cycling, and the stand-offs will therefore be scraped against at least one of the lite surfaces. Because many mechanically robust materials suitable for stand-offs have high friction, it is beneficial to apply a lubricant to the surface of the stand-off. However, it is also beneficial to adhere the stand-off to one lite during the manufacturing operation, and this need opposes the need for good lubricity. This invention describes means for optimizing the composition of a stand-off to meet these conflicting needs.

Abstract: Technologies are generally described for a photoresist and methods and systems effective to form a pattern in a photoresist on a substrate. In some examples, the photoresist includes a resin, a photoinitiator and a photoinhibitor. The photoinitiator may be effective to generate a first reactant upon the absorption of at least one photon of a particular wavelength of light. The first reactant may be effective to render the resin soluble or insoluble in a photoresist developer. The photoinhibitor may be effective to generate a second reactant upon the absorption of at least one photon of the particular wavelength of light. The second reactant may be effective to inhibit the first reactant.

Abstract: Coatings configured to change between a relatively higher reflectivity state and a relatively lower reflectivity state depending at least partially upon temperature are generally disclosed. Some example coatings may include a selectively reflective layer including a plurality of microcapsules, which may include an ionic liquid and/or a surfactant within a shell. The microcapsules may have a relatively higher reflectively when at temperatures above a cloud transition temperature and/or a relatively lower reflectivity when at temperatures below the cloud transition temperature. When at temperatures above the cloud transition temperature, the selectively reflective layer may reflect a first fraction of the incident light. When at temperatures below the cloud transition temperature, the selectively reflective layer may reflect a second fraction of the incident light. The first fraction of the incident light may be greater than the second fraction of the incident light.

Abstract: A reduced pressure treatment appliance is provided for treating a wound on the body of a patient. In some embodiments, the appliance comprises an overlay, which is further comprised of cup members that may be detached or cut away from the overlay so that the overlay can be adjusted in size and shape. Also, in some embodiments, the overlay is further comprised of a pressure venting valve to maintain a predetermined level of reduced pressure at the site of the wound. In other embodiments, the wound treatment appliance also includes a vacuum system to supply reduced pressure to the site of the wound in the volume under the overlay. In yet other embodiments, the treatment appliance also includes wound packing means to prevent overgrowth of the wound or to encourage growth of wound tissue into an absorbable matrix comprising the wound packing means. In still other embodiments, a suction bulb may be used to provide a source of reduced pressure to an overlay that covers the wound.

Abstract: A solvent composition comprising an organic solvent; dispersed nanoparticles; and a non-volatile electrolyte.

Abstract: Technologies are generally described for perforated graphene monolayers and membranes containing perforated graphene monolayers. An example membrane may include a graphene monolayer having a plurality of discrete pores that may be chemically perforated into the graphene monolayer. The discrete pores may be of substantially uniform pore size. The pore size may be characterized by one or more carbon vacancy defects in the graphene monolayer. The graphene monolayer may have substantially uniform pore sizes throughout. In some examples, the membrane may include a permeable substrate that contacts the graphene monolayer and which may support the graphene monolayer. Such perforated graphene monolayers, and membranes comprising such perforated graphene monolayers may exhibit improved properties compared to conventional polymeric membranes for gas separations, e.g., greater selectivity, greater gas permeation rates, or the like.

Abstract: Technologies are generally described for a membrane that may incorporate a graphene layer perforated by a plurality of nanoscale pores. The membrane may also include a gas sorbent that may be configured to contact a surface of the graphene layer. The gas sorbent may be configured to direct at least one gas adsorbed at the gas sorbent into the nanoscale pores. The nanoscale pores may have a diameter that selectively facilitates passage of a first gas compared to a second gas to separate the first gas from a fluid mixture of the two gases. The gas sorbent may increase the surface concentration of the first gas at the graphene layer. Such membranes may exhibit improved properties compared to conventional graphene and polymeric membranes for gas separations, e.g., greater selectivity, greater gas permeation rates, or the like.

Abstract: The present application is directed to a reservoir for use with a micro-electromechanical device having a first surface area to be lubricant. The reservoir comprises a solid component with a porous structure having a second surface area. The second surface area is greater than the first surface area. The reservoir also comprises a lubricant capable of reversibly reacting with either the solid component or the first surface area of the micro-electromechanical device.

Abstract: Technologies are generally described for a method and system configured effective to alter a defect area in a layer on a substrate including graphene. An example method may include receiving and heating the layer to produce a heated layer and exposing the heated layer to a first gas to produce a first exposed layer, where the first gas may include an amine. The method may further include exposing the first exposed layer to a first inert gas to produce a second exposed layer and exposing the second exposed layer to a second gas to produce a third exposed layer where the second gas may include an alane or a borane. Exposure of the second exposed layer to the second gas may at least partially alter the defect area.

Abstract: Technologies are generally described for method and systems effective to at least partially alter a defect in a layer including graphene. In some examples, the methods may include receiving the layer on a substrate where the layer includes at least some graphene and at least some defect areas in the graphene. The defect areas may reveal exposed areas of the substrate. The methods may also include reacting the substrate under sufficient reaction conditions to produce at least one cationic area in at least one of the exposed areas. The methods may further include adhering graphene oxide to the at least one cationic area to produce a graphene oxide layer. The methods may further include reducing the graphene oxide layer to produce at least one altered defect area in the layer.

Abstract: Technologies are generally described for a method and system configured effective to detect a defect in a sample including graphene. An example method may include receiving a sample, where the sample may include at least some graphene and at least some defects in the graphene. The method may further include exposing the sample to a gas under sufficient reaction conditions to produce a marked sample, where the marked sample may include marks bonded to at least some of the defects. The method may further include placing the marked sample in a detector system. The method may also include detecting at least some of the marks with the detector system.

Abstract: Techniques related to nanocomposite dielectric materials are generally described herein. These techniques may be embodied in apparatuses, systems, methods and/or processes for making and using such material. An example process may include: providing a film having a plurality of nanoparticles and an organic medium; comminuting the film to form a particulate; and applying the particulate to a substrate. The example process may also include providing a nanoparticle film having nanoparticles and voids located between the nanoparticles; contacting the film with a vapor containing an organic material; and curing the organic material to form the nanocomposite dielectric film. Various described techniques may provide nanocomposite dielectric materials with superior nanoparticle dispersion which may result in improved dielectric properties.

Abstract: Corrosion control in reinforced concrete is generally disclosed. Some example embodiments may include concrete including aggregate, cement, and/or microcapsules distributed within the cement, where the individual microcapsules may include a high pH salt substantially contained within an acid-soluble shell. If the pH of the concrete decreases, the acid soluble shell may swell and/or dissolve, such as below a pH of about 11, which may release the high pH salt. The high pH salt may locally increase the pH of the concrete. By increasing the pH above about pH 11, corrosion of steel rebar may be prevented and/or reduced.

Abstract: Examples that are described herein provide systems and methods for creating virtual areas for realtime communications. Some examples provide a quick and easy process for creating a virtual area for a set of communicants and provisioning those communicants for realtime communications in the virtual area. Some examples provide a quick and easy way for a user to wrap a realtime communications framework around a network service. Through seamless integration of realtime communications (e.g., realtime audio, video, chat, screen sharing, and file transfer) in persistent virtual areas, these examples are able to enhance and improve communicants' experiences with a network service relative to traditional browser based methods of collaborating on network service based projects.

Abstract: Implementations and techniques for sensing hydroxyl radicals in ozone washing systems are generally disclosed.

Abstract: Coatings configured to change between a relatively higher reflectivity state and a relatively lower reflectivity state depending at least partially upon temperature are generally disclosed. Some example coatings may include a selectively reflective layer including a plurality of microcapsules, which may include an ionic liquid and/or a surfactant within a shell. The microcapsules may have a relatively higher reflectively when at temperatures above a cloud transition temperature and/or a relatively lower reflectivity when at temperatures below the cloud transition temperature. When at temperatures above the cloud transition temperature, the selectively reflective layer may reflect a first fraction of the incident light. When at temperatures below the cloud transition temperature, the selectively reflective layer may reflect a second fraction of the incident light. The first fraction of the incident light may be greater than the second fraction of the incident light.

Abstract: Coatings configured to change between a relatively higher reflectivity state and a relatively lower reflectivity state depending at least partially upon a hydration state of at least a portion of the coating are generally disclosed. Some example coatings may include a selectively reflective layer comprising superabsorbent particles. The superabsorbent particles may have a relatively higher reflectively when substantially dry and a relatively lower reflectivity when substantially hydrated. When substantially dry, the selectively reflective layer may reflect a first fraction of incident light. When substantially hydrated, the selectively reflective layer may reflect a second fraction of the incident light. The first fraction of the incident light may be greater than the second fraction of the incident light.