Abstract: Methods, apparatus, and system for storing perishable products in a vacuum container. An atmosphere control system is coupled to the vacuum container for measuring and maintaining controlled atmospheric conditions within the vacuum container. The atmosphere control system includes a plurality of monitors configured to monitor atmospheric conditions within the vacuum container. The atmosphere control system further includes a vacuum pump configured to reduce total absolute pressure in the vacuum chamber to below a total gas pressure limit, an ozone generator configured to generate gaseous ozone, and an inlet valve coupled to the ozone generator and configured to admit an ozone-containing gas into the vacuum container.

Abstract: A nanostructure is fabricated using charged particle deposition to deposit a catalyst on a substrate. A charged particle beam is directed to location on the substrate where the catalyst is to be deposited, with a beam-activated precursor gas also being directed to the location. For example, a nickel dot can be selectively deposited onto a substrate by using a charged particle beam to decompose a nickel-containing precursor gas, and then a carbon nanotube can be grown on the nickel dot, with the diameter of the nanotube conforming to the size of the nickel dot.

Abstract: A method of fabricating a nanotube probe tip and the resultant probe tip, particularly for use in an atomic force microscope. A moderately sharply peaked support structure has its tip cut or flattened to have a substantially flat end of size of about 20 to 200 nm across. The support structure may be formed by etching a conical end into a silica optical fiber. Nickel or other catalyzing metal such as iron is directionally sputtered onto the flat end and the sloped sidewalls of the support structure. The nickel is anisotropically etched to remove all the nickel from the sidewalls but leaving at least 15 nm on the flat end to form a small nickel dot. A nanotube is then grown with the nickel catalyzing its growth such that only a single nanotube forms on the nickel dot and its diameter conforms to the size of the nickel dot. In another preferred embodiment of the invention, a catalyst material can be directly deposited on to the probe end using charged particle beam deposition, such as electron beam deposition.

Abstract: A method of fabricating a nanotube probe tip and the resultant probe tip, particularly for use in an atomic force microscope. A moderately sharply peaked support structure has its tip cut or flattened to have a substantially flat end of size of about 20 to 200 nm across. The support structure may be formed by etching a conical end into a silica optical fiber. Nickel or other catalyzing metal such as iron is directionally sputtered onto the flat end and the sloped sidewalls of the support structure. The nickel is anisotropically etched to remove all the nickel from the sidewalls but leaving at least 15 nm on the flat end to form a small nickel dot. A nanotube is then grown with the nickel catalyzing its growth such that only a single nanotube forms on the nickel dot and its diameter conforms to the size of the nickel dot. In another preferred embodiment of the invention, a catalyst material can be directly deposited on to the probe end using charged particle beam deposition, such as electron beam deposition.

Abstract: A probe having a probe tip, especially for use in an atomic force microscope, formed by micromachining techniques in a silicon wafer. The tip is photolithographically defined in a layer, preferably of silicon nitride deposited on the silicon wafer, and has a width and thickness of usually less than 250 nm. Thereby, the probe tip can be formed to have a generally square cross section in which one lateral dimension is determined by the layer thickness, and the other lateral dimension by the photolithography or by a subsequent step of focused ion beam milling. The portion of the silicon wafer underlying the area probe tip is etched away, preferably before the probe tip is etched, but another portion of the silicon is left to serve as a support at the base of the probe tip. A hinge may be formed in the silicon wafer, and the probe tip together with a robust shank can be made to rotate to a direction perpendicular to the wafer surface.

Abstract: A method of fabricating a carbon nanotube probe tip and the resultant probe tip, particularly for use in an atomic force microscope. A moderately sharply peaked support structure has its tip cut or flattened to have a substantially flat end of size of about 20 to 200 nm across. The support structure may be formed by etching a conical end into a silica optical fiber. Nickel or other catalyzing metal such as iron is directionally sputtered onto the flat end and the sloped sidewalls of the support structure. The nickel is anisotropically etched to remove all the nickel from the sidewalls but leaving at least 15 nm on the flat end to form a small nickel dot. A carbon nanotube is then grown with the nickel catalyzing its growth such that only a single nanotube forms on the nickel dot and its diameter conforms to the size of the nickel dot.

Abstract: A probe tip manufactured from a conically shaped quartz tip etched to a fine apex. The quartz tip is coated with about 1 &mgr;m of a hard material such as silicon nitride. A probe tip having dimensions of about 100 nm×1 &mgr;m is then machined from the hard material adjacent to the apex of the quartz tip along the axis of the quartz tip. The machining is preferably performed by focused ion beam milling.

Abstract: A method of fabricating a carbon nanotube probe tip and the resultant probe tip, particularly for use in an atomic force microscope. A moderately sharply peaked support structure has its tip cut or flattened to have a substantially flat end of size of about 20 to 200 nm across. The support structure may be formed by etching a conical end into a silica optical fiber. Nickel or other catalyzing metal such as iron is directionally sputtered onto the flat end and the sloped sidewalls of the support structure. The nickel is anisotropically etched to remove all the nickel from the sidewalls but leaving at least 15 nm on the flat end to form a small nickel dot. A carbon nanotube is then grown with the nickel catalyzing its growth such that only a single nanotube forms on the nickel dot and its diameter conforms to the size of the nickel dot.

Abstract: Hydrogenation-dehydrogenation of suitable feedstock is provided wherein such feedstock is subjected to hydrogenation-dehydration conditions in the presence of a catalytic amount of a solid containing, at least in part, a synthetic amorphous solid prepared by hydrolyzing and polymerizing in the presence of water a silane having the formula R(Si)X.sub.3, wherein R is a nonhydrolyzable organic group, X is a hydrolyzable group and (Si) is selected from the group consisting of ##STR1## AND ##STR2## AND CALCINING THE POLYMERIZED PRODUCT, SAID SILANE BEING ADMIXED WITH A SECOND COMPOUND, R'.sub.n MY.sub.m, wherein R' is selected from the group consisting of the same groups as R, Y is selected from the group consisting of the same groups as X and oxygen, M is at least one member selected from the group consisting of the elements of Groups IIIA, IVA, IVB, VA, VB, VIB, VIIB and VIII of the Periodic Table, m is any number greater than 0 and up to 8 and n is from 0 to any number less than 8.

Abstract: Organic compound conversion in the presence of refractory metal oxide solid materials, characterized by the presence of surface hydroxyl groups, which have undergone modification by being subjected to the sequential steps of (1) silylating, (2) calcining and (3) steaming is provided. The silylating step in the modification of the refractory materials is accomplished by contacting the solid material with an organic- or halogen-substituted silane at a temperature of between about 25.degree. C and about 500.degree. C to effect bonding between the silane and the surface hydroxyl groups of the solid. The calcining step in the modification of the refractory materials is accomplished by heating the resulting silylated solid at a temperature and for a time sufficient to remove substantially all of any introduced organic or halogen substituent.

Abstract: Organic compound conversion in the presence of a new class of heterogeneous catalyst is provided. Said new class of heterogeneous catalyst comprises a substrate having a minimum surface area of about 10 m.sup.2 /g and having pores with a minimum pore diameter of about 5 Angstrom Units, said substrate being modified by at least one amine functional member coordinated to a metal function, said amine functional member acting as a bridging member between said substrate and said metal function.

Abstract: Refractory metal oxide solid materials, characterized by the presence of surface hydroxyl groups, which have undergone modification by being subjected to the sequential steps of (1) silylating, (2) calcining and (3) steaming are provided. Said silylating step is accomplished by contacting said solid material with an organic-or halogen-substituted silane at a temperature of between about 25.degree.C and about 500.degree.C to effect bonding between said silane and the surface hydroxyl groups of said solid. Said calcining step is accomplished by heating the resulting silylated solid at a temperature and for a time sufficient to remove substantially all of any introduced organic or halogen substituent. Said steaming step is accomplished by contacting the resulting calcined solid with an atmosphere containing at least 2 percent by volume of steam at a temperature of between about 900.degree.F and about 1600.degree.F for at least about 1/2 hour.Organic compound conversion, e.g.

Abstract: Complexed metals bonded to inorganic oxides are a new class of heterogeneous catalysts which display high upper reaction temperature limits, exceptional chemical and thermal stability and good catalytic activity for organic compound conversion. The catalyst of this invention comprises a substrate having a minimum surface area of about 10 m.sup.2 /g and having pores with a minimum pore diameter of about 5 Angstrom Units, said substrate being modified by at least one amine functional member coordinated to a metal function, said amine functional member acting as a bridging member between said substrate and said metal function.Also herein provided is a novel method of organic compound conversion which comprises contacting said organic compound with a catalytic amount of the above catalyst under organic compound conversion conditions.