A micro electromechanical (mem) device includes a first electrode, a second electrode, and a shaped carbon nanotube with a first end and a second end. The first end of the shaped carbon nanotube is conductively connected to the first electrode and the second end is conductively connected to the second electrode. A system for making the device includes a plurality of electrodes placed outside the growth region of a furnace to produce a controlled, time-varying electric field. A controller for the system is connected to a power supply to deliver controlled voltages to the electrodes to produce the electric field. A mixture of gases is passed through the furnace with the temperature raised to cause chemical vapor deposition (CVD) of carbon on a catalyst. The sequentially time-varying electric field parameterizes a growing nanotube into a predetermined shape.

The present invention relates to a method for removing a polymeric material from a surface of a nanostructure. The method includes applying, by a scanning probe microscope, an electrical field between a probe tip of the scanning probe microscope and the nanostructure, and simultaneously scanning over the surface of the nanostructure. Thereby, bonds connecting the polymeric material to the surface of the nanostructure are broken. A further step includes cleaning the surface of the nanostructure. A scanning probe microscope for performing such a method and a computer program product for controlling the scanning probe microscope are also disclosed.

An embodiment of the present disclosure relates to an apparatus for synthesizing nanoparticles by irradiating, with an electron beam, a nanoparticle aqueous solution in a reaction vessel provided inside a shielding chamber, and more particularly, to an apparatus for synthesizing nanoparticles, which is capable of preventing radiation generated in a shielding chamber from leaking out, and facilitating maintenance and repair.

Provided is a composite metal-wide-bandgap semiconductor tip for scanning tunneling microscopy and/or scanning tunneling lithography, a method of forming, and a method for using the composite metal-wide-bandgap semiconductor tip.

The present invention relates to a method for preparing nanoparticles by using laser and more particularly, a method for preparing nanoparticles by irradiating a laser beam to the mixture of a source material gas and a hexafluoride (SF.sub.6) catalyst gas, thereby improving the production yield of nanoparticles with energy saved. More particularly, the present invention provides the method for preparing the nanoparticles by using the laser wherein the laser beam of wavelength having the excellent energy absorption by the mixture gas of source material gas and catalyst gas is irradiated to the mixture gas so as to increase the reactivity of the source material gas with energy saved, which brings the effects of solving the problems of damaging environment due to the unreacted toxic source material gas incurred by the low production yield of the conventional nanoparticle preparation method and of making system complicated with the high cost when the discarded source gas is recovered and reused.

Systems and methods of synthesizing nanoparticles on substrates using rapid, high temperature thermal shock. A method involves depositing micro-sized particles or salt precursors on a substrate, and applying a rapid, high temperature thermal pulse or shock to the micro-sized particles or the salt precursors and the substrate to cause the micro-sized particles or the salt precursors to become nanoparticles on the substrate. A system may include a rotatable member that receives a roll of a substrate sheet having micro-sized particles or salt precursors; a motor that rotates the rotatable member so as to unroll consecutive portions of the substrate sheet from the roll; and a thermal energy source that applies a short, high temperature thermal shock to consecutive portions of the substrate sheet that are unrolled from the roll by rotating the first rotatable member. Some systems and methods produce nanoparticles on existing substrate. The nanoparticles may be metallic, ceramic, inorganic, semiconductor, or compound nanoparticles. The substrate may be a carbon-based substrate, a conducting substrate, or a non-conducting substrate. The high temperature thermal shock process may be enabled by electrical Joule heating, microwave heating, thermal radiative heating, plasma heating, or laser heating.

The present invention relates to a method for removing a polymeric material from a surface of a nanostructure. The method includes applying, by a scanning probe microscope, an electrical field between a probe tip of the scanning probe microscope and the nanostructure, and simultaneously scanning over the surface of the nanostructure. Thereby, bonds connecting the polymeric material to the surface of the nanostructure are broken. A further step includes cleaning the surface of the nanostructure. A scanning probe microscope for performing such a method and a computer program product for controlling the scanning probe microscope are also disclosed.

Filter assemblies are disclosed. In particular, filter assemblies including a filter media and an overlay portion covering the filter media are disclosed. Such filter assemblies may provide both acceptable filtering capacity and cleanable visible front surfaces.

The disclosed embodiments provide a system that performs molecular assembly. During operation, the system delivers one or more droplets of a fluid onto a surface using a nanofluidic delivery probe and an associated high-precision positioning device, wherein the solution comprises a solvent and one or more solute molecules, and wherein delivery of the droplets onto the surface facilitates evaporation-driven assembly of one or more structures on the surface. Moreover, while delivering a droplet onto the surface, the system controls a size of the droplet and a shape of the droplet during evaporation to produce a variety of shapes in resulting structures.

An additive manufacturing method for fabricating 3D nanostructures, comprising: generating charged species, and controlling a first fluid field to transport the charged species; controlling a second fluid field and a first electric field to transport and screen the charged species, thereby generating charged screened particles for printing; configuring a second electric field to directionally migrate the charged screened particles, enabling them to move to preset printing sites; moving the printing sites in multiple directions to realize 3D printing, the second electric field is generated by three parallel plates connected to external electric potentials, the plates comprise a conductive upper plate connected to V1, a patterned layer connected to V2, and a substrate connected to V3; the upper plate and the patterned layer generate the first electric field, and the patterned layer is located between the upper plate and the substrate, with distances h1 and h2 respectively.