93 results about "Negatively charged particle" patented technology

The present invention is concerned with a device for charged particle transportation and manipulation. Embodiments provide a capability of combining positively and negatively charged particles in a single transported packet. Embodiments contain an aggregate of electrodes arranged to form a channel for transportation of charged particles, as well as a source of power supply that provides supply voltage to be applied to the electrodes, the voltage to ensure creation, inside the said channel, of a non-uniform high-frequency electric field, the pseudopotential of which field has one or more local extrema along the length of the channel used for charged particle transportation, at least, within a certain interval of time, whereas, at least one of the said extrema of the pseudopotential is transposed with time, at least within a certain interval of time, at least within a part of the length of the channel used for charged particle transportation.

A novel method and mass spectrometer apparatus is introduced to enable the simultaneous isolation of cations and anions (i.e., precursor and reagent ions) in a linear multipole ion trap via the application of an additional axial DC gradient in combination with coupled RF potential(s). Thus, the combination of the RF and DC voltages in such an arrangement forms a pseudopotential designed to provide for minima for the trapped positively and negatively charged particles that result in the overlap of the ion clouds so as to provide for beneficial ion / ion reactions.

An electrophoretic display device including a first substrate, a second substrate, an electrophoretic material interposed between the first substrate and the second substrate, the electrophoretic material including a positively charged particle and a negatively charged particle, a common electrode provided on the second substrate, a pixel provided at an intersection of a signal line and a scan line, the pixel provided in a plural number and arranged in matrix on the first substrate. The electrophoretic display device further including a pixel electrode provided in the pixel, a capacitor line provided in the pixel, a storage capacitor provided in the pixel, and a second electrode of the storage capacitor being coupled to a storage capacitor line and a thin film transistor (TFT) provided in the pixel, a source electrode of the TFT being coupled to a first electrode of the storage capacitor and the pixel electrode, a drain electrode of the TFT being coupled to the signal line, and a gate electrode of the TFT being coupled to the scan line. A capacitor line low select signal VSL or a capacitor line non-select signal VSC having a higher electric potential than an electric potential of the capacitor line low select signal VSL is supplied to the storage capacitor line.

A method and system for supplying an ultra-pure fluid to a substrate process chamber using point-of-use filtration and purification. The method and system provide ability to automatically monitor and control contamination levels in fluids in real time and to stop substrate processing when contamination levels exceed predetermined thresholds. In one aspect, the invention is a system comprising: a fluid supply line adapted to supply a fluid to the process chamber; filtration means operably coupled to the fluid supply line for removing positively and negatively charged particles from the fluid prior to the fluid passing into the process chamber; a purifier operably coupled to the fluid supply line in series with the filtration means for removing ionic contaminants from the fluid prior to the fluid passing into the process chamber; sensor means for repetitively measuring particle and ionic impurity levels in the fluid that has passed through the filtration means and the purifier, the sensor means producing signals indicative of the measured particle and ionic impurity levels; a controller electrically coupled to the sensor means for receiving the signals created by the sensor means, the controller adapted to respectively compare the measured particle level and the measured ionic impurity level indicated by the signals to a predetermined particle threshold and a predetermined ionic impurity threshold, wherein upon the controller determining that either the measured particle level is above the predetermined particle threshold and / or that the measured ionic impurity level is above the predetermined ionic impurity threshold, the controller further adapted to (1) activate means to alert a user, (2) cease processing of substrates in the process chamber, and / or (3) prohibit processing of substrates in the process chamber.

A device is disclosed for providing an inductively coupled radio frequency plasma flood gun. In one particular exemplary embodiment, the device is a plasma flood gun in an ion implantation system. The plasma flood gun may comprise a plasma chamber having one or more apertures; a gas source capable of supplying at least one gaseous substance to the plasma chamber; a single-turn coil disposed within the plasma chamber, and a power source coupled to the coil for inductively coupling radio frequency electrical power to excite the at least one gaseous substance in the plasma chamber to generate a plasma. The inner surface of the plasma chamber may be free of metal-containing material and the plasma may not be exposed to any metal-containing component within the plasma chamber. The plasma chamber may include a plurality of magnets for controlling the plasma. An exit aperture may be provided in the plasma chamber to enable negatively charged particles of the resulting plasma to engage an ion beam that is part of the associated ion implantation system. In one embodiment, magnets are disposed on opposite sides of the aperture and are used to manipulate the electrons of the plasma.

The present invention relates to a stripping member for stripping electrons off a negatively charged particle beam at the periphery of a cyclotron for extracting a particle beam out of said cyclotron, said stripping member comprising a first stripper foil adapted for being located at the periphery of said cyclotron so that said particle beam passes through said first stripper foil, characterized in that it comprises a second stripper foil adapted for being located side-by-side with the first foil at the periphery of said cyclotron at a more peripheral radius than said first stripper foil so that said negatively charged particle beam passes through said second stripper foil when said first stripper foil is damaged.

An apparatus for the generation of anionic and neutral particulate beams is described. The apparatus comprises a duct defined by walls having an inner surface capable of sustaining a temperature above an electron emission temperature of the surface, so as to negatively charge electrically neutral particles being passed through the duct when the surface is heated to the temperature; a heating element for heating the inner surface to the temperature; and an acceleration electrode for ion-optically controlling and manipulating the negatively charged particles into the anion beam. The apparatus may further comprise a protection electrode defining a protected region, which substantially prevent emitted electrons from escaping the protected region. Moreover, a system for analyzing substances ejected from a surface of a sample bombarded with an anion beam generated by the apparatus is described. The system further comprises a detector for detecting the substances once ejected of the surface. Further, a method of generating an anion beam is described.

An air filtration device for suppressing biological pollutants for closed environments, including at least one enclosure with at least one air inlet, at which at least one perforated conducting grille is located, that has a present negative electrical potential adapted to emit electrons when air flows, so as to give negative electric charge to particles to which microorganisms adhere, at least one air passage duct being formed between at least one plate having predefined positive potential for collecting negatively charged particles to which microorganisms adhere, at least one deflector plate having a negative potential adapted to divert the particles to which microorganisms adhere, an electrical field being generated between the collector plate and the deflector plate, facing each other, the field to divert and precipitate the particles to which the microorganism adhere onto the collector plate, and an inactivator for inactivation of the microorganisms provided and at least one filtered air outlet.

A display apparatus includes a first substrate provided with a plurality of closed containers, a fluid filled in the closed containers, a plurality of positively charged particles which have a relative dielectric constant different from the fluid and are dispersed and held in the fluid, a plurality of negatively charged particles which have a same color as the positively charged particles and a relative dielectric constant different from the fluid and are dispersed and held in the fluid, and a pair of electrodes for generating an electric field in the closed containers. The display apparatus displays an image formed by a positional distribution of positively and negatively charged particles in each of the closed containers.

An electrophoretic display panel includes a first substrate, a second substrate, a partition wall, first electrodes, a second electrode, a dispersant, positively-charged particles, negatively-charged particles, weakly-charged particles, switching thin film transistors, scanning lines, and signal lines. Pixel spaces are surrounded by the partition wall, the first substrate and the second substrate. Two of the first electrodes are formed on the first substrate in each pixel. The second electrode facing the first electrodes is formed on the second substrate. The dispersant with the positively-charged particles, the negatively-charged particles, and weakly-charged particles is contained in the pixel spaces. The switching thin film transistors are connected to the first electrode, and the signal line. The scanning lines supply scanning signals to gate electrodes of the switching thin film transistors. The signal lines input a data signal to the switching thin film transistors.

An apparatus for the generation of anionic and neutral particulate beams is described. The apparatus comprises a duct defined by walls having an inner surface capable of sustaining a temperature above an electron emission temperature of the surface, so as to negatively charge electrically neutral particles being passed through the duct when the surface is heated to the temperature; a heating element for heating the inner surface to the temperature; and an acceleration electrode for ion-optically controlling and manipulating the negatively charged particles into the anion beam. The apparatus may further comprise a protection electrode defining a protected region, which substantially prevent emitted electrons from escaping the protected region. Moreover, a system for analyzing substances ejected from a surface of a sample bombarded with an anion beam generated by the apparatus is described. The system further comprises a detector for detecting the substances once ejected of the surface. Further, a method of generating an anion beam is described.