Abstract: Engineered particles are provided may be used for the delivery of a bioactive agent to the respiratory tract of a patient. The particles may be used in the form of dry powders or in the form of stabilized dispersions comprising a nonaqueous continuous phase. In particularly preferred embodiments the particles may be used in conjunction with an inhalation device such as a dry powder inhaler, metered dose inhaler or a nebulizer.

Abstract: A thin film battery comprises a substrate with a front side and a back side. A first battery cell is provided on the front side of the substrate, the first battery cell including an electrolyte between a pair of electrodes. A second battery cell is provided on the back side of the substrate, the second battery cell also including an electrolyte between a pair of electrodes. The battery is capable of providing an energy density of more than 700 wh/l and a specific energy of more than 250 wh/kg. A method of annealing a deposited thin film is also described.

Abstract: In a method of cleaning metal-containing deposits such as tantalum from a surface of a process chamber component, such as a metal surface, the surface is immersed in a cleaning solution. In one version, the cleaning solution is a solution having HF and HNO3 in a ratio that removes deposits from the surface substantially without eroding the surface. In another version, the cleaning solution is a solution having KOH and H2O2. The solution can be treated after cleaning the surface to recover tantalum-containing materials and one or more of the cleaning solutions.

Abstract: An electron beam source has a photocathode with a photoemitter material having a work function, and with a beam receiving portion and an electron emitting portion. A first light source directs a first light beam onto the beam receiving portion of the photocathode to generate an electron beam from the electron emitting portion. The first light beam has a wavelength ?1 such that hc/?1 is at least about the work function of the photoemitter material, where ‘h’ is Planck's constant and ‘c’ is the speed of light. A second light source directs a second light beam onto the beam receiving portion of the photocathode, such as onto the beam receiving portion, to stabilize the electron beam. The second light beam having a wavelength ?2 such that hc/?2 is less than about the work function of the photoemitter material.

Abstract: A process for etching a substrate and removing etch residue deposited on the surfaces in the etching chamber has two stages. In the first stage, an energized first process gas is provided in the chamber, and in the second stage, an energized second process gas is provided in the chamber. The energized first process gas comprises SF6 and Ar, the volumetric flow ratio of SF6 to other components of the first process gas being from about 5:1 to about 1:10. The energized second process gas comprises CF4 and Ar, the volumetric flow ratio of CF4 to other components of the second process gas being from about 1:0 to about 1:10.

Abstract: In a method of etching a substrate, a substrate is provided in a process zone, the substrate having a pattern of features comprising dielectric covering semiconductor. In a first stage, an energized first etching gas is provided in the process zone, the energized first etching gas having a first selectivity of etching dielectric to semiconductor of at least about 1.8:1, wherein the dielectric is etched preferentially to the semiconductor to etch through the dielectric to at least partially expose the semiconductor. In a second stage, an energized second etching gas is provided in the process zone, the energized second etching gas having a second selectivity of etching dielectric to semiconductor of less than about 1:1.8, wherein the semiconductor is etched preferentially to the dielectric.

Abstract: A substrate processing chamber has a substrate support, a gas supply, a gas exhaust, a gas energizer, and a wall about the substrate support, the wall having a porous ceramic material at least partially infiltrated with a fluorinated polymer, whereby a substrate on the substrate support may be processed by gas introduced by the gas supply, energized by the gas energizer, and exhausted by the gas exhaust.

Abstract: A substrate processing chamber 25 comprising a substrate support 85, and a wall 24 about the substrate support 85, the wall 24 having a radiation absorbing surface 36 adapted to preferentially absorb radiation having wavelengths in the visible or infra-red spectrum.

Abstract: A chamber 25 comprises a support 45 for holding a substrate 20 and a sensor system 135 adapted to detect the presence or proper placement of the substrate 20 on the support 45. The support 45 comprises a window 155 that is transparent and adapted to transmit light therethrough. The sensor system 135 comprises a light source 140 adapted to direct a light beam 150 through the window 155 and a light sensor 160 in the path of the light beam 150. The light beam 150 is sensed by the light sensor 135 when the substrate 20 is properly positioned and the light beam 150 is blocked from the light sensor 135 when the substrate 20 is improperly positioned or vice versa. Preferably, the support 45 comprises an electrostatic chuck 55 adapted to electrostatically hold the substrate 20, the electrostatic chuck 55 comprising a window 155 composed of transparent material or a cut-out or a hole therein.

Abstract: An electrostatic chuck 55 for holding a substrate 30 comprises an electrostatic member 100 made from a dielectric 115 covering an electrode 105 that is chargeable to electrostatically hold the substrate 30. A base 175 that includes a heater 235 is joined to the electrostatic member 100. The base may be made from a composite material, such as a porous ceramic infiltrated with the metal, and may be joined to the electrostatic member by a bond layer.

Abstract: A chamber 35 for energizing a gas comprises a gas distributor 85 having an aperture 250 for introducing gas into the chamber 35 and a wall 175 comprising boron nitride. The chamber 35 further comprises a gas energizer 90 capable of passing electromagnetic energy through the wall 175 to energize the gas in the chamber 35.

Abstract: A gas feed-through 150 to provide gas to a plasma chamber 10, comprises a dielectric insert 155 having a passage 160 that allows the gas to be flowed therethrough, and a electrically conducting cup 165 around a portion of the passage. The electrically conducting cup 165 is shaped to reduce plasma formation in the gas feed-through 150.

Abstract: A process chamber 110 capable of processing a substrate 30 in a plasma of process gas. The chamber 110 comprises a support 200 having a dielectric 210 covering an electrode 220 and a conductor 230 below the electrode 220. A voltage supply 180 supplies a gas energizing voltage to the conductor 220, and the conductor is adapted to capacitively couple the voltage to the electrode 220 to energize the process gas. Alternatively, the voltage may be supplied to the electrode 220 through a connector 195 which can capacitively couple with the conductor 230. A DC power supply 190 may also provide an electrostatic chucking voltage to the electrode 220. In one version, the conductor 230 comprises an interposer 280.

Abstract: A chamber 30 for processing a substrate 25 comprises a support 55 comprising a dielectric 60 enveloping an electrode 70. The electrode 70 may be chargeable to electrostatically hold the substrate 25 or may be chargeable to form an energized gas in the chamber 30 to process the substrate 25. A base 130 is below the support 55, and a compliant member 300 is positioned between the support 55 and the base 130. The compliant member 300 may be adapted to alleviate thermal stresses arising from a thermal expansion mismatch between the dielectric 60 and the base 130.

Abstract: A substrate having a patterned mask and exposed openings is provided in a process chamber having process electrodes. In a plasma ignition stage, a process gas is provided in the process chamber and is energized by maintaining the process electrodes at a plasma ignition bias power level. In an etch-passivating stage, an etch-passivating material is formed on at least portions of the substrate by maintaining the process electrodes at an etch-passivating bias power level. In an etching stage, the exposed openings on the substrate are etched by maintaining the process electrodes at an etching bias power level.

Abstract: An electrostatic chuck for holding a substrate has an electrostatic member having a dielectric covering an electrode that is chargeable to electrostatically hold the substrate. The bond layer has a metal layer that is infiltrated or brazed between the electrostatic member and the base. The base may be a composite of a ceramic and metal, the composite having a coefficient of thermal expansion within about ±30% of a coefficient of thermal expansion of the electrostatic member. The base may also have a heater.

Abstract: A process chamber 110 capable of processing a substrate 50 in a plasma comprises a dielectric 210 covering a first electrode 220 and a second electrode 230, a conductor 250 supporting the dielectric 210, and a voltage supply 170 to supply an RF voltage to the first electrode 220 or the second electrode 230 in the dielectric 210. The first electrode 220 capacitively couples with a process electrode 225 to energize process gas in the process chamber 110 and RF voltage applied to the second electrode 230 is capacitively coupled to the conductor 250 and through a collar 260 or the second electrode 230 is directly capacitively coupled through the collar 260.

Abstract: An electrostatic chuck 55 comprises an electrical connector 140 which is connected to the electrode 105 to conduct an electrical charge to the electrode 105. The electrical connector 140 comprises a refractory metal having a melting temperature of at least about 1500° C., such as for example, tungsten, titanium, nickel, tantalum, molybdenum, or alloys thereof. Preferably, the electrical connector 140 is bonded to the electrode 105 by a metal having a softening temperature of less than about 600° C., such as aluminum, indium, or low melting point alloys.

Abstract: A process chamber 25 for processing a semiconductor substrate, comprises a support for supporting a substrate 50. A gas distributor 90 provided for introducing process gas into the chamber 25, comprises a gas nozzle for injecting process gas at an inclined angle relative to a plane of the substrate 50, into the chamber 25. Optionally, a gas flow controller 100 controls and pulses the flow of process gas through one or more gas nozzles 140. An exhaust is used to exhaust the process gas from the chamber 25.

Abstract: A substrate processing apparatus comprises a process chamber capable of processing a first material on the substrate. A radiation source is capable of emitting radiation that is reflected from the substrate during processing. A radiation detector is provided to detect the reflected radiation and generate a signal trace. A controller is adapted to receive the signal trace and evaluate an endpoint of processing the first material from a change in the signal trace that is distinctive of an exposure of a second material having a different reflectivity coefficient than the first material.