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 disclosure pertains to a capacitively coupled plasma source in which VHF power is applied through an impedance-matching coaxial resonator having a symmetrical power distribution.

Methods and process chambers for etching of low-k and other dielectric films are described. For example, a method includes modifying portions of the low-k dielectric layer with a plasma process. The modified portions of the low-k dielectric layer are etched selectively over a mask layer and unmodified portions of the low-k dielectric layer. Etch chambers having multiple chamber regions for alternately generating distinct plasmas are described. In embodiments, a first charge coupled plasma source is provided to generate an ion flux to a workpiece in one operational mode, while a secondary plasma source is provided to provide reactive species flux without significant ion flux to the workpiece in another operational mode. A controller operates to cycle the operational modes repeatedly over time to remove a desired cumulative amount of the dielectric material.

A method of producing a plasma is provided. The method includes providing at least three hollow cathodes, including a first hollow cathode, a second hollow cathode, and a third hollow cathode. Each hollow cathode has a plasma exit region. The method further includes providing a source of power capable of producing multiple output waves, including a first output wave, a second output wave, and a third output wave. The first output wave and the second output wave are out of phase, the second output wave and the third output wave are out of phase, and the first output wave and the third output wave are out of phase. Each hollow cathode is electrically connected to the source of power such that the first hollow cathode is electrically connected to the first output wave, the second hollow cathode is electrically connected to the second output wave, and the third hollow cathode is electrically connected to the third output wave. Electrical current flows between the at least three hollow cathodes that are out of electrical phase. A plasma is generated between the hollow cathodes.

Methods and process chambers for etching of low-k and other dielectric films are described. For example, a method includes modifying portions of the low-k dielectric layer with a plasma process. The modified portions of the low-k dielectric layer are etched selectively over a mask layer and unmodified portions of the low-k dielectric layer. Etch chambers having multiple chamber regions for alternately generating distinct plasmas are described. In embodiments, a first charge coupled plasma source is provided to generate an ion flux to a workpiece in one operational mode, while a secondary plasma source is provided to provide reactive species flux without significant ion flux to the workpiece in another operational mode. A controller operates to cycle the operational modes repeatedly over time to remove a desired cumulative amount of the dielectric material.

A method of producing a plasma is provided. The method includes providing at least three hollow cathodes, including a first hollow cathode, a second hollow cathode, and a third hollow cathode. Each hollow cathode has a plasma exit region. The method further includes providing a source of power capable of producing multiple output waves, including a first output wave, a second output wave, and a third output wave. The first output wave and the second output wave are out of phase, the second output wave and the third output wave are out of phase, and the first output wave and the third output wave are out of phase. Each hollow cathode is electrically connected to the source of power such that the first hollow cathode is electrically connected to the first output wave, the second hollow cathode is electrically connected to the second output wave, and the third hollow cathode is electrically connected to the third output wave. Electrical current flows between the at least three hollow cathodes that are out of electrical phase. A plasma is generated between the hollow cathodes.

A vacuum layer deposition apparatus includes a vacuum coating chamber with an inner space; a material source to generate electrically positively charged particles of a material to be deposited on a substrate in said inner space; a substrate holder with an extended metal or dielectric material surface exposed to said inner space; and a Rf plasma source comprising: first and second electrodes Rf-connectable or Rf-connected to first and second taps of a Rf generator, respectively. Said first and second electrodes include first and second electrode surfaces, respectively, of metal or of a dielectric material which are freely exposed to said inner space. Said extended surface of said substrate holder is at least a part of said first electrode surface and said second electrode surface is larger than said first electrode surface by at least a factor of 1.5. A method includes vacuum-process depositing a layer on a substrate.