Methods of forming patterned structures suitable for a multiple patterning process are disclosed. Exemplary methods include forming a silicon nitride layer overlying the substrate by providing a silicon precursor to the reaction chamber for a silicon precursor pulse period, providing a nitrogen reactant to the reaction chamber, providing a hydrogen reactant to the reaction chamber, and providing a plasma power to form a plasma within the reaction chamber for a plasma pulse period. An etch profile of sacrificial features on the substrate can be controlled by controlling an amount of hydrogen provided to the reaction chamber and/or using other process parameters.

Methods of forming patterned structures suitable for a multiple patterning process are disclosed. Exemplary methods include forming a silicon nitride layer overlying the substrate by providing a silicon precursor to the reaction chamber for a silicon precursor pulse period, providing a nitrogen reactant to the reaction chamber, providing a hydrogen reactant to the reaction chamber, and providing a plasma power to form a plasma within the reaction chamber for a plasma pulse period. An etch profile of sacrificial features on the substrate can be controlled by controlling an amount of hydrogen provided to the reaction chamber and/or using other process parameters.

Exemplary methods of semiconductor processing may include flowing a silicon-containing precursor into a processing region of a semiconductor processing chamber. A substrate may be housed within the processing region, and the substrate may be maintained at a temperature below or about 450° C. The methods may include striking a plasma of the silicon-containing precursor. The methods may include forming a layer of amorphous silicon on a semiconductor substrate. The layer of amorphous silicon as-deposited may be characterized by less than or about 3% hydrogen incorporation.

A method for preparing a transparent sheet material comprising an organic, polymeric substrate and inorganic layers on each side of the substrate, the method comprising the steps of: a) providing an apparatus for generating a glow discharge plasma, said apparatus comprising at least two opposing electrodes, a power supply for the electrodes and a treatment space between the electrodes; b) providing the treatment space with a gas mixture at about atmospheric pressure, the gas mixture comprising a reactive gas and a precursor; and c) moving a transparent substrate through the treatment space comprising the gas mixture at an average speed of at least 1 m/min while applying an electrical potential across the electrodes, thereby generating a glow discharge plasma in the treatment space and depositing an inorganic layer on one or both sides of the substrate; wherein the electrodes apply a discharge energy to the substrate of less than 25 J/cm.sup.2.

Disclosed herein are techniques for molding a slanted structure. In some embodiments, a mold for nanoimprint lithography includes a support layer, a polymeric layer on the support layer and including a slanted structure, and an oxide layer on surfaces of the slanted structure. In some embodiments, the oxide layer is conformally deposited on the surfaces of the slanted structure by atomic layer deposition. In some embodiments, the mold further includes an anti-sticking layer on the oxide layer.

Disclosed herein are techniques for molding a slanted structure. In some embodiments, a mold for nanoimprint lithography includes a support layer, a polymeric layer on the support layer and including a slanted structure, and an oxide layer on surfaces of the slanted structure. In some embodiments, the oxide layer is conformally deposited on the surfaces of the slanted structure by atomic layer deposition. In some embodiments, the mold further includes an anti-sticking layer on the oxide layer.

Methods and systems include supplying pulsed microwave radiation through a waveguide, where the microwave radiation propagates in a direction along the waveguide. A pressure within the waveguide is at least 0.1 atmosphere. A supply gas is provided at a first location along a length of the waveguide, a majority of the supply gas flowing in the direction of the microwave radiation propagation. A plasma is generated in the supply gas, and a process gas is added into the waveguide at a second location downstream from the first location. A majority of the process gas flows in the direction of the microwave propagation at a rate greater than 5 slm. An average energy of the plasma is controlled to convert the process gas into separated components, by controlling at least one of a pulsing frequency of the pulsed microwave radiation, and a duty cycle of the pulsed microwave radiation.

A pulsed radio frequency inductive plasma source and method are provided. The source may generate plasma at gas pressures from 1 torr to 2000 torr. By utilizing high power RF generation from fast solid state switches such as Insulated-Gate Bipolar Transistor (IGBT) combined with the resonance circuit, large inductive voltages can be applied to RF antennas to allow rapid gas breakdown from 1-100 μs. After initial breakdown, the same set of switches or an additional rf pulsed power systems are utilized to deliver large amount of rf power, between 10 kW to 10 MW, to the plasmas during the pulse duration of 10 μs-10 ms. In addition, several methods and apparatus for controlling the pulse power delivery, timing gas and materials supply, constructing reactor and substrate structure, and operating pumping system and plasma activated reactive materials delivery system will be disclosed. When combined with the pulsed plasma generation, these apparatuses and the methods can greatly improve the applicability and the efficacy of the industrial plasma processing.

A pulsed radio frequency inductive plasma source and method are provided. The source may generate plasma at gas pressures from 1 torr to 2000 torr. By utilizing high power RF generation from fast solid state switches such as Insulated-Gate Bipolar Transistor (IGBT) combined with the resonance circuit, large inductive voltages can be applied to RF antennas to allow rapid gas breakdown from 1-100 μs. After initial breakdown, the same set of switches or an additional rf pulsed power systems are utilized to deliver large amount of rf power, between 10 kW to 10 MW, to the plasmas during the pulse duration of 10 μs-10 ms. In addition, several methods and apparatus for controlling the pulse power delivery, timing gas and materials supply, constructing reactor and substrate structure, and operating pumping system and plasma activated reactive materials delivery system will be disclosed. When combined with the pulsed plasma generation, these apparatuses and the methods can greatly improve the applicability and the efficacy of the industrial plasma processing.

A processing method and system are provided for processing a substrate with a plasma in the presence of an electro-negative gas. A processing gas is injected into a processing chamber. The gas includes a high electron affinity gas species. A surface is provided in the plasma chamber onto which the gas species has a tendency to chemisorb. The gas species is exposed to the surface, chemisorbed onto it, and the surface is exposed to energy that causes negative ions of the chemisorbed gas species, that interact in the plasma to release secondary electrons. A neutralizer grid may be provided to separate from the chamber a second chamber in which forms a low energy secondary plasma for processing the substrate that is dense in electrons and contains high energy neutrals of the gas species and high energy positive ions of processing gas. Pulsed energy may be used to excite plasma or bias the substrate. A hollow cathode source is also provided.