Abstract: Methods of depositing boron and carbon containing films are provided. In some embodiments, methods of depositing B, C films with desirable properties, such as conformality and etch rate, are provided. One or more boron and/or carbon containing precursors can be decomposed on a substrate at a temperature of less than about 400° C. One or more of the boron and carbon containing films can have a thickness of less than about 30 angstroms. Methods of doping a semiconductor substrate are provided. Doping a semiconductor substrate can include depositing a boron and carbon film over the semiconductor substrate by exposing the substrate to a vapor phase boron precursor at a process temperature of about 300° C. to about 450° C., where the boron precursor includes boron, carbon and hydrogen, and annealing the boron and carbon film at a temperature of about 800° C. to about 1200° C.

Abstract: In some embodiments, a system is disclosed for delivering hydrogen peroxide to a semiconductor processing chamber. The system includes a process canister for holding a H2O2/H2O mixture in a liquid state, an evaporator provided with an evaporator heater, a first feed line for feeding the liquid H2O2/H2O mixture to the evaporator, and a second feed line for feeding the evaporated H2O2/H2O mixture to the processing chamber, the second feed line provided with a second feed line heater. The evaporator heater is configured to heat the evaporator to a temperature lower than 120° C. and the second feed line heater is configured to heat the feed line to a temperature equal to or higher than the temperature of the evaporator.

Abstract: A process for depositing aluminum nitride is disclosed. The process comprises providing a plurality of semiconductor substrates in a batch process chamber and depositing an aluminum nitride layer on the substrates by performing a plurality of deposition cycles without exposing the substrates to plasma during the deposition cycles. Each deposition cycle comprises flowing an aluminum precursor pulse into the batch process chamber, removing the aluminum precursor from the batch process chamber, and removing the nitrogen precursor from the batch process chamber after flowing the nitrogen precursor and before flowing another pulse of the aluminum precursor. The process chamber may be a hot wall process chamber and the deposition may occur at a deposition pressure of less than 1 Torr.

Abstract: Method of depositing a film having a substantially uniform thickness by means of chemical vapor deposition, comprising: providing a reaction chamber; providing a substrate in said reaction chamber; subjecting the substrate to a series of deposition cycles, wherein each deposition cycle includes the steps of: (a) during a first time interval, supplying a first reactant to the reaction chamber; (b) during a second time interval, supplying a second reactant to the reaction chamber; and (c) during a third time interval, supplying neither the first nor the second reactant to the reaction chamber; wherein a start of the second time interval lies within the first time interval, such that a pre-exposure interval exists between a start of the first time interval and the start of the second time interval, during which pre-exposure interval the first reactant is supplied to the reaction chamber while the second reactant is not.

Abstract: Method of depositing a film having a substantially uniform thickness by means of chemical vapor deposition, comprising: providing a reaction chamber; providing a substrate in said reaction chamber; subjecting the substrate to a series of deposition cycles, wherein each deposition cycle includes the steps of: (a) during a first time interval, supplying a first reactant to the reaction chamber; (b) during a second time interval, supplying a second reactant to the reaction chamber; and (c) during a third time interval, supplying neither the first nor the second reactant to the reaction chamber; wherein a start of the second time interval lies within the first time interval, such that a pre-exposure interval exists between a start of the first time interval and the start of the second time interval, during which pre-exposure interval the first reactant is supplied to the reaction chamber while the second reactant is not.

Abstract: A method is disclosed depositing multiple layers of different materials in a sequential process within a deposition chamber. A substrate is provided in a deposition chamber. A plurality of cycles of a first atomic layer deposition (ALD) process is sequentially conducted to deposit a layer of a first material on the substrate in the deposition chamber. These first cycles include pulsing a cyclopentadienyl metal precursor. A plurality of cycles of a second ALD process is sequentially conducted to deposit a layer of a second material on the layer of the first material in the deposition chamber. The second material comprises a metal different from the metal in the cyclopentadienyl metal precursor.