Abstract: A plasma enhanced physical vapor deposition process deposits an amorphous carbon layer on an ion-implanted wafer for use in dynamic surface annealing of the wafer with an intense line beam of a laser wavelength. The deposition process is carried out at a wafer temperature below the dopant clustering threshold temperature, and includes introducing the wafer into a chamber having a carbon-containing target overlying the wafer, and furnishing a carrier gas into the chamber. The process further includes generating a wafer bias voltage and applying target source power to the carbon-containing target sufficient to produce ion bombardment of the carbon-containing target. The wafer bias voltage is set to a level at which the amorphous carbon layer that is deposited has a desired extinction coefficient at the laser wavelength.

Abstract: A plasma enhanced physical vapor deposition process deposits an amorphous carbon layer on an ion-implanted wafer for use in dynamic surface annealing of the wafer with an intense line beam of a laser wavelength. The deposition process is carried out at a wafer temperature below the dopant clustering threshold temperature, and includes introducing the wafer into a chamber having a carbon-containing target overlying the wafer, and furnishing a carrier gas into the chamber. The process further includes generating a wafer bias voltage and applying target source power to the carbon-containing target sufficient to produce ion bombardment of the carbon-containing target. The wafer bias voltage is set to a level at which the amorphous carbon layer that is deposited has a desired extinction coefficient at the laser wavelength.

Abstract: A plasma enhanced physical vapor deposition process deposits an amorphous carbon layer on an ion-implanted wafer for use in dynamic surface annealing of the wafer with an intense line beam of a laser wavelength. The deposition process is carried out at a wafer temperature below the dopant clustering threshold temperature, and includes introducing the wafer into a chamber having a carbon-containing target overlying the wafer, and furnishing a carrier gas into the chamber. The process further includes generating a wafer bias voltage and applying target source power to the carbon-containing target sufficient to produce ion bombardment of the carbon-containing target. The wafer bias voltage is set to a level at which the amorphous carbon layer that is deposited has a desired extinction coefficient at the laser wavelength.

Abstract: A plasma enhanced physical vapor deposition process deposits an amorphous carbon layer on an ion-implanted wafer for use in dynamic surface annealing of the wafer with an intense line beam of a laser wavelength. The deposition process is carried out at a wafer temperature below the dopant clustering threshold temperature, and includes introducing the wafer into a chamber and furnishing a hydrocarbon process gas into the chamber, preferably propylene (C3H6) or toluene (C7H8) or acetylene (C2H2) or a mixture of acetylene and methane (C2H4). The process further includes inductively coupling RF plasma source power into the chamber while and applying RF plasma bias power to the wafer. The wafer bias voltage is set to a level at which the amorphous carbon layer that is deposited has a desired stress (compressive or tensile). We have discovered that at a wafer temperature less than or equal to 475 degrees C.

Abstract: A gate hard mask is deposited on a gate structure using low pressure chemical vapor deposition (LPCVD). By doing so, the wet etch removal ratio (WERR) of the gate hard mask relative to the underlying polysilicon gate layer is increased when compared to prior art hard masks. The LPCVD gate hard mask will not only etch faster than prior art hard masks, but it will also reduce undercutting of the gate oxide. To provide additional control of the wet etch rate, the LPCVD hard mask can be annealed. The annealing can be tailored to achieve the desired etching rate.

Abstract: A plasma enhanced physical vapor deposition process deposits an amorphous carbon layer on an ion-implanted wafer for use in dynamic surface annealing of the wafer with an intense line beam of a laser wavelength. The deposition process is carried out at a wafer temperature below the dopant clustering threshold temperature, and includes introducing the wafer into a chamber having a carbon-containing target overlying the wafer, and furnishing a carrier gas into the chamber. The process further includes generating a wafer bias voltage and applying target source power to the carbon-containing target sufficient to produce ion bombardment of the carbon-containing target. The wafer bias voltage is set to a level at which the amorphous carbon layer that is deposited has a desired extinction coefficient at the laser wavelength.

Abstract: A plasma enhanced physical vapor deposition process deposits an amorphous carbon layer on an ion-implanted wafer for use in dynamic surface annealing of the wafer with an intense line beam of a laser wavelength. The deposition process is carried out at a wafer temperature below the dopant clustering threshold temperature, and includes introducing the wafer into a chamber and furnishing a hydrocarbon process gas into the chamber, preferably propylene (C3H6) or toluene (C7H8) or acetylene (C2H2) or a mixture of acetylene and methane (C2H4). The process further includes inductively coupling RF plasma source power into the chamber while and applying RF plasma bias power to the wafer. The wafer bias voltage is set to a level at which the amorphous carbon layer that is deposited has a desired stress (compressive or tensile). We have discovered that at a wafer temperature less than or equal to 475 degrees C.

Abstract: A gate hard mask is deposited on a gate structure using low pressure chemical vapor deposition (LPCVD). By doing so, the wet etch removal ratio (WERR) of the gate hard mask relative to the underlying polysilicon gate layer is increased when compared to prior art hard masks. The LPCVD gate hard mask will not only etch faster than prior art hard masks, but it will also reduce undercutting of the gate oxide. To provide additional control of the wet etch rate, the LPCVD hard mask can be annealed. The annealing can be tailored to achieve the desired etching rate.