Data from time-resolved optical emission spectroscopy (TROES) are presented from experiments on plasma modulation in a typical parallel-plate reactor used for the deposition of amorphous-silicon-based materials. The SiH(4)-H(2), GeH(4), SiF(4) and SiF(4)-H(2) systems have been investigated by varying the modulation parameters (period and duty cycle) and RF power. The mechanisms of excited species formation have been elucidated as well as their decay in the afterglow region. It has been found that SiH*, Si*, GeH* and Ge* originate from a dissociation-excitation process of the parent molecule, while SiF(x)* (x = 3,2,1) are formed by a direct excitation of the same species in the ground state. In addition, SiF(2) radicals in SiF(4)-H(2) plasmas exhibit the highest stability in the late afterglow region.
Time-resolved optical emission spectroscopy of modulated plasmas for amorphous silicon deposition
1992
Abstract
Data from time-resolved optical emission spectroscopy (TROES) are presented from experiments on plasma modulation in a typical parallel-plate reactor used for the deposition of amorphous-silicon-based materials. The SiH(4)-H(2), GeH(4), SiF(4) and SiF(4)-H(2) systems have been investigated by varying the modulation parameters (period and duty cycle) and RF power. The mechanisms of excited species formation have been elucidated as well as their decay in the afterglow region. It has been found that SiH*, Si*, GeH* and Ge* originate from a dissociation-excitation process of the parent molecule, while SiF(x)* (x = 3,2,1) are formed by a direct excitation of the same species in the ground state. In addition, SiF(2) radicals in SiF(4)-H(2) plasmas exhibit the highest stability in the late afterglow region.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
