Abstract :
Aluminum (Al) and its alloy films are widely used for fabricating VLSI interconnections. The discharge behavior of a magnetically enhanced reactive ion etching (MERIE) of Al(Si) has been modeled using neural networks. A 26-1 fractional factorial experiment was employed to characterize etch variations with RF power, pressure, magnetic field and gas mixtures of Cl2, BCl3, and N2. Responses of an Al(Si) film etched in a chlorine-based plasma include etch rate, selectivity to oxide, anisotropy and bias of critical dimension (CD). The generalization accuracy of the models, measured by the root-mean squared error (RMS) on a test set, are 285 Å/min for etch rate, 5.58 for oxide selectivity, 0.08 for anisotropy, and 3.82 Å/min for CD bias. Al(Si) etch rate was found to be chlorine-dependent with significantly affected by magnetic field variations. For the other etch responses, RF power was dominant. Gas additives such as BCl3 and N2 were seen to have conflicting effects on etch outputs. Predicted Al(Si) etch behaviors from neural process models were in qualitative good agreement with reported experimental results
Keywords :
VLSI; aluminium alloys; electronic engineering computing; integrated circuit interconnections; integrated circuit metallisation; neural nets; semiconductor process modelling; sputter etching; Al alloy films; AlSi; AlSi film; BCl3; Cl2; N2; RF power variation; RIE process modelling; RMS; VLSI interconnections; anisotropy; chlorine-based plasma; critical dimension bias; discharge behavior; etch rate; fractional factorial experiment; gas additives; gas mixtures; magnetic field variation; magnetically enhanced RIE; neural networks; oxide selectivity; pressure variation; reactive ion etching; root-mean squared error; Aluminum alloys; Anisotropic magnetoresistance; Etching; Magnetic anisotropy; Magnetic field measurement; Magnetic films; Perpendicular magnetic anisotropy; Plasma measurements; Radio frequency; Very large scale integration;
