Aurélien Tavernier scite author profile

At the 28 nm technology node, the conventional Shallow Trench Isolation (STI) gap-fill process shows some filling limitations due to voids formation in the oxide layer (SiO 2 ), leading to electrical isolation trouble. In this paper, a new gap-fill strategy called L-E-G (for Liner -Etch-back -Gap-fill) is presented. This strategy is based on an innovative etch-back step, using downstream plasma, which allows liner profile reshaping and improves the slope in trenches. First, the etch-back process on blanket wafers is studied. A slowdown phenomenon of the etch rate with plasma exposure time is observed. Then, the relation between plasma conditions and liner profile reshaping is established. Finally, the L-E-G strategy is applied on 28 nm technology wafers. Successful STI void-free is obtained.

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First Demonstration of Low Temperature (≤500°C) CMOS Devices Featuring Functional RO and SRAM Bitcells toward 3D VLSI Integration

Fenouillet-Béranger

Brunet

Batude

et al. 2020

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Role of SiCl4 addition in CH3F/O2 based chemistry for Si3N4 etching selectively to SiO2, SiCO, and Si

Boulard

Bacquié

Tavernier

et al. 2023

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Dry etching of amorphous silicon nitride (Si3N4) selectively toward silicon dioxide (SiO2), silicon oxicarbide (SiCO), and crystalline silicon (c-Si) in an inductive coupled plasma reactor using CHF3/O2/He chemistry with SiCl4 addition is studied. Plasma exposure of c-Si, SiO2, and SiCO leads to an oxifluoride deposition. The deposition rate is the same for all these materials and increases linearly with the amount of SiCl4 added. On the other hand, Si3N4 etching is observed at very small amount of SiCl4 added (2 SCCM), while oxide deposition takes place at higher SiCl4 flow (10 SCCM). Quasi- in situ angle resolved x-ray photoelectron spectroscopy investigation shows oxifluoride SiOxFy deposition on c-Si and SiCO, while a thin F-rich reactive layer is observed on Si3N4. The oxidation of the Si3N4 surface with O2 plasma prior to CHF3/O2/He with small SiCl4 addition plasma treatment showed that the oxidation state plays a significant role in the etching/deposition equilibrium. In addition, it is found that oxifluoride deposition on Si3N4 is driven by ion energy, with deposition observed at 0 V substrate bias voltage, while etching is observed for values higher than 150 V. All these results show that a competition takes place between silicon oxifluoride deposition and etching, depending on the substrate material, surface oxidation, and ion energy. Based on the additional optical emission spectroscopy data, we proposed insights to explain the different etching and deposition behaviors observed. It is focused on the crucial role of ion energy and the nitrogen presence in Si3N4 leading to the formation of CN and HCN, helping to get a thinner reactive layer and to evacuate etch by-products on Si3N4 while an oxifluoride buildup on the other materials takes place.

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