The etching of sub-100-nm porous dielectric trenches has been investigated using an organic mask. The etching process that is performed in an oxide etcher is composed of three steps: a thin dielectric antireflective coating (DARC) layer (silicon containing layer) is etched in the first step, the organic mask [carbon-based layer (CL)] is opened in the second step, and the dielectric layer is etched in the last step. The DARC layer is open in a fluorocarbon-based plasma (CF4/Ar/CH2F2) and the main critical dimension issue is the critical dimension control of the trench, which can be adjusted by controlling the amount of polymer generated by the etching chemistry (% of CH2F2). The CL is etched using NH3 based plasmas, leading to straight trench profiles. For dielectric patterning, the etch process results from a delicate trade-off between passivation layer thickness and mask faceting. This is driven by the polymerizing rate of the plasma (% of CH2F2) which controls the trench width. Using an optimized etching process (CF4/Ar/2%CH2F2), p-SiOCH trenches can be patterned with straight etch profiles down to 75 nm trench width. In this article, the authors have also compared the organic mask and TiN metal hard mask strategies in terms of patterning performances (profile control, porous SiOCH modification, and reactor wall cleaning processes).