Directly patternable high refractive index ferroelectric sol–gel resist

highlights � A new formula directly patternable PZT high refractive index resist is presented. � The gel is sensitive to both UV and electron beam exposure. � The refractive index can vary from 1.68 up to 2.33 (@400 nm). � Direct nanopatterning by means of Focused Ion Beam (FIB) lithography was verified. � High aspect ratio hollow nanostructures will be presented. article abstract The development of a ferroelectric negative tone solegel resist for Ultraviolet (UV) and Electron Beam (EB) lithography is presented. A new system based on Lead Zirconate Titanate (PZT, with formula PbZr0.52Ti0.48O3) was synthesized by solegel method. The lithographic performances were investigated and several structures spanning from the micron range down to less than 50 nm have been achieved by UV and EB lithography. The system interaction with UV light and Electron beam was thoroughly char- acterized by FT-IT spectroscopy. The exposed PZT was annealed at high temperatures in order to study the crystalline phase evolution, the optical constants values and stability of patterned structures. After exposure and annealing, the refractive index of the material can vary from 1.68 up to 2.33 (@400 nm), while the ferroelectric behaviour seems to be maintained after high temperature annealing. These results suggest a possible application of PZT resist not only as ferroelectric but also as nanopatternable high refractive index material. Moreover, direct nanopatterning by means of Focused Ion Beam (FIB) lithog- raphy was verified and the potentiality for the preparation of high aspect ratio hollow nanostructures will be presented.

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