Suppression Of Short Channel Effects In Ferroelectric Si Junctionless Transistors With A Sub-10 Nm Gate Length Defined By Helium Ion Beam Lithography

The performance enhancements of Si junctionless transistors (JLTs) with a short gate length (L-G) below 10 nm by a pronounced ferroelectric (FE) gate dielectric were demonstrated for the first time. A TiN gate with L-G = similar to 8 nm was defined by helium ion beam lithography (HIBL) using hydrogen silsesquioxane as a resist. As compared with the paraelectric HfO2 gate oxide, the FE Hf0.5Zr0.5O2 gate dielectric leads to a suppression of the off-state current (I-OFF) by similar to 2 orders of magnitude and a reduction of the minimum subthreshold swing (SS) to (similar to)33 mV dec(-1), along with an enhancement of the on/off ratio in the reverse-sweep direction in JLTs with L-G = similar to 8 nm. JLTs with a long L-G = 5 mu m were also investigated for comparison, revealing a decrease of I-OFF by similar to 25x and the sub-60 mV dec(-1) SS across similar to 3 orders of drain current (I-D) under a large drain voltage (V-D = 0.5 V) operation during the reverse sweep in FE JLTs. A time domain analysis indicated that the transient negative capacitance (TNC) effect takes place in the FE gate dielectric. A physical model was proposed to account for the TNC effect and the sub-60 mV dec(-1) SS based on the capacitance increase during the FE polarization switching. This study also demonstrates for the first time the fabrication of nanoelectronic devices with a sub-10 nm critical dimension by using the HIBL technique with a damage-free dose.