Jun 28, 2021

Program 2021: Symposium on Schottky Barrier MOS Devices

The symposium goal is to combine the activities of an enthusiastic group of Schottky barrier researchers worldwide. The topics cover all important aspects of potential applications, simulation and modeling, processing and implementation for CMOS/SOI technologies, Quantum technologies and approaches for neuromorphic applications. The content will be beneficial for anyone who needs to learn the opportunities and challenges of this technology since the first introduction by Walter Schottky in the 1938s. New aspects and future proposals to make the Schottky barrier into the main stream are welcome.

Wed 30.06.2021 (Virtual)
13:00-13:05  
Opening IEEE DL
13:05-14:00














IEEE Distinguished Lecture: Tunneling Graphene FET
Gana Nath Dash, Sambalpur University (IN)
Abstract: During the last few decades, aggressive scaling in Si MOSFET
(Metal Oxide Semiconductor Field Effect Transistor) architecture has
given rise to several short channel effects, which in turn has set a performance
limit on the device owing to constraint in Si technology. The emergence of
graphene at this juncture with a host of exotic and favorable electronic
properties, generated new hopes for the FET industry. While the graphene
based analogue FET witnessed some advantages, the digital counterpart
showed a dismal performance, primarily due to the zero bandgap of graphene
(poor ON/OFF ratio). For a way out, an alternative architecture based on the
quantum tunneling process is augmented with the graphene FET resulting
in the new device named TGFET.

14:00-14:05  
Opening SSBMOS
14:05-14:35   


















Germanium nanosheet and nanowire transistor technologies for beyond
CMOS applications

Walter M. Weber, Raphael Böckle, Lukas Wind, Kilian Eysin, Daniele Nazzari,
Tatli Ezgi, Oliver Solfronk, Alois Lugstein and Masiar Sistani,
Institute of Solid State Electronics, TU Vienna (A)
Abstract: The ultimate downscaling limits of conventional field effect transistors
calls for alternative computational methods that provide perspectives towards the
enhancement of computational complexity, circuit performance and energy
efficiency. In this sense germanium nano-transistors offer both an approachable
access to quantum confinement effects and promising electronic transport properties
that distinctly are compatible with modern CMOS fabrication flows. We will discuss
the applicability of different germanium active regions and gating architectures
towards the realization of computational electronics with added functionality.
On top of exploring different realizations of reconfigurable transistors with
programmable polarity we will discuss further functionality enhancement by
enabling operability within the negative differential resistance regime at room
temperature. Prospective implications at the circuit level will be discussed.
14:40-15:10





  
Evolving contact-controlled thin-film transistors
Radu Sporea, University of Surrey (UK)

Abstract: TFT designs that comprise multiple gates and rectifying source contacts
can be designed to produce linear transconductance and act as robust amplifiers
and signal converters. This talk outlines device design and opportunities in
emerging edge processing applications.
15:10-15:50   COFFEE BREAK
15:50-16:20













  
Compact Modelling of Dually-Gated Reconfigurable Field-Effect Transistors
Christian Römer*, Ghader Darbandy*, Mike Schwarz*, Jens Trommer**,
André Heinzig**, Thomas Mikolajick**, Walter M. Weber***, Benjamín
Iñíguez**** and Alexander Kloes*
*NanoP, THM (DE), **namLAB, TU Dresden (DE),
***TU Vienna (A), ****DEEEA, URV (ES)

Abstract: This work presents a closed-form and physics-based DC compact model,
which is applicable on dually-gated reconfigurable field-effect transistors (RFETs).
The presented compact model is focused on the charge-carrier injection at the
device’s source and drain side Schottky barriers, which can be separated into field
emission and thermionic emission current contributions. This work explains the basic
equations which are used to calculate the current contributions and shows calculated
device characteristics compared to measurements.

16:25-16:55









  
The Schottky barrier transistor in all its forms
Laurie Calvet*, John P. Snyder**, Mike Schwarz***
*C2N, University Paris (FR),** JCap, LLC (USA), ***NanoP, THM (DE)

Abstract: The Schottky barrier (SB) transistor, where the source and drain of a
conventional planar MOSFET are replaced with metallic contacts, was first
explored in the 1960s. Since then, many variations on this structure have been
explored in the literature including: different semiconductors materials such as
other non-organic semiconductors and nano-structures such as carbon nanotubes
and nanowires. In this talk we review some of the changes in the electronic transport
that are observed as the geometry and materials of the SB transistors are changed.

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