Vertical III-V Nanowire MOSFETs

Olli-Pekka Kilpi

Vertical III-V Nanowire MOSFETs

Olli-Pekka Kilpi

Nano Electronics

Research output: Thesis › Doctoral Thesis (compilation)

Abstract

Vertical III-V nanowire MOSFETs are interesting candidates for future digital and analog applications. High electron velocity III-V materials allow fabrication of low power and high frequency MOSFETs. Vertical vapor-liquid-solid growth enables fabrication of axial and radial heterostructure nanowires. This enables fabrication of novel structures where the band-gap can be engineered in the electron transport direction.

In this thesis, vertical InAs/InGaAs DC and RF MOSFETs on Si are fabricated and characterized. Several novel structures in vertical nanowire MOSFETs have been implemented such as gate-last process, axial/radial heterostructures, sub-30-nm gate-length, optimized RF design and field-plate structures. Several different nanowire compositions, such as InAs, InAs/In_0.7Ga_0.3As and InAs/In_0.4Ga_0.6As, were used. The radial heterostructureand the gate-last process enabled a record low access resistance in these devices. The axial heterostructure, on the other hand, allowed a wider band-gap material on the drain side, therefore suppressing the band-to-band tunnelling and impact ionization. This enabled a considerable improvement in the transistor off-state performance and for the first time I_off < 1 nA/µm was reported in non-planar In(Ga)As MOSFETs.

This work demonstrated several high performance devices, therefore highlighting the potential of the vertical nanowire MOSFETs. We demonstrate I_on = 407 mA/µm at I_off= 100 nA/µm and V_DD = 0.5 V, which is the highest reported I_on on vertical nanowire MOSFETs. We demonstrated g_m = 3.1 mS/µm, which is the highest demonstrated g_m on any MOSFET on Si. Further, we increased the breakdown voltage on InAs/InGaAs MOSFETs from 0.5 V to 2.5 V and demonstrated vertical nanowire MOSFETs with fT/ fmax > 100 GHz / 100 GHz.

Original language	English
Qualification	Doctor
Supervisors/Advisors	Wernersson, Lars-Erik, Supervisor Lind, Erik, Assistant supervisor Svensson, Johannes, Assistant supervisor
Publisher	Department of Electrical and Information Technology, Lund University
ISBN (Print)	978-91-7895-292-2
ISBN (electronic)	978-91-7895-293-9
Publication status	Published - 2019

Bibliographical note

Defence details
Date: 2019-10-11
Time: 09:15
Place: Lecture Hall E:1406, E-Building, Ole Römers väg 3, Lund University, Faculty of Engineering LTH
External reviewer(s)
Name: Takagi, Shinichi
Title: Professor
Affiliation: The University of Tokyo, Japan
---

Subject classification (UKÄ)

Electrical Engineering, Electronic Engineering, Information Engineering

Free keywords

Nanowire
MOSFET
III-V
InGaAs
Vertical
Heterostructure
High frequency

3 Paper in conference proceeding
2 Article
1 Letter

Electrical Properties of Vertical InAs/InGaAs Heterostructure MOSFETs
Kilpi, O. P., Svensson, J., Lind, E. & Wernersson, L. E., 2019, In: IEEE Journal of the Electron Devices Society. 7, p. 70-75
Research output: Contribution to journal › Article › peer-review

Open Access
Sub-100-nm gate-length scaling of vertical InAs/InGaAs nanowire MOSFETs on Si
Kilpi, O. P., Svensson, J. & Wernersson, L. E., 2018 Jan 23, 2017 IEEE International Electron Devices Meeting, IEDM 2017. IEEE - Institute of Electrical and Electronics Engineers Inc., Vol. Part F134366. p. 17.3.1-17.3.4
Research output: Chapter in Book/Report/Conference proceeding › Paper in conference proceeding › peer-review

File
295 Downloads (Pure)
Vertical InAs/InGaAs Heterostructure Metal-Oxide-Semiconductor Field-Effect Transistors on Si
Kilpi, O. P., Svensson, J., Wu, J., Persson, A. R., Wallenberg, R., Lind, E. & Wernersson, L. E., 2017 Oct 11, In: Nano Letters. 17, 10, p. 6006-6010 5 p.
Research output: Contribution to journal › Article › peer-review

File
193 Downloads (Pure)

Cite this

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title = "Vertical III-V Nanowire MOSFETs",

abstract = "Vertical III-V nanowire MOSFETs are interesting candidates for future digital and analog applications. High electron velocity III-V materials allow fabrication of low power and high frequency MOSFETs. Vertical vapor-liquid-solid growth enables fabrication of axial and radial heterostructure nanowires. This enables fabrication of novel structures where the band-gap can be engineered in the electron transport direction.In this thesis, vertical InAs/InGaAs DC and RF MOSFETs on Si are fabricated and characterized. Several novel structures in vertical nanowire MOSFETs have been implemented such as gate-last process, axial/radial heterostructures, sub-30-nm gate-length, optimized RF design and field-plate structures. Several different nanowire compositions, such as InAs, InAs/In0.7Ga0.3As and InAs/In0.4Ga0.6As, were used. The radial heterostructureand the gate-last process enabled a record low access resistance in these devices. The axial heterostructure, on the other hand, allowed a wider band-gap material on the drain side, therefore suppressing the band-to-band tunnelling and impact ionization. This enabled a considerable improvement in the transistor off-state performance and for the first time Ioff < 1 nA/µm was reported in non-planar In(Ga)As MOSFETs.This work demonstrated several high performance devices, therefore highlighting the potential of the vertical nanowire MOSFETs. We demonstrate Ion = 407 mA/µm at Ioff = 100 nA/µm and VDD = 0.5 V, which is the highest reported Ion on vertical nanowire MOSFETs. We demonstrated gm = 3.1 mS/µm, which is the highest demonstrated gm on any MOSFET on Si. Further, we increased the breakdown voltage on InAs/InGaAs MOSFETs from 0.5 V to 2.5 V and demonstrated vertical nanowire MOSFETs with fT/ fmax > 100 GHz / 100 GHz.",

keywords = "Nanowire, MOSFET, III-V, InGaAs, Vertical, Heterostructure, High frequency",

author = "Olli-Pekka Kilpi",

note = "Defence details Date: 2019-10-11 Time: 09:15 Place: Lecture Hall E:1406, E-Building, Ole R{\"o}mers v{\"a}g 3, Lund University, Faculty of Engineering LTH External reviewer(s) Name: Takagi, Shinichi Title: Professor Affiliation: The University of Tokyo, Japan --- ",

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language = "English",

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T1 - Vertical III-V Nanowire MOSFETs

AU - Kilpi, Olli-Pekka

N1 - Defence details Date: 2019-10-11 Time: 09:15 Place: Lecture Hall E:1406, E-Building, Ole Römers väg 3, Lund University, Faculty of Engineering LTH External reviewer(s) Name: Takagi, Shinichi Title: Professor Affiliation: The University of Tokyo, Japan ---

PY - 2019

Y1 - 2019

N2 - Vertical III-V nanowire MOSFETs are interesting candidates for future digital and analog applications. High electron velocity III-V materials allow fabrication of low power and high frequency MOSFETs. Vertical vapor-liquid-solid growth enables fabrication of axial and radial heterostructure nanowires. This enables fabrication of novel structures where the band-gap can be engineered in the electron transport direction.In this thesis, vertical InAs/InGaAs DC and RF MOSFETs on Si are fabricated and characterized. Several novel structures in vertical nanowire MOSFETs have been implemented such as gate-last process, axial/radial heterostructures, sub-30-nm gate-length, optimized RF design and field-plate structures. Several different nanowire compositions, such as InAs, InAs/In0.7Ga0.3As and InAs/In0.4Ga0.6As, were used. The radial heterostructureand the gate-last process enabled a record low access resistance in these devices. The axial heterostructure, on the other hand, allowed a wider band-gap material on the drain side, therefore suppressing the band-to-band tunnelling and impact ionization. This enabled a considerable improvement in the transistor off-state performance and for the first time Ioff < 1 nA/µm was reported in non-planar In(Ga)As MOSFETs.This work demonstrated several high performance devices, therefore highlighting the potential of the vertical nanowire MOSFETs. We demonstrate Ion = 407 mA/µm at Ioff = 100 nA/µm and VDD = 0.5 V, which is the highest reported Ion on vertical nanowire MOSFETs. We demonstrated gm = 3.1 mS/µm, which is the highest demonstrated gm on any MOSFET on Si. Further, we increased the breakdown voltage on InAs/InGaAs MOSFETs from 0.5 V to 2.5 V and demonstrated vertical nanowire MOSFETs with fT/ fmax > 100 GHz / 100 GHz.

AB - Vertical III-V nanowire MOSFETs are interesting candidates for future digital and analog applications. High electron velocity III-V materials allow fabrication of low power and high frequency MOSFETs. Vertical vapor-liquid-solid growth enables fabrication of axial and radial heterostructure nanowires. This enables fabrication of novel structures where the band-gap can be engineered in the electron transport direction.In this thesis, vertical InAs/InGaAs DC and RF MOSFETs on Si are fabricated and characterized. Several novel structures in vertical nanowire MOSFETs have been implemented such as gate-last process, axial/radial heterostructures, sub-30-nm gate-length, optimized RF design and field-plate structures. Several different nanowire compositions, such as InAs, InAs/In0.7Ga0.3As and InAs/In0.4Ga0.6As, were used. The radial heterostructureand the gate-last process enabled a record low access resistance in these devices. The axial heterostructure, on the other hand, allowed a wider band-gap material on the drain side, therefore suppressing the band-to-band tunnelling and impact ionization. This enabled a considerable improvement in the transistor off-state performance and for the first time Ioff < 1 nA/µm was reported in non-planar In(Ga)As MOSFETs.This work demonstrated several high performance devices, therefore highlighting the potential of the vertical nanowire MOSFETs. We demonstrate Ion = 407 mA/µm at Ioff = 100 nA/µm and VDD = 0.5 V, which is the highest reported Ion on vertical nanowire MOSFETs. We demonstrated gm = 3.1 mS/µm, which is the highest demonstrated gm on any MOSFET on Si. Further, we increased the breakdown voltage on InAs/InGaAs MOSFETs from 0.5 V to 2.5 V and demonstrated vertical nanowire MOSFETs with fT/ fmax > 100 GHz / 100 GHz.

KW - Nanowire

KW - MOSFET

KW - III-V

KW - InGaAs

KW - Vertical

KW - Heterostructure

KW - High frequency

M3 - Doctoral Thesis (compilation)

SN - 978-91-7895-292-2

T3 - Series of licentiate and doctoral theses

PB - Department of Electrical and Information Technology, Lund University

ER -

Vertical III-V Nanowire MOSFETs

Abstract

Bibliographical note

Subject classification (UKÄ)

Free keywords

Fingerprint

Research output

Electrical Properties of Vertical InAs/InGaAs Heterostructure MOSFETs

Sub-100-nm gate-length scaling of vertical InAs/InGaAs nanowire MOSFETs on Si

Vertical InAs/InGaAs Heterostructure Metal-Oxide-Semiconductor Field-Effect Transistors on Si

Cite this