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SIMULATION AND CHARACTERIZATION OF SILICON NANOWIRE TRI-GATE

TRANSISTOR WITH HIGH-k INSULATOR

NONA BT RIDWAN

UNIVERSITI TEKNOLOGI MALAYSIA

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―I hereby declare that I have read this thesis and in my opinion this thesis is

sufficient in terms of scope and quality for the award of the degree of Bachelor of

Engineering Electrical (Electronics).‖

Signature : ……………………………..

Supervisor : Prof. Dr. Razali Ismail

Date : 21th

June 2013

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SIMULATION AND CHARACTERIZATION OF SILICON NANOWIRE TRI-GATE

TRANSISTOR WITH HIGH-k INSULATOR

NONA BT RIDWAN

A thesis submitted in fulfilment of the

requirements for the award of degree

Bachelor of Engineering Electrical (Electronics)

Faculty of Electrical Engineering

Universiti Teknologi Malaysia

JUNE 2013

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I declare that this thesis entitled ―Simulation and Characterization of Silicon Nanowire

Tri-gate Transistor with High-k Insulator‖ is the result of my own research except as

cited in the references. The thesis has not been accepted for any degree and is not

concurrently submitted in candidature of any other degree.

Signature : ………………………………

Name : Nona bt Ridwan

Date : 21th

June 2013

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Dedicated to my beloved family,

siblings and all my friends for their

love and sacrifice.

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ACKNOWLEDGEMENT

First and foremost, I thank God for everything that has made this dissertation

possible.

I would like to sincerely thank my supervisor, Prof. Dr. Razali Bin Ismail for his

enormous support and encouragement. Without his vision, technical guidance, patience,

and willingness to let me pursue this work, this thesis would not have been possible.

I wish to express my deepest gratitude to my mentor, Fatimah binti Abdul Hamid

for all help and support. Without her guidance and knowledge, I may not manage to

complete this thesis on time. Also, special thanks to my friends, Maisara binti Yasak and

others for their friendship, help and support.

I would like to thank Yayasan Tuanku Abdul Rahman Sarawak, for financial

support of my study.

Finally, I am grateful to my mother, father, and sisters for their encouragement,

support and love.

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ABSTRACT

Multigate such as double gate, tri-gate, surrounding gate and FinFET has been

studied rigorously as a potential structure to replace metal-oxide-semiconductor field-

effect transistor (MOSFET). This paper reports the performance between silicon

nanowire tri-gate (SNWT), a semi-cylindrical channel shaped with tri-gate structure and

square shaped tri-gate. However, highlighted part on the report is performance of SNWT

with high-k insulator layer is compared with SNWT with oxide layer. The SNWTT is

modeled based on ideal silicon nanowire structure model; Gate-All-Around (GAA).

First, by using Sentaurus TCAD tool, three-dimensional (3D) geometrical structure is

developed with channel length of 65nm as the validation. Then, the algorithm from

validated model is edited according to required specifications such as channel length,

radius, and dielectric layer deposition. As the length of channel goes beyond 65nm for

tri-gate structure, the electrostatic potential surfaced at corner of channel (corner effect)

is increasing. The performance of the circuit is affected due to channel shape of

transistor. Hence, the corner effect can be reduced by replacing square shaped channel to

semi-cylindrical shape (SNWT). Following that, (I-V) characteristics for tri-gate

transistor, SNWTT, SNWTT with high-k (HfO2) layer and SNWTT with oxide layer are

extracted from simulated model and explored. I-V curves for all performance are

plotted using MATLAB for comparison purpose in terms of leakage current, drive

current, DIBL and on-off ratio. In optimization of device performance, parameters such

as channel length, temperature, radius, and doping concentration are varied and studied.

It was found that modeled SNWTT has minimum leakage current, maximum drive

current and lower DIBL compared to reported silicon nanowire tri-gate MOSFET.

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ABSTRAK

Multigate seperti dua planar, tiga planar, planar penuh dan FinFET telah dikaji

secara berterusan sebagai struktur yang berpotensi untuk menggantikan (MOSFET).

Kajian ini melaporkan prestasi antara silikon nanowire tiga planar (SNWT), saluran

berbentuk separa silinder dengan struktur tiga planar dan tiga planar berbentuk empat

segi. Walau bagaimanapun, bahagian utama pada laporan itu adalah prestasi SNWT

dengan lapisan penebat tinggi k dibandingkan dengan SNWT dengan lapisan oksida.

SNWTT ini dimodelkan berdasarkan ideal silikon nanowire model struktur; Gate-All-

Around (GAA). Pertama, dengan menggunakan Sentaurus TCAD alat, tiga dimensi (3D)

struktur geometri dibangunkan dengan panjang saluran 65nm sebagai permulaan.

Kemudian, algoritma daripada model disahkan dan diolah mengikut spesifikasi yang

diperlukan. Apabila panjang saluran dikurangkan dari 65nm untuk struktur tiga planar,

potensi elektrostatik muncul di sudut saluran (kesan sudut) semakin meningkat. Prestasi

litar terjejas kerana bentuk saluran transistor. Oleh itu, kesan sudut boleh dikurangkan

dengan menggantikan saluran berbentuk segi empat dengan bentuk semi-silinder

(SNWT). Berikutan itu, (I-V) ciri-ciri bagi transistor tiga planar, SNWTT, SNWTT

dengan high- k (HfO2) lapisan dan SNWTT dengan lapisan oksida yang diekstrak

daripada model simulasi dan diterokai. I-V graf untuk semua prestasi diplot

menggunakan MATLAB untuk tujuan perbandingan dari segi arus kebocoran, memandu

semasa, DIBL dan nisbah di-off. Dalam mengoptimumkan prestasi peranti, parameter

seperti panjang saluran, suhu, radius, kelikatan doping yang berbeza dikaji. Hasilnya,

SNWTT model mempunyai kebocoran minimum,pemacu electik maksimum dan semasa

DIBL lebih rendah berbanding silicon nanowire tiga planar MOSFET yang dilaporkan.

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TABLE OF CONTENTS

CHAPTER TITLE PAGE

DECLARATION ii

DEDICATION iii

ACKNOWLEDGEMENT iv

ABSTRACT iv

ABSTRAK vi

TABLE OF CONTENTS vii

LIST OF TABLES x

LIST OF FIGURES xi

LIST OF ABBREVIATIONS xiii

LIST OF SYMBOLS xiv

LIST OF APPENDICES xv

1 INTRODUCTION

1.1 Research Background 1

1.2 Problem Statements 5

1.3 Research Objectives 6

1.4 Research Scopes 7

1.5 Thesis Outline 7

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2 LITERATURE REVIEW

2.1 Introduction 9

2.2 MOSFET Scaling 10

2.3 MOSFET Scaling Issues 10

2.3.1 Higher Subthreshold Conduction 11

2.3.2 Increased Gate Oxide Leakage 11

2.3.3 Increased Junction Leakage 12

2.3.4 Short Channel Effect 13

2.3.5 Channel Length Modulation 13

2.4 Alternatives and Potential Solutions to Overcome

Scaling Issues

15

2.5 Silicon Nanowire 16

2.5.1 Silicon Nanowire Structure 16

2.5.2 Silicon Nanowire Electrical Properties 18

2.5.3 Fabrication Process of Silicon Nanowire 19

2.5.4 Relationship between Current and Voltage

of Silicon Nanowire Transistor

20

2.6 Tri-gate MOSFETs 22

2.6.1 Tri-gate Structure 22

2.6.2 Corner Effect in Tri-gate Structure 24

2.7 High-k Dielectric 26

2.8 Summary 27

3 RESEARCH METHODOLOGY

3.1 Introduction 29

3.2 Research Activities 29

3.3 Modeling Approach 30

3.3.1 MATLAB 31

3.3.2 Sentaurus TCAD 32

3.4 The SNWTT Modeling 33

3.4.1 Fermi Dirac Distributions 33

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xi

3.4.2 Analytical Model for Silicon Nanowire

Transistor

34

3.4.3 SNWTT Modeling Overview 36

3.5 A Development of Silicon Nanowire Tri-gate 40

3.6 Summary 43

4 CHARACTERIZATION OF SILICON NANOWIRE

TRI-GATE

4.1 Introduction 44

4.2 Silicon Nanowire Tri-gate Structure 45

4.3 Flowchart of Device Fabrication for Silicon

Nanowire Tri-gate Transistor

47

4.4 Result and Discussion 48

4.4.1 Tri-gate versus Silicon Nanowire Tri-gate 48

4.4.2 SNWTT with Two Different Insulator

Layers

50

4.4.3 Channel Radius Variation 52

4.4.4 Temperature effect on SNWTT performance 55

4.4.5 Doping concentration effect 56

4.5 Summary 58

5 CONCLUSION AND RECOMMENDATIONS

5.1 Conclusion 59

5.2 Suggestions for Future Work 61

REFERENCES 63-70

APPENDICES 71-78

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LIST OF TABLES

TABLE NO. TITLE PAGE

2.1 Comparison of nanowire MOSFET device 18

4.1 The geometry values of silicon nanowire tri-gate transistor

Model 46

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LIST OF FIGURES

FIGURE NO. TITLE PAGE

1.1 The numbers of transistors in Intel processor increased

exponentially throughout the years from 1960 to 2010

according to Moore‘s Law

2

1.2 International Technology Roadmap for Semiconductor

(ITRS,2011)

4

1.3 Technology trends on MOSFET (Jakub Kedzierski, 2011) 5

2.1 Structure of (a) Silicon dioxide gate dielectric (b) Potential

high-k dielectric

12

2.2 An effective channel length modulation at saturation

mode.

13

2.3 A comparison between ideal curve MOSFET and

MOSFET with channel length modulation effect.

14

2.4 Schematic representation of different architecture

Silicon Nanowire MOSFET (K. Henari et. al, 2005).

16

2.5 Summary Progression of device structure from single-

gated planar to fully GAA NW MOSFETs (Navab Singh

et al, 2008)

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2.6 Drain current versus gate voltage for Silicon Nanowire 21

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2.7 Illustration of (a) TEM cross section of N-MOS Tri-gate

structure (b) 3-Dimensional of Tri-gate structure (Doyle et

al., 2003).

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2.8 Corner effect reduction methods using Pi-Gate device as

reference (Ritzenthaler et al., 2006).

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2.9 The architecture of (a) 3-D of Tri-gate (b) Cross section of

3-D tri-gate include the corner region

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3.1 Schematic diagram for silicon nanowire transistor 34

3.2 Methodology for Silicon Nanowire Tri-gate Transistor

modeling.

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3.3 Flow chart for device simulation of silicon nanowire tri-

gate transistor, SNWTT

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4.1 Schematic diagram for Silicon Nanowire Tri-gate in (a) 2-

dimensional (2-D) (b) 3-dimensional (3-D)

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4.2.1 Structure of a) Tri-gate transistor b) Silicon Nanowire Tri-

gate transistor

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4.2.2 I-V curve Silicon Nanowire Tri-gate designed and

reference Tri-gate (Gate length, Lg = 26nm; Vds = Vgs =

1V)

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4.3.1 (a) Silicon Nanowire Tri-gate Transistor with oxide layer

structure,

(b) Silicon Nanowire Tri-gate Transistor with high-k

(HfO2) layer structure

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4.3.2 I-V curve for undoped high-k (HfO2) layer and undoped

oxide layer

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4.4.1 (a) SNWTT structure with 9nm radius, (b) SNWTT

structure with 11nm radius

52

4.4.2 I-V curve for SNWTT with various channel radiuses 53

4.4.3 Graph of threshold voltage, Vth against radius of channel

of SNWTT

54

4.4.4 DIBL against radius of channel of SNWTT 55

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4.5 I-V curve incorporating with SNWTTs for different

temperature

55

4.6 I-V curve for doped high-k metal (HfO2) with different

doping concentration, Na

57

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LIST OF ABBREVIATIONS

MOSFET -Metal-Oxide-Semiconductor Field-Effect Transistor

FinFET -Fin Field-Effect-Transistor

GAA -Gate-All-Around

SNWT -Silicon Nanowire Tri-gate

SNWTT -Silicon Nanowire Tri-gate Transistor

DIBL -Drain Induced Barrier Lowering

BJT -Bipolar Junction Transistor

FET -Field Effect Transistor

IC -Integrated Circuit

SCE -Short Channel Effect

ITRS -International Technology Roadmap for Semiconductor

TCAD -Technology Computer Aided Design

GIDL -Gate Induced Drain Leakage

EBM -Electron Beam Lithography

VLS -Vapor Liquid Solid

CVD -Chemical Vapor Deposition

SS -Subthreshold Swing

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LIST OF SYMBOLS

Ioff -Off-state current/ Leakage current

Ion -On-state current/ Drive current

HfO2 -Hafnium dioxide

SiO2 -Silicon Oxide

Leff -Effective channel length

𝐶𝐺 , -Gate capacitance

𝑉𝐺𝑇 -Gate voltage

𝜐𝑠𝑎𝑡 -Velocity saturation

𝐼𝐷𝑠𝑎𝑡 -Drain current in saturation

𝑅𝑖𝑛𝑠 -Radius of insulator

𝑅𝑤𝑖𝑟𝑒 -Radius of channel

𝑉𝑐 -Critical Voltage

𝜇0 -Electron permittivity

𝜇𝑙𝑓 -Mobility of electron that is correlated to the mean free

path

A -Capacitor area

K -Dielectric constant of the material

ε0 -Permittivity of free space

T -Thickness of the capacitor oxide insulator

𝑓(𝐸) -Fermi-Dirac Distribution

E -Quantum state of energy

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EF -Fermi energy

kB -Boltzmann‘s constant

T -Temperature

𝜇𝐿𝐹 -Mobility of electrons under low electric field

𝜀𝑜𝑥 -Permittivity of an insulator

𝛼 -Body factor

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LIST OF APPENDICES

APPENDIX TITLE PAGE

A Fabrication Process by Structure 69

B Sentaurus TCAD software 73

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1

CHAPTER 1

INTRODUCTION

1.1 Research Background

The first discovery of the transistor was reported, in 1925 by Julius Edgar

Lilienfeld. Twenty five years later, Bell Laboratories junction transistor created by

Bell Telephone was named as bipolar junction transistor (BJT) while Lilienfeld‘s

design named as field effect transistor (FET). After that, in year 1959, Dawon

Kahng and Martin M. (John) Atalla invented metal-oxide-semiconductor field-

effect-transistor (MOSFET). These findings have become a pioneer in the

development of the transistor world. Since the day, the electronic industry has

started to growth aggressively with rapid changes in every year. In order to expand

the usage of transistors for many areas, the integrated circuit, (IC) was designed,

which is consisting of a number of transistors. From here, a lot of devices have

been produced for many applications such as for automotive, telecommunication

and security and alarm as well as for medical treatment. Besides, a lot of

sophisticated gadgets have been introduced such as notebook, iPad, smart phones

and many more. Previously, it was obvious people only buy the electronic gadget

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as a hobby or interest. But nowadays, it seems everything has changed and the

gadget is become a necessity in their routine life. In addition, the functionality of

the device is adorable and up to date.

Since today‘s generation concern with the latest invention of electronic

devices, the manufacturer has faced a great responsibility and challenges to make

their product more sophisticated, small and light in size, convenient, reliable,

higher processing speed, and lower power consumption with affordable prices

compare to previous one for the next following years . Normally, the

manufacturers will compete to market their product. To insure to stay ahead, they

will offer to the consumer a multifunctional devices features with reasonable

prices. A multifunctional device normally requires a very complex circuit in the

integrated circuit to enable the device system operate with high speed device and

low power consumption. Both of these two criteria would be the main concern for

the next product for all of electronic suppliers.

Figure 1.1: The numbers of transistors in Intel processor increased exponentially

throughout the years from 1960 to 2010 according to Moore‘s Law

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The remarkable evolution of semiconductor from a single transistor to a

million of transistor packaging into a single chip was introduced by Moore‘s Law.

Moore‘s Law stated that the number of transistor in the IC is predicted to be

double for every two years which has begun since 1959 as shown in Figure 1.1. To

meet this requirement, scaling down the transistor is a must to ensure more

transistors can be incorporated into a single IC. Besides, more functionality can be

added and lead to a better device performance.

However, scaling down of MOSFET to nanometer scale results in major

challenges including simultaneously maintaining satisfactory drive current, Ion ,

reducing leakage current, Ioff, controlling short channel effect (SCEs), drain

induced barrier lowering (DIBL), carrier or electron surface scattering and velocity

saturation may severely affect and degrade the performance of this device.

According to the International Technology Roadmap for Semiconductor (ITRS,

2011), it pointed out some potential solutions and approaches to overcome

transistor scaling limitation such as initiation of new materials: carbon nanotube,

high-k dielectric, strain silicon and metal gate; new devices structures: vertical

MOSFET, multigates such as double gate, tri-gate, surrounding gate-all-around

(GAA) and FinFET.

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Figure 1.2: International Technology Roadmap for Semiconductor (ITRS, 2011)

Multigates MOSFET such tri-gate has gain outstanding attention by the

researcher as evident growing numbers of publication in recent year. TCAD tools

seem help the researcher to analyze the multigates device behavior in a short time.

Moreover, it also can reduce time to the market for the device as a result it can

fulfill the demand by the industry and consumer. This research work will focus on

the simulation and characterization of silicon nanowire with high-k insulator

behavior based on the three dimensional, (3D) geometry effect of the channel, by

using TCAD tool.

5

1.2 Problem Statements

The downsizing of channel length in a planar MOSFET leads to several

disadvantages. Therefore, the conventional devices' modeling is no longer accurate

when the channel lengths reach the nanometer scale due to the numerous unknown

parameters. As a result, silicon nanowire tri-gate transistor with high-k (HfO2)

insulator is the potentially one of the alternatives to overcome all the scaling issues

specifically on leakage current, Ioff. It can be seen in Figure 1.2 that the latest trend

is FinFET (double gate) MOSFET with channel length 22nm, with silicon

nanowire tri-gate transistor structure channel length can be further shrinks to

20nm.

Figure 1.3: Technology trends on MOSFET (Jakub Kedzierski, 2011).

Hence, the proposed model of silicon nanowire tri-gate transistor with high-k

insulator is following the trends. Silicon nanowire ideal structure, gate-all-around

(GAA) is the benchmark of proposed model. Since GAA has numerous

advantages: excellent gate control; high Ion/Ioff ratio; suppressed leakage current

and high drive current.

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Here are the questions that are bound to be answered throughout the research:

a. How to maintain high drive current, Ion?

b. What is the relationship of corner effect in silicon nanowire tri-gate with

transistor structure?

c. How to minimize the leakage current?

1.3 Research Objectives

The research focus on analytical analysis by structure and not by process of

silicon nanowire transistor model using 3D Sentaurus TCAD tool and MATLAB

software is utilized to evaluate the performance of the model. On the whole the

objectives of this research are:

(i) To model silicon nanowire tri-gate transistors with oxide (SiO2) layer and

high-k (HfO2) insulator layer.

(ii) To simulate the device performances based on the model designed for

both silicon nanowire tri-gate transistor with oxide (SiO2) layer and high-

k (HfO2) insulator layer.

(iii) To characterize the electrical properties of silicon nanowire tri-gate

transistor with oxide (SiO2) layer and high-k (HfO2) insulator layer.

(iv) To analyze and compare device performance between tri-gate transistor

with oxide (SiO2) and high-k (HfO2) insulator layer.

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1.4 Research Scopes

This research scopes cover the analytical modeling of 3D silicon nanowire

tri-gate transistor, simulation of two difference models (silicon nanowire with

oxide (SiO2) layer and silicon nanowire tri-gate with high-k (HfO2) insulator layer)

and comparison of the result from both models. The scopes of the research briefly

explain as follows:

(i) Implement the structure of silicon nanowire tri-gate transistor with oxide

(Si02) layer and high-k (HfO2) insulator layer using 3D simulator tool(

Sentaurus TCAD software)

(ii) TCAD simulation for silicon nanowire tri-gate transistor by including

the corner effect on the channel. The channel length used as the starting

point is 65nm (validation).

(iii) MATLAB graph plotting for I-V curves extraction for each design.

Analyzing the performance based on specified electrical properties.

(iv) Comparing the device performances of silicon nanowire tri-gate transistor

with oxide (SiO2) layer and silicon nanowire tri-gate with high-k (HfO2)

layer.

1.5 Thesis outline

The outline of thesis begins with introduction and general background

reviews and reasons to conduct this research as can be found in Chapter 1.

The literature review and theory of silicon nanowire tri-gate transistor are

performed in Chapter 2.

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It establishes new insights on one-dimensional physics, which provides a

foundation to the rest of the proposal. Methodology part will take place in Chapter

3 in which the research activities will be described in details. The findings and

discussion of the research will be demonstrated in the following section, Chapter 4.

Finally, the findings of the current achievements will be summarized in conclusion

section.

CHAPTER 2

LITERATURE REVIEW

2.1 Introduction

The basic principle of transistor was first patented by Julius Edgar

Lilienfeld in 1925. Twenty five years later, when Bell Telephone attempted to

patent the junction transistor, they found Lilienfeld already holding a patent which

was worded in a way that would include all types of transistors. Bell Labs was able

to work out an agreement where Bell Labs transistor patent was given the name

bipolar junction transistor, (BJT), and Lilienfeld's design took the name field effect

transistor. Then, in year 1959, Dawon Kahng and Martin M. (John) Atalla at Bell

Labs invented the metal–oxide–semiconductor field-effect transistor (MOSFET) as

an offshoot to the patented FET design which has become a pioneer in transistor

world.

10

2.2 MOSFET scaling

The MOSFET has continually been scaled down in size; typical MOSFET

channel lengths were once several micrometers, but modern integrated circuits are

incorporating MOSFETs with channel lengths of nanometers. Robert Dennard's

work on scaling theory was pivotal in recognizing that this ongoing reduction was

possible. Hence, Intel began production of a process featuring a transistor with 32

nm channel length in late 2009. The semiconductor industry maintains a

"roadmap", the ITRS,[20] which sets the pace for MOSFET development. The

main purposes of scaling down transistor are to pack more transistors per chip,

reducing fabrication cost, and elevate overall devices performance. However, the

reduction of MOSFET size has cause complication on semiconductor device

fabrication process (discuss further in section 2.1.3).

2.3 MOSFET scaling issues

Producing MOSFETs with channel lengths beyond micrometer

(nanometer) is a challenge, and will lead to several issues.

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2.3.1 Higher subthreshold conduction

As MOSFET geometries shrink, the voltage that can be applied to the gate

must be reduced to maintain reliability. To maintain performance, the threshold

voltage of the MOSFET has to be reduced as well. As threshold voltage is reduced,

the transistor cannot be switched from complete turn-off to complete turn-on with

the limited voltage swing available; the circuit design is a compromise between

strong drive current, Ion and low leakage current, Ioff. Subthreshold leakage can

contribute to increment of total power consumption. [22]

2.3.2 Increased gate oxide leakage

The gate oxide, which serves as insulator between the gate and channel,

should be made as thin as possible to increase the channel conductivity and

performance when the transistor is on and to reduce subthreshold leakage when the

transistor is off. However, with current gate oxides with a thickness of around 1.2

nm as shown in Figure 2.1(a) the quantum mechanical phenomenon of electron

tunneling occurs between the gate and channel, leading to increased power

consumption.

Silicon dioxide has traditionally been used as the gate insulator. Silicon

dioxide however has a modest dielectric constant. Increasing the dielectric constant

of the gate dielectric allows a thicker layer while maintaining a high capacitance

where capacitance is proportional to dielectric constant and inversely proportional

to dielectric thickness. Higher dielectric thickness can reduces the quantum

tunneling current through the dielectric between the gate and the channel.

12

Insulators that have a larger dielectric constant than silicon dioxide is high-k

dielectrics, such as group hafnium dioxide, HfO2 and zirconium silicates are being

used to reduce the gate leakage from the 45 nanometer technology node onwards.

Figure 2.1: (a) Silicon dioxide gate dielectric structure,

(b) Potential high-k dielectric structure

2.3.3 Increased junction leakage

To make devices smaller, junction design has become more complex,

leading to higher doping levels, shallower junctions, "halo" doping and so

forth,[23][26] all to decrease drain-induced barrier lowering To keep these

complex junctions in place, the annealing steps formerly used to remove damage

and electrically active defects must be curtailed[24] increasing junction leakage.

Heavier doping is also associated with thinner depletion layers and more

recombination centers that result in increased leakage current, even without lattice

damage.

13

2.3.4 Short Channel Effect

A short channel effect is a key or indicator of limitation of device scaling.

The aims of scaling are to reduce the size of transistor in order to integrate more

transistors into a single chip to achieve low power dissipation per function,

increased speed and function density of transistors (Dennard, 1997)[6]. The degree

of worsening short channel effect can be seen obviously from these effects such as

channel length modulation, drain induced barrier lowering (DIBL), threshold

voltage roll-off, velocity saturation, punch-through, impact ionization, hot carriers,

source drain series resistance, gate induced drain leakage (GIDL), band to band

tunneling, poly-Si depletion and quantum effects. However, only several effects

will be discussed extensively which related with the models development and

simulation work.

2.3.5 Channel Length Modulation

Fig 2.2: An effective channel length modulation at saturation mode.

14

Originally, the channel length, L is assumed as a constant in ideal case of

the current-voltage model. However, this consideration is not valid when MOSFET

is biased in the saturation region. Under this condition, the depletion region (∆L) at

the drain terminal extends laterally into the channel, thus, the effective channel

length getting smaller. The depletion region width is bias dependent; it also makes

the effective channel length (Leff) modulated by the drain to source voltage. This

phenomenon is called as channel length modulation as shown in Fig 1. The

importance to this effect is clearly visible when the actual channel length is

reduced by a factor of Leff =L-∆L. This lead to a shorter channel length and

increased the drain current. Ignorance of this situation can cause an existence of

uncertainty because Leff is a very crucial parameter for characterization and

optimization, SPICE model extraction and manufacturing control (Chung et

al.,1999)[7]. In standard MOSFET, the general views can be seen from channel

length modulation is shown in Figure 2.3.

Fig 2.3: A comparison between ideal curve MOSFET and MOSFET with

channel length modulation effect.

0 5 10 15 20 25 300

0.5

1

1.5

2

2.5

3x 10

-3

Drain Voltage,VDS

(V)

Drain

Cu

rren

t, I

D(A

)

Simulated data with Channel Length Modulation Effect

Ideal Curve MOSFET

15

2.4 Alternatives and Potential Solutions to Overcome Scaling Issues

In order to overcome scaling issues encountered, there are potential

solution such as the introduction of new materials and new structures. All these

potential alternatives are being applied by researcher were shown in technology

trends of MOSFET. Since 2001, when bulk MOSFET was fabricated with the

technology node of 130 nm by Intel as Under this technology, the device was

produced using gate length and oxide thickness of 60 nm and 1.5 nm respectively

(Thompson et al[10]., 2001). An attempt to reduce the oxide thickness from 1.5

nm to 1 nm (30%) was failed when gate leakage current increased up to 100 A

[11](Lo et al., 1997). From these result, gate oxide thickness cannot be scale down

as the next technology node.

Then, strained silicon a new material of transistor was reported within a

year 2003 as the 90nm technology node (Thompson et al., 2004; Ghani et al[12].,

2003). In this technology, an oxide thickness and gate length were defined as 1.2

nm and 45 nm .The effect an incorporation of strain into silicon could alter the

mobility as well as improve device performance. Uniaxial longitudinal stress is

very convincing in enhancing the performance. In the following two years, a

65nm technology node was presented where the gate length is reducing to 35 nm.

The achievement in this node is better compared than the former node with

installation of enhanced strain layer [13](Bai et al., 2004). A high k-metal and

metal gate were introduced in the 45 nm technology node using the oxide

thickness of 1 nm (Mistry et al., 2007)[14]. A second generation of a high-k

metal gate was reported with 32 nm technology node (Jan et al., 2009; Jan, et al.,

2009; Packan, et al., 2009)[15-17]. In order to enable downscaling for the next

node, an implementation of high-k is an inevitable. A great performance from

this technology node was a rectification of Idsat, Idlin as well as highest drive

currents from the past node ( Mistry et al., 2007 ; Packan, et al., 2009; Auth, et

al., 2008 ) .

16

The latest technology node was completely different from previous

device and node, where the device was created based on a new structure,

FinFET; one of the high achievements among the existence technology node

with excellent performance. Besides, the gate length also reported as the

smallest. The outcome of every technology node explained earlier only could be

achieved through the research work. Thus, a continuous improvement needs to

perform so that the device for the next technology node can be prepared better

and enhanced from the existence node.

2.5 Silicon Nanowire

2.5.1 Silicon Nanowire Structure

Silicon nanowire FETs are more appealing than the conventional Double

Gate (DG) FETs because of its higher on-current conduction due to their quantum

nature and its adoptability for high density integration including that of 3D.

Figure 2.4: Schematic representation of different architecture silicon nanowire

MOSFET (K. Henari et. al, 2005).

17

Silicon nanowire transistors offer better gate control and more flexibility

in device design (Lundstorm and Jing Guo, 2006) when comparing with planar

double-gate (DG) MOSFETs. Figure 2.5 shows the evolution of multiple-gate

transistors schematically in the order of increasing gate electrostatic control.

Apparently, the tri-gate structure is the better resistant to short-channel effects than

FinFET device structures for given silicon body thickness. The reduction in

channel 11 width and thickness can further increase the effectiveness of the gate

control and become major candidate for extreme CMOS scaling process

complexities.

Figure 2.5: Progression of device structure from single-gated planar to

fully GAA NW MOSFETs (Navab Singh et al, 2008)

There have been several experiments that demonstrated the advantages of

tri-gate gaining short-channel control as thin-body double-sided FinFET, excellent

drain-induced barrier lowering (DIBL) suppression, better on current and leakage

current. Tables 1 indicate the DIBL suppression effect for a given architecture of

nanowire. Furthermore, the cylindrical geometry gives inverse logarithmic

dependence of the gate capacitance on the channel diameter; the gate length in

these devices can be scaled with wire diameter without reducing the gate dielectric

thickness (Navab Singh et. al, 2008).

18

Table 2.1: Comparison of nanowire MOSFETs

2.5.2 Silicon Nanowire Electrical Properties

Many theoretical works have been reported to investigate the behavior of

electron transport silicon nanowire. The electronic properties of silicon nanowire

could be altered using the following methods such as introducing the dopant,

varying the diameter, surface reconstruction as well as passivating the surface.

[65](Muller et al., 1986) observed that the additional dopants into lattice structure

could enhance the carriers transport. These dopants either donor or acceptor

actually act as catalyst to increase the stability of atomic bonding by making them

more stable. The band gap of silicon nanowire is found to be reduced with the

increment of diameter as well as surface reconstruction (Vo et al., 2006)[66].

Surface reconstruction is referring to the shape of silicon nanowire cross section

during the growth process. Silicon nanowire with orientation <110> is believed

can behave as metallic or semi-metallic depending on its surface reconstruction

[67](Rurali, 2010).

19

Surface passivation in SNWs occurred due to the growth of insulator

layer by thermal oxidation and the existence of hydrogen atom during growth

process ( Zhong et al., 2003)[68]. Such technique was proven can improve the

mobility of SNW as reported by (Cui et al., 2003)[69].

2.5.3 Fabrication process of Silicon Nanowire

Silicon nanowire transistor have recently gained a great attention, due to

their wide potential to implement as nanoscale electronics device [70]( Cui &

Lieber, 2001)[71]. This statement also agreed by (Singh et al., 2006)[72] when

their findings in such device exhibit a good device performance in terms of drive

current, ideal subthreshold slope (SS), low DIBL, and high ION/IOFF.

Normally, silicon nanowire transistor is synthesized using ―top-down‖ or

―bottom up‖ approaches. For ―top-down‖ approach, silicon nanowire growth using

electron beam lithography (EBM) meanwhile for ―bottom up‖ approach, vapor

liquid solid (VLS) and chemical vapor deposition (CVD) underlying under this

method. Each method will be discussed at length in the next section.

20

2.5.4 Relationship between current and voltage of silicon nanowire

transistor

The best way to explain the silicon nanowire is a new structure device

based which has an outstanding electrical characteristics such as high mobility,

high on drive current and the most important key is downscaling process could be

proceed much further with desired size and performance [ 1-6 ]. Eventually, such

device is still using the silicon as common material in fabrication process. The

ultimate goal in modeling is to develop drain current model in order to see either

the device could be implemented as a device through the critical analysis on its

performance. The drain current model for SNW contains two different regions

which are saturation region and linear region. The drain current in saturation is

given as ( Ahmadi et al., 2009)

𝐼𝐷𝑠𝑎𝑡 = 𝐶𝐺 𝑉𝐺𝑇 − 𝑉𝐷𝑠𝑎𝑡 𝑣𝑠𝑎𝑡 (2.1)

where 𝐶𝐺 ,𝑉𝐺𝑇 , 𝜐𝑠𝑎𝑡 respectively are the gate capacitance, gate voltage and

saturation velocity. Gate capacitance for cylindrical is calculated as followed:

𝐶𝐺 = 2𝜋ɛ𝑖𝑛𝑠

ln 𝑅𝑖𝑛𝑠

𝑅𝑤𝑖𝑟𝑒 (2.2)

The variables such 𝑅𝑖𝑛𝑠 , 𝑅𝑤𝑖𝑟𝑒 are represent as radius of insulator and channel

correspondingly. The drain voltage at saturation regime is denoted as (Ahmadi et

al., 2009)

𝑉𝐷𝑠𝑎𝑡 = 𝑉𝑐 1 +2𝑉𝐺𝑇

𝑉𝑐− 1 (2.3)

where 𝑉𝑐 is the critical voltage and defined as 𝑉𝑐 = (𝜐𝑠𝑎𝑡 / 𝜇0)𝐿 .

21

A drain current model in linear region is formulated as

𝐼𝐷 =𝐶𝐺𝜇𝑙𝑓

2𝐿 2 𝑉𝐺𝑆 − 𝑉𝑇 𝑉𝐷 − 𝑉𝐷

2

1 +𝑉𝐷

𝑉𝐶

(2.4)

where 𝜇𝑙𝑓 is the mobility of electron that is correlated to the mean free path. Thus,

a final view on the current-voltage curve is demonstrated in Figure 2.6.

Linear region

Saturation region

Figure 2.6: Drain current versus gate voltage for Silicon Nanowire

(Ahmadi et al., 2009)

22

2.6 Tri-gate MOSFETs

2.6.1 Tri-gate structure

Tri-gate structure is more promising in comparison to the double gate

structure, not only due to its favorable electrical behavior, yet has a simple and

low cost of fabrication method ( Wong et al., 1997; Doyle et al., 2003)[25, 36].

Moreover, the manufacturing process of the device is compatible with CMOS

technology. The first tri-gate process was invented by (Doyle et al., 2003) as

shown in Figure 2.7. The inventors even have patented their findings as intellectual

properties (Chau et al., 2009)[37]. Their works have inspired many researchers

with rapid number of publications for further development in such device (Breed

et al., 2003; Chau et al., 2005; Thean, et al., 2006; Haensch et al., 2006; Bernstein

et al., 2006; Moselund et al., 2006; Lee et al., 2007; Garcia et al.,2007; Ernst et al.,

2007; Jin et al., 2007) . [35, 38-46] In this experiment, the device was fabricated

for the gate length of 60 nm, meanwhile silicon fin width and height respectively

55 nm and 36 nm. Firstly, the formation of body fin was prepared using the same

method as poly-silicon gate. Aggressive poly-silicon lithography and etching

techniques were used in order to have the fin width similar to gate length. Next, a

conventional boron implant was implemented to achieve desire threshold voltage.

The oxide layer was formed on the top of body fin with thickness of 1.5 nm. To

reduce parasitic resistance, raised source and drain were introduced. The formation

of contact surface for source, drain and gate were silicided using metal such nikel.

In overall, an important findings from this process is a fully depleted device could

be achieved with excellent electrical performance of Subthreshold Swing(SS) ,

Drain Induced Barrier Lowering(DIBL) , the on state current ( ION ) and the off

state current ( IOFF.).

23

Figure 2.7: Illustration of (a) TEM cross section of N-MOS Tri-gate structure

(b) 3-Dimensional of Tri-gate structure (Doyle et al., 2003).

Another fabrication process was proposed by (Landgraf et al., 2006) [47]

with body doping and influence of crystal orientation as the subject of the analysis.

SOI substrate was prepared by staking the 50 nm silicon above the buried oxide

layer with thickness of 100 nm. Next, the body fin was doped with boron, with

doping concentration of 2 × 1015 cm−3. Then, the silicon body was patterned with

the hardmask layer using e-beam lithography and plasma etching ( Kretz et al.,

2003)[48]. To round the corner, a sacrificial oxide was used to vary the silicon fin

surface. Before hand, the hardmask was removed in order to grow the insulator

(SiO2) on the top layer of silicon fin. The process of gate formation includes such

phosphorus deposition and patterned using e-beam mask. The spacer was

deposited and etched anistropically with material of SI3N4 and thickness of 20 nm.

To form raised source and drain, 60 nm of epitaxially silicon was grown. The

corresponding region was doped with arsenic using annealing method and

temperature of 1000C.Finally, metallization was used to form contact for source,

drain and gate.

(a) (b)

24

In overall, the fabrication process as described earlier do not emphasized

much about the consequence of corner effect toward performance analysis.

However, corner effect is of the important issue need to look into a consideration

because the effect has major connection with the I-V characteristic of the device

[25](Doyle et al., 2003). In the next section, several methods that have been used

to reduce such effect will be discussed extensively.

2.6.2 Corner Effect in Tri-gate Structure

Published works have highlighted the advantageous of tri-gate as future

device (Poiroux et al., 2005; Kavalieros et al., 2006 ; Doyle et al., 2003; Sun et al.,

2008 )[49-52], instead of their benefits, multi-gates can give different values in

threshold voltage (Ritzenthaleret al., 2006) [53]. This variation can affect the

electrical characteristic of the device. Based on Figure 2.8, originally the device

(Pi-Gate) has two maximum points which are represent two different sets of

threshold voltage. This phenomenon called as corner effect. Nevertheless, when

the device is subjected to different corner effect reduction methods, the threshold

left as a single value.

25

Figure 2.8: Corner effect reduction methods using Pi-Gate device as a reference

(Ritzenthaler et al., 2006).

Several alternatives were proposed to reduce corner effect. According to

(Fossum et al., 2003)[54], they suggest that the fin body should be left undoped in

order to minimize the corner effect. The two-dimensional (2D) numerical

simulation was used to perform the analysis. Figure 2.9(a) shows the three

dimensional (3D) of tri-gate meanwhile Figure 2.9(b) describes the cross section of

tri-gate with the corner region included through this analysis. Eventually, this

technique only applicable for the device beyond 50 nm and low threshold voltage

application due to the changes of impurities position (Dollfus et al.,2004) [55].

26

Figure 2.9: The architecture of (a) 3-D of Tri-gate (b) Cross section of 3-D tri-

gate include the corner region

2.7 High-k dielectric

Silicon dioxide has been used as a gate oxide material for decades. As

transistors have decreased in size, the thickness of the silicon dioxide gate

dielectric has steadily decreased to increase the gate capacitance and thereby drive

current, raising device performance. As the thickness scales below 2 nm, leakage

currents due to tunneling increase drastically, leading to high power consumption

and reduced device reliability. Replacing the silicon dioxide gate dielectric with a

high-κ material allows increased gate capacitance without the associated leakage

effects.

(a) (b)

27

The gate oxide in a MOSFET can be modeled as a parallel plate capacitor.

Ignoring quantum mechanical and depletion effects from the Si substrate and gate,

the capacitance C of this parallel plate capacitor is given by

𝐶 =𝑘𝜀0𝐴

𝑡 (2.5)

Conventional silicon dioxide gate dielectric structure compared to a potential high-

k dielectric structure. Where A is the capacitor area, κ is the relative dielectri

constant of the material, ε0 is the permittivity of free space and t is the thickness of

the capacitor oxide insulator. Since leakage limitation constrains further reduction

of t, an alternative method to increase gate capacitance is altering κ by replacing

silicon dioxide with a high-κ material. In such a scenario, a thicker gate oxide layer

might be used which can reduce the leakage current flowing through the structure

as well as improving the gate dielectric reliability.

2.7 Summary

Multigate such as double gate, tri-gate, surround gate, and FinFET have

been studied rigorously as potential successor of MOSFET. Besides that, high-k

material such as hafnium dioxide has been introduced to replace oxide layer.

Following that, the designed model; silicon nanowire transistor with high-k

insulator is relevant to recent technology trends with channel length variation

down to 22nm.

28

In addition, design approaches of model are different from published

work where implementation using three-dimensional (3D) Sentaurus TCAD tool,

advanced version of SILVACO and the design process is by structure and not by

process. Contributions of this design model as compared to published work are

on structure, device optimization based on parameter variation and analysis.

CHAPTER 3

RESEARCH METHODOLOGY

3.1 Introduction

This chapter focused on the method use to virtually fabricate of silicon

nanowire tri-gate transistor with high-k (HfO2) insulator using Sentaurus‘s TCAD

tools. The overall process flow for SNWTT are shown and discussed in details.

3.2 Research Activities

The aim of this research is to model and analyze a silicon nanowire tri-

gate transistor with high-k insulator.

30

This includes the studies and development of low leakage current and

high driving current, effective mobility, thermal effect, doping concentration and

finally the I-V characteristics of a three-dimensional (3D) silicon nanowire tri-gate

transistor model. The main challenge is to validate the model with the

experimental data as 3D modeling with Sentaurus TCAD tool is considered as a

new-emerging approach of silicon nanowire tri-gate transistor with high-k

insulator and research is still rapidly taking place so far. Therefore, data extracted

from Sentaurus TCAD tool will used for I-V curve plotting via MATLAB. The

plotted I-V curves will be compared with reference model as well as comparison

with silicon nanowire tri-gate transistor with tri-gate transistor. Basically, the

research activities consist of three components which are:

1. Literature review, which includes the studies of published material

and resources.

2. Modeling silicon nanowire tri-gate with high-k insulator and

silicon nanowire tri-gate with oxide layer.

3. Modeling the development of low leakage current and high driving

current, effective mobility and finally the I-V characteristics

4. Numerical simulation and comparison with model or experimental

data via MATLAB.

5. Optimization of the model until satisfying result is achieved.

3.3 Modeling approach

In implementing a silicon nanowire tri-gate transistor structure, full

process flow using a commercial three-dimensional (3D) technology CAD

(TCAD) tool is used.

31

The simulation is based on and refers to the modeled tri-gate FET

devices. Using our real process flow, various process simulation parameters from

activation models are first calibrated to the experimental data. Device simulations

are then performed with varying doping, channel width, channel height and length,

and box thickness.

Sentaurus-Process and Sentaurus-Device simulators from Synopsys [23]

have been used in this work because of its 3D process and device capability and

the compatibility to the mainstream 2D TCAD framework TSUPREM4/ MEDICI

(also from Synopsys) which has been well calibrated to all advanced CMOS logic

technologies. The critical process steps for tri-gate FET on standard SOI are gate

oxide growth, gate formation, and source-drain implant before final annealing .All

necessary thermal steps have been excluded in the process simulation.

3.3.1 MATLAB

A MATLAB (version 2008) tool is widely used by different background

peoples such as student, engineer and even professional in order to simulate the

numerical models. The simulator enables the users to perform computationally

tasks faster than traditional programming languages such as C, C++ and Fortran.

By simulating the model, numerous types of graph can be generated. In addition,

from those graphs, a critical analysis can be attained. The research framework in

Chapter 4 will be conducted using this simulator.

32

3.3.2 SENTAURUS TCAD

Sentaurus is classified as one of the Technology computer aided design

(TCAD) which accommodate a user friendly and convenient tools for

semiconductor devices. The tools comprises of Process Simulation, Structure

Editing and Device and Interconnect. Both of the Process Simulation and the

Structure Editing are provided to develop the actual wafer fabrication process

virtually. Meanwhile, Device and Interconnect tool, it can be used to characterize

and extract the electrical properties.

TCAD tools are crucial for semiconductor industry which usually faced

with time and cost constraints. Requirement of high speed device with advanced

technology may be the reason for the semiconductor always exposed to the

technology innovation. The advantages of TCAD tool are reduced time and cost

consuming for technology development. Besides, it also compatible with fast

prototyping, development and optimization of semiconductor technology

(Synopsy,2012) ("Modules of Sentaurus TCAD Industry-Standard Process and

Device Simulators at "). The tools also occupied with the physics modeling

capabilities. Not only is that, the tools flexible to execute for multidimensional

devices such as two dimensional (2-D) and three dimensional (3-D) devices. Thus,

Sentaurus TCAD will be used to carry the researches aims.

33

3.4 The SNWTT Modeling

3.4.1 Fermi-Dirac Distributions

The function of 𝑓(E) is called as Fermi-Dirac Distribution which

provides the probability that a quantum state at energy E will occupied by the

electron expressed as (Lau, et al., 2008) [82]

𝑓 𝐸 =1

𝐸 − 𝐸𝐹

𝑒𝑘𝐵𝑇+1

(3.1)

where 𝑓 E , EF , kB , T respectively represent as the occupation probability of a state

of energy E , Fermi energy, boltzmann‘s constant and temperature. This

distribution explains the probability of electron to occupy the empty state at certain

energy, E, and temperature, T. Fermi-Dirac Distribution can be approximated in

two different conditions either degenerate or non degenerate state. For degenerate,

when the energy of electron is equal to energy of electron at Fermi level (E = EF) ,

the probability of electrons is calculated as ½. However, in Maxell-Boltzman (non-

degenerate) approximation, another form of Fermi direct can be clarify as

𝑓 𝐸 =1

𝐸 − 𝐸𝐹

𝑒𝑘𝐵𝑇

= 𝑒−𝐸−𝐸𝐹𝑘𝐵𝑇 (3.2)

where ‗1‘ in the denominator in equation (2.6) can be neglected since the Fermi

energy is below the conduction band (Neamen, 2003)[83]. In this case, the

probability of electrons is estimated as 1 when E = EF.

34

3.4.2 Analytical Model for Silicon Nanowire Transistor

Figure 3.1: Schematic diagram for silicon nanowire transistor

In the beginning of modelling, a development of silicon nanowire

transistor started from fully cylindrical nanowire transistor where the structure is

assumed have the same behaviour as gate all around for comparison the data. It is

done since there is no fabrication yet reported for the proposed structure. In order

to create a model that reflect to silicon nanowire transistor structure, new

capacitance model for its structure was designed; an approximation method was

implemented based on capacitance model for gate all around silicon nanowire .

One dimensional drain current has been implemented which is a function of drain

voltage, 𝑉DS and gate voltage, 𝑉GS in linear and saturation region by (Ahmadi et

al., 2009)[104]. For the linear region 𝑉𝐷𝑠 < 𝑉𝐷𝑆 (𝑠𝑎𝑡 ) drain current condition before

considering the CLM model is given by

35

𝐼𝐷 =𝜇𝐿𝐹𝐶𝐺

2𝐿

2 𝑉𝐺𝑆 − 𝑉𝑇 (𝑉𝐷𝑆 − 𝑉𝐷𝑆2)

1 +𝑣𝐷𝑆

(𝑉𝑠𝑎𝑡

𝜇𝐿𝐹 )

(3.3)

where 𝜇𝐿𝐹 is the mobility of electrons under low electric field (equation 4.7),

𝑉𝑠𝑎𝑡 is the drift velocity in saturation region for degenerate regime (Vijay,1985;

Ahmadi et al., 2009), L is the channel length of device and CG is the gate

capacitance per unit length. For device that operates at the saturation region

𝑉𝐷𝑠 ≥ 𝑉𝐷𝑆 (𝑠𝑎𝑡 ), the drain current before implementing CLM model can be

simplified and expressed as

𝐼𝐷𝑠𝑎𝑡 = 𝐶𝐺 𝑉𝐺𝑇 − 𝑉𝐷𝑆 𝑠𝑎𝑡 𝑣𝑠𝑎𝑡 (3.4)

Gate capacitance per unit length for fully cylindrical structure is presented as

(Lundstrom and Guo, 2006)[105]

𝐶𝐺 = 2𝜋𝜀𝑜𝑥

log(𝑡𝑖𝑛𝑠 + 2𝑡𝑠𝑖

𝑡𝑠𝑖) (3.5)

where 𝜀𝑜𝑥 is the permittivity of an insulator . The thickness value for both

insulator (tins) and silicon (twire) are 10nm and 5nm respectively. Gate

capacitance for Silicon Nanowired FinFET is developed based on approximation

of gate capacitance of gate all round. Given that gate capacitance for respective

structure is given as

𝐶𝐺′ = 𝑛𝐶𝐺 (3.6)

Where n is the ratio of gate capacitance between 70 percent of omega shape and

fully cylindrical that was approximated as 0.86 (L. Yiming et al.,2005)[106] .

36

The equations for drain to source current for both saturation and linear region after

consideration of channel length modulation effect are simplified as ( Hamid, et al.,

2013)

𝐼𝐷′ = 𝛼𝐼𝐷 (3.7)

𝐼𝐷𝑠′ = 𝛼𝐼𝐷𝑠 (3.8)

3.4.3 SNWTT modeling Overview

Generally, the device model is essential method before any device is

implemented in electronic circuit or system. This model is used to study and

predict the device‘s behavior based on carrier transports of electrons, current-

voltage and capacitance voltage characteristics. From here, the electrical

characteristics could be extracted and determine the operation range of the devices.

Normally, these data can be found in datasheet of any semiconductor vendors such

as Intel.

According to Arora, there are two types of device model which are physical device

models and equivalent circuit models (Arora, 2007). Physical device models

normally developed based on transport equations, device geometry, technological

parameters, temperature effects, doping profile and material characteristic (Arora,

2007; Montoro and Schneider, 2007). Even though the model is rarely and not

favorable to used, but, it is useful to investigate the electrical behavior, optical

device and thermal properties.

37

A compact model which also known as equivalent model circuit is consist

of a collection of mathematical equations whose variables are used as an input to

a SPICE-like circuit simulators [7]. The mathematical equation which works

similar as physical mechanism is estimated to be able to extract the electrical

characteristics of a device for different physical dimension, temperature and

process variation [41-46]. This model is more favorable compared to physical

device because the model is normally can be transferred directly to the circuit

application.

The model of this research framework involved with the physical

modeling device. Even though this model takes time to develop; the data obtained

through the model can be used as preliminary views to the device characteristics.

Figure 3.1 shows the research flow of Silicon Nanowire Tri-gate Transistor

modeling. The research activities begin with the literature reviews of Silicon

Nanowire Tri-gate Transistor with high-k insulator which required reviewing the

works that related to the published materials. The literature understanding includes

the carrier statistic, velocity, mobility and I-V curve. The former research work

that associated with research scope also been summarized in Chapter 2 in order to

identify the research gap.

Next, the modeling of I-V of SiNWTT were performed which

incorporated with various parameter; doping concentration, temperature, channel

length and radius of channels. The command scripts for these models then

extracted using Sentaurus Process and it can be edited according to necessity.

After a complete command is written and executed on this file, the output file in

form of graph is generated. In order to make a comparison for varied parameter all

the data from graph generated in TCAD are copied to MATLAB editor so that all

can be plotted n the same graph.

38

From here, the current-voltage proposed SNWTT model then compared with the

published model. If there is no divergence or error, an extensive analysis could be

carried out.

The next stage is the analysis of results obtained from the models after a

comparison with published model. In this work, significant findings from those

variations will be discussed in details in Chapter 4

39

Figure 3.2: Methodology for Silicon Nanowire Tri-gate Transistor modeling

No

Yes

Start

Literature

review

Silicon Nanowire Tri-

gate transistor with oxide

layer implementation

using Sentaurus TCAD.

Silicon Nanowire Tri-

gate transistor with High-

k insulator

implementation using

Sentaurus TCAD. I-V characteristics

(MATLAB)

Result analysis

Analyzing and

comparing the device

performance based

on the graph of

parameters

extraction.

Acceptable Design

improvement

performance

optimization. Finish

40

3.5 A development of Silicon Nanowire Tri-gate

TCAD is listed as physical modeling device tools which simulating the

device based on certain underlying physic concept such as carrier statistic, mobility

and impact ionization of electrons. Numerous of physical model tools that

available nowadays such as PISCES, Atlas, and Synopsys are designated based on

finite element method (Duane, 2002)[98]. Sentaurus TCAD is one of the

applications provided by the Synopsys company. The tools can be used to cut cost

and speed up the research and process development when developing a new

semiconductor device. As the technologies become more advanced and complex,

the semiconductor manufacturers relies increasingly more on TCAD tool. TCAD is

more preferable to implement on the latest technology due to less time and cost

consuming on the production.

The simulation work for silicon nanowire tri-gate transistor was

performed mainly using the Sentaurus TCAD tools. This simulator consists of

three types of device application which are fabrication, structure and device

simulator. Fabrication and structure can be used to design the new structure either

in 2-D or 3-D. However, the recent trends show the structure for semiconductor

device gets complex. For this case, the structure simulator can be used to prepare

for such device. In order to extract the device characterization, finite element

method which known as mesh need to define early. Mesh definition is important to

ensure the accuracy of result yield for analysis the device performance.

In device simulator, the most important thing is to nominate the

appropriate the physical device model. A right model nomination will help to

increase the accuracy of result. Thus, a different model will produced a different

result for device characterization.

41

There are five categories of physical models in device simulator offered

by the Synopsys: carrier statistics, mobility, impact ionization, recombination, and

tunneling model.

From the previous literatures that have been discussed in Chapter 2, the

simulation of fabrication method of Tri-gate and Silicon Nanowire Tri-gate with

high-k insulator were gathered. The fabrication method used needs to ensure

compatible with the CMOS technology. Besides, knowledge and tools required for

device fabrication in TCAD can be found from the manual guideline provided by

the Synopsys. Before hand, Tri-gate and Silicon Nanowire Tri-gate were compared

to see the significant improvement in electrical characteristics. In this research,

the main work is to fabricate the Silicon Nanowire Tri-gate Transistor. The

fabricated of Silicon Nanowire Tri-gate then compared with published data which

has the similar structure such Tri-gate Nanowire using device simulation. From

this method, if the data obtained for fabricated device having the same trend as

published material, then the data analysis will be proceed. Data analysis will be

focusing on the enhancement of electrical properties for the proposed structure

through parameter variations.

The flow chart as shown in Figure 3.2 below summarizes all the

processes done in device simulation using the Sentaurus TCAD program from

beginning up to parameter extraction.

42

Figure 3.3: Flow chart for device simulation of silicon nanowire tri-gate

transistor, SNWTT

Device simulation start by loading the structure file created to Sentaurus

Workbench. There are several steps in device simulation in order to obtain the

SNWTT characteristics for further analysis. The output (IDS versus VDS curve) and

transfer characteristics (IDS versus VGS curve) for DP-MOSFET will be obtained

respectively. In addition, parameters extraction for VT, Ion/Ioff ratio, IOFF, IDsat,

DIBL and others will also be carried out.

Load Structure File

Created to Sentaurus

Workbench

Define Gate

Work Function

Set Material

Model

Choose Contact and

Interface

Characteristics

Select Biasing

Method

Set Different Drain Biases for Certain

Range of Gate Biases to Get the Plot

of Family Curve of IDS versus VGS

Using Log, Solve and Load

Statements

Obtain an Initial Solution

Created from ATHENA

Set Different Drain Biases for Certain

Range of Gate Biases to Get the Plot

of Family Curve of IDS versus VDS

Using Log, Solve and Load

Statements

Parameters extraction

Created from ATHENA

43

3.6 Summary

In this chapter, modeling approach, method, and tools used are being

discussed. The implementation of silicon nanowire tri-gate transistor using

Sentaurus is described in details including the fabrication process. Besides that,

tools used in the research such as Sentaurus TCAD and MATLAB are explained in

details. Flowchart for the whole research work also shown.

CHAPTER 4

CHARACTERIZATION OF SILICON NANOWIRE TRI-GATE

4.1 Introduction

As outlined in the literature reviews, multigate structure such as silicon

nanowire tri-gate offer a lot of advantageous due its good electrical properties

such as better electrostatic controlled and high drive on-current. Enhancement

and improvement of previous multigate structure is studied extensively through

this chapter. However, the main concern for the improvements is discussed in

term of its on-state current (Ion) where silicon nanowire tri-gate is better than

standard tri-gate. Silicon nanowire tri-gate where the channel is a way to control

leakage current and other parameters (SS, DIBL, Ion , Vth ) based numerous

parameter variation.

45

4.2 Silicon Nanowire Tri-gate Structure

A silicon nanowire tri-gate device is designed and simulated using a three

dimensional (3-D) tool known as SENTAURUS TCAD. Figure 4.1 demonstrates

the simulated device with all physical dimensions shown clearly. The device is

made up of silicon material based for both the channel and the substrate region.

Meanwhile for the insulator (silicon oxide) and the buried oxide regions, they are

created using silicon oxide. The gate device is formed using the poly-silicon

material. For channel region, the semi-cylindrical structure is used as a channel

with the radius of 9.5 nm. The width of channel is defined as two times of radius

that is set as 19 nm. The device also has the oxide thickness (tox1 = tox2) of 3 nm. A

lightly doped is chosen at the channel and the gate regions. On the other hand, a

heavily doped is applied at the source and drain region. For the substrate and

buried oxide, they are left as undoped region. All the physical geometries used in

the device are summarized in table 4.1.

Figure 4.1: Schematic diagram for Silicon Nanowire Tri-gate in (a) 2-

dimensional (2-D) (b) 3-dimensional (3-D)

Substrate

BOX

Silicon

Oxide

Gate

A=(pi/2)x(9.5nm)2

tsub

tBOX

tox1

tox2

tgate

(a) (b)

46

Table 4.1: Parameter values that have been used to build silicon nanowire

tri-gate transistor model.

Physical geometry Value

Gate length, Lg(nm) 65

Width of channel (diameter=2*

radius)(nm)

19

Height of channel (radius) 9.5

Channel doping, Nd ( cm-3

) 1e12

Gate doping, Ng ( cm-3

) 1e15

Source/drain doping ,NS/D ( cm-3

) 5e18

Oxide thickness,tox (nm) 3

47

4.3 Flow Chart of Device Fabrication for Silicon Nanowire Tri-gate

Transistor

2. Boron doped (100) Silicon wafer

3. P-type body – Boron implantation (8x1012cm-2, 100keV)

4. Diffuse using dry oxygen (50s,1000oC) & nitrogen gas (90s,1200oC)

5. Removal of growth Oxide

6. Well implantation (B) – to adjust VT

7. Gate oxide, TOX=5nm (800oC)

10. LDD extensions (Arsenic, 8x1013 at/cm2)

9. Deposit Oxide cap layer

8. Deposit PolySi Gate

11. 20nm Nitride spacer formation

12. Etching process, 70nm in the S/D region were formed

13. Selective epitaxy was carried out to fulfill the depression in the S/D

14. Implant HDD junctions with Arsenic (50keV, 5x1015 at/cm2)

15. Anneal with RTA (1000oC, 20s)

1. Mesh Definition

16. Metal Deposition and Contact Openings

18. Mirror the Structure and Name the Electrodes

17. Parameters Extraction

48

4.4 Result and Discussion

4.4.1 Tri-gate versus Silicon Nanowire Tri-gate

Figure 4.2.2 shows the I-V curve Silicon Nanowire Tri-gate designed and

reference Tri-gate of channel length LG=26nm. The graph was simulated by using

normalization method, where the current was normalized by the total of width of

channel and height of the channel. Normally, a standard tri-gate is defined as

structure in Figure 4.2.1(a).

Silicon

Oxide

Gate

Substrate

BOX

Substrate

BOX

Silicon

Oxide

Gate

(a) (b)

A=19nm x12nm

A=(pi/2)x(9.5nm)2

Figure 4.2.1: Structure of a) Tri-gate transistor b) Silicon Nanowire Tri-gate

transistor

An early assumption was observed where silicon nanowire tri-gate has

better electrical properties compared to tri-gate in term of off-state current trend.

On state current degradation facing by this device is not considerably high

compared to off-state current, thus, off-state current achievement is much

preferable to discuss in this analysis. From simulated result, off state current for

structure in Figure 4.2.1 (b) is much lower compared to standard structure

respectively with IOFF =9 μA and IOFF = 11μA .A significant reduction on off state

49

current is suspected contributed by the nature of structure that replicate as gate all

around but in semi-cylindrical form that offers better electrostatic control (electric

field) over the channel by the gate. Using this structure, off-state current could be

reduced by up to 50%. Originally, the trapped charge at the edge of corner in

standard tri-gate could contribute to a high leakage current during off-state

condition (M. P. Kumar, et al) and also known as corner effect. Corner effect is

believed to happen when the electric field line is not uniform and caused the

trapped charge at the corner (A. Godoy, et al). This problem can be minimized by

introducing the proposed structure in Figure 4.1(b). The rounding structure make

the uniform electrons distribution on the channel easily can be controlled by the

gate during the switching off period, which indicates a good controlled over the

electric field since the electric field line is uniform in this structure. Thus, it make

the device has smaller leakage current compared to tri-gate. In addition, even

though the channel for both structure were applied with heavily doped, but this

condition is seem to give more benefit on proposed structure. It is because the area

involved in fabricating for suggested structure is smaller than standard tri-gate,

thus cost of production be able to reduce efficiently.

Figure 4.2.2: I-V curve Silicon Nanowire Tri-gate designed and reference Tri-

gate (Gate length, Lg = 26nm; Vds = Vgs = 1V)

50

4.4.2 SNWTT with two different insulator layers

(a) (b)

Figure 4.3.1: (a) Silicon Nanowire Tri-gate Transistor with oxide layer structure,

(b) Silicon Nanowire Tri-gate Transistor with high-k (HfO2) layer structure

High-κ dielectrics are used in semiconductor manufacturing processes where they

are usually used to replace a silicon dioxide gate dielectric or another dielectric

layer of a device. The implementation of high-κ gate dielectrics is one of several

strategies developed to allow further miniaturization of microelectronic

components.

HfO2

layer

SiO2

layer

51

Figure 4.3.2: I-V curve for undoped high-k (HfO2) layer and undoped oxide layer

As can be seen in Graph 2, the two curves are noticeably different. I-V curve of

undoped high-k layer shows significantly lower leakage current as compared to

undoped oxide. The difference occurs due to the thickness of capacitor layer of

insulator. Since, HfO2 layer is thicker than SiO2, thus, leakage current HfO2 is

smaller. According to (Moshe Eizenberg, 2012) ,when the transistor size shrink,

thickness of SiO2 is reduced and will contributing in significant increase of leakage

current. These finding is supported with the publish work where high-k dielectric

has low leakage current, low loss factor and substantially higher permittivity than

SiO2.

52

4.4.3 Channel radius variation

(a) (b)

Figure 4.4.1: (a) SNWTT structure with 9nm radius, (b) SNWTT structure with

11nm radius

According to I-V curve in Figure 4.4.2, the positive impact of decrement

of radius of channel can be notified when on state current of devices almost remain

constant, but the desire outcome with lower leakage current can be achieved that

trade off with small declination of carrier mobility. The width of channel is defined

as two times of radius. As the radius scale down, the height of channel also

decreased and makes the gate control over the channel become more dominant by

lowering their off state current(Ru Huang et al,2011 ).Volume inversion could be

the best explanation regarding the relationship between leakage current and radius

effect. A larger radius induced a larger volume inversion. However, as the radius

increased, the gate control over the channel also affected and indicated by

increment of leakage current. Channel with larger radius make the position of

volume inversion is far away from the gate and located at the middle of the

channel. But, the case is different for the channel with smaller radius where the

location of volume inversion is nearer to top gate surface. As the volume inversion

is located nearer to the top gate, a leakage current could be improved better by

having a smaller of radius of channel. A small leakage current is much preferred to

make the device applicable as low power devices since less power loss during

switching period.

53

Figure 4.4.2: I-V curve for SNWTT with various channel radiuses

The threshold voltage is decreasing as radius of channel increase as shown in

Figure 4.4.3. The reason threshold decrease can be understood as a consequence of

charge neutrality: the Yau charge-sharing model. The combined charge in

the depletion region, device and in the channel are balanced by three electrode

charges: the gate, the source and the drain. As drain voltage is increased,

the depletion region of the p-n junction between the drain and body increases in

size and extends under the gate, so the drain assumes a greater portion of the

burden of balancing depletion region charge, leaving a smaller burden for the gate.

As a result, the charge present on the gate retains charge balance by attracting

more carriers into the channel, an effect equivalent to lowering the threshold

voltage of the device.

54

Radius of channel,R (nm)

Th

resh

old

vo

lta

ge

,Vth

(V)

141312111098765 10 15

0.65

0.7

0.75

0.8LG=26nm

tox=1.5nm

Figure 4.4.3 Graph of threshold voltage, Vth against radius of channel of

SNWTT

According to Figure 4.4.4 it shows that drain induced barrier lowering (DIBL);

a short-channel effect or referred as reduction in threshold voltage of

the transistor at high drain voltages against radius of channel. It can be deduced

that DIBL is directly proportional to radius of channel because the source and

drain form p-n junctions with the body, and so have associated built-in depletion

layers associated with them that become significant partners in charge balance at

short channel lengths, even with no reverse bias applied to increase depletion

widths. Besides, long channel is electrostatically shielded from the drain by the

combination of the substrate and gate. While for short-channel devices the drain

is close enough to gate the channel, and so a high drain voltage and turn on the

transistor prematurely.

.

55

Radius of channel, R (nm)

DIB

L (

V/V

)

1413121198765 10 150.4

0.5

0.6

LG=26nm

tox=1.5nm

Figure 4.4.4 DIBL against radius of channel of SNWTT

4.4.4 Temperature effect on SNWTT performance

0 0.2 0.4 0.6 0.8 110

-6

10-4

10-2

T=500K

T=400K

T=350K

T=300K

LG=65nm Nd= 1x1017

cm-3

tox=3nm

Dra

in C

urre

nt, I

D (A

/um

)

Gate Voltage, VG (V)

Figure 4.5: I-V curve incorporating with SNWTTs for different temperature.

56

Figure 4.5 presents the sensitivity of temperature effect on device

performance. Initially, when the temperature increased to 400K, the on-state

current and off state current is not much affected. However, degradation on state

current was notable when the temperature increased to 500K. Decrement of on-

state current is believed associated with the dependent of mobility of electrons on

the heat at the channel with higher temperature. As the temperature increased over

400K, energy posses by the sea of electrons started to reduced with temperature

due to mobility limited by phonon emission. This emission make the electron

scattered and reduced their mobility (F. Wessely, et al, 2012). On state current is

contributed by the carrier concentration at the conduction band, where the energy

dependent on mobility of electrons. Mobility decrement make the behavior of

doped channel become less extrinsic and caused the percentage amount of carrier

concentration moving to the conduction band decreased and affected the on-current

performance (D. A.Neamen,2003).

Nevertheless, this trend still can be accepted as robustness device since

their off-state current remain same and on-state current slightly shifted downward.

These criteria also imply that the lifetime of devices could be keep further.

Furthermore, normally the device will expose to high temperature when they are

combined into more than one device to work as electronic system.

4.4.5 Doping concentration effects

An analysis of different uniform body doping: 1011

cm-3

, 1015

cm-3

and

1018

cm-3

of 22 nm channel length for SNWTT structure with high-k (HfO2)

insulator has been done successfully. The SNWTT structure has suppressed short

channel effect without the need to reduce the junction depth. A reduction of

leakage current was obtained without altering the drive current.

57

Besides, the threshold voltage is increase accordingly with increasing

body doping. Thus, the incorporation of SNWTT structure will enhance the

electrical performance and give a good control of the SCE for scaling the

MOSFET in nanometer regime for future development of nanoelectronics devices.

Figure 4.6: I-V curve for doped high-k metal (HfO2) with different

doping concentration, Na

Figure 4.6 shows the current-voltage (IDS – VGS) characteristics and

subthreshold curves for MOSFET device of channel length Lg = 22 nm with

uniform boron doping of 1011

cm-3

, 1015

cm-3

and 1018

cm-3

taken at VDS = 0.1 V.

In the off-state operation mode the transistor showed a drain leakage current IOFF

which is independent of the gate voltage, but increases with decreasing body

doping concentration as depicted in Figure 4.6. With low body doping, the carrier

mobility can be increased [45] meanwhile higher substrate doping density reduces

the mobility and the extension of the source and drain depletion layers into the

channel [9]. Low body doping concentration was used instead of high body

concentration because the carrier mobility can be increased and in the same time

the extension of depletion layers can be reduced. In addition, it is obvious that the

off-state leakage current reduced to 2 x 10-8

A/µm, 4 x 10-8

A/µm and 12 x 10-9

58

A/µm for body doping of 1011

cm-3

, 1015

cm-3

and 1018

cm-3

. A slight different on

drive current, ION is obtained for all body doping concentration.

4.5 Summary

In this chapter, SNWTT structure analysis and comparison to reference model

structure, some manipulation parameter such variation of doping level , variation of

channel radius , variation of temperature and variation of asymmetry mobility was

presented by numerical simulation. The analysis includes the IDS versus VGS

curves, transfer and output characteristics, threshold voltage roll-off, and off-state

leakage current and DIBL Key results are: (i) to optimize the fabrication process

using process simulation, 3D Sentaurus TCAD tool allow better IDS versus VGS

performance.

CHAPTER 5

CONCLUSION AND RECOMMENDATIONS

5.1 Conclusion

Silicon nanowire tri-gate transistor with high-k (HfO2) insulator device

has been designed, fabricated and investigated the characterization with

comparison with standard tri-gate structure. It has shows the advantages especially

to suppress corner effect, short channel effect such as allowing better VT control

depends on reduction of VT roll-off, reduction of IOFF and improve ION/IOFF ratio

Current-voltage characteristics for both IDS - VGS and IDS - VDS curve illustrated the

electrical behavior of designed silicon nanowire tri-gate structure. It was also

found that the proposed structure plays a role in determining the effective threshold

voltage, subthreshold swing, on and off current and drain induced barrier lowering.

As channel shaped of SNWTT is semi-cylindrical, it reduced corner effect that are

caused by accumulated electron at the corner of standard tri-gate structure (square

in shape) besides reducing the current leakage.

60

In order to optimize the performance of silicon nanowire tri-gate

transistor with high-k (HfO2) insulator, a few different approaches have been

investigated which were scaling of dielectric (applied HfO2 as dielectric instead of

SiO2), body doping concentration, different channel radius, and temperature effect

on performance. In the beginning, two different structure of transistor: tri-gate

structure and silicon nanowire tri-gate were constructed to shows proposed modal

has better performance. Then, silicon nanowire structure with two different

dielectric layers: oxide and high-k were modeled. Silicon nanowire tri-gate

transistor with high-k insulator has better performance especially in reduction of

IOFF and increased the ION/IOFF ratio. An analysis of three different uniform body

doping concentration: 1011

cm-3

,1015

cm-3

, 1018

cm-3

of SNWTT was shown the

increasing in magnitude of VT with increasing the body doping concentration. An

optimum body doping concentration of 1 x 1018

cm-3

was selected due to the

capability to improve the VT roll-off and reduce the DIBL effect. Lower value of

VT was obtained due to lower body or channel doping of 1018

cm-3

and high S/D

doping of 1020

cm-3

. Thus, the channel was created with the small value of VGS.

IOFF was decreased with an increasing body doping concentration meanwhile drain

current was increased with decreasing body doping concentration. While, analyze

of thermal effect on devices performance shows that when temperature is raised

above 400K, the device performance is reduced: increased in leakage current.

Therefore, the suitable temperature for the device to function optimally is at 300K

or below 400K.

A simulation study of Silicon Nanowire Tri-gate Transistor is presented

in this dissertation. This type of device has advantages Tri-gate transistor such as

less corner effect, reduction in leakage current through channel, and high drive

current. The current-voltage characteristics showed that for wider pillars the

threshold voltage, IOFF With the results obtained in simulating the transistor, DP-

MOSFET device showed a possibility to give a very good control of the SCE for

scaling the MOSFET in nanometer regime for future development of

nanoelectronics device.

61

Compare to other researchers, our contribution to do this research were:

(i) Using latest TCAD tool, Sentaurus to model silicon nanowire tri-gate

transistor in three-dimensional (3D)

(ii) The structure was develop based on ideal structure of silicon nanowire,

Gate-All-Around (GAA)

(iii) Introducing high-k (HfO2) as nanowire insulator

(iv) Optimization of silicon nanowire tri-gate structure; channel length =

22nm, doping concentration, radius of channel, and temperature

(v) Analysis on device performance based on parameter variation such

doping concentration, threshold voltage, on and off current, threshold

voltage roll-off, drain induced barrier lowering and ION/IOFF ratio.

For information, this research has been carried out on a simulation basis.

Technology computer-aided design (TCAD) is an important tool to simulate the

actual wafer fabrication process and device characterization. However, it is better

if there is facility to carry out the real fabrication process for better comparison

with the simulated results.

5.2 Suggestions for Future Work

In this dissertation, the feasibility of a silicon nanowire tri-gate transistor

with high-k insulator is demonstrated. Since the proposed device has a lot of

advantages, further utilize of the devices should be carried on.

62

Suggestions for future studies are as follows:

• The modeling data can be compared to either real fabricated structured or

simulation data. The parameters from this modeling can be used to

analyst in circuit performance. Thus, SNWTT structure can be used at

circuit level modeling.

• SNWTT fabrication process: Real fabrication MOSFET is an actual

structure to be investigated. However, it needs a facility such as clean

room lab which is expensive. The results from fabrication can be

compared with simulation. The simulation for SNWTT is almost done

and the process and device simulation data can be use to fabricate it.

• Novel device structures: It is important to continue to study the effects of

scaling down the channel length on the characteristics of the device in

order to optimize their performance. Therefore, many theoretical devices

structures and the use of new materials are proposed to extend future

scaling of MOSFET in future. Recently, vertical MOSFET become more

popular topic to be investigated. This is because of its performance and

many advantages over the conventional planar MOSFET. The channel

length can be reduced more easily using this structure. There are silicon-

based vertical MOSFETs and other alternative structure or using new

materials. Other new structures are nano-scroll, nano-ribbon and other

new materials such as grapheme.

63

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