# Introduction

arbon Nanotubes are sheets of graphite rolled in the shape of a tube. Depending on chirality they can be either metallic or semiconducting. Carbon Nanotubes were discovered by Iijima at the NEC Fundamental Research Laboratory while he used a high resolution transmission electron microscope (TEM) to observe byproducts of carbon which had been generated by an arc between two carbon electrodes (Iijima, 1991). After that momentous development has been achieved by understanding the characteristics and searching possible applications of these on semiconductor technology. They have high elastic modulus, small weight and are predicted to be the strongest fibers. Carbon Nanotube's strength and flexibility are their unique properties. The fascinating electronic properties of them depend drastically on both the diameter and the chirality of the hexagonal carbon lattice along the tube (Mintmire et al., 1992;Hamada et al., 1992;Saito et al., 1992). Because of its excellent conductivity and high dielectric properties, CNTs play a vital role in different nano electronic devices such as transistors, digital logic devices, memory components, etc (Heinze et al., 2002).

The fundamental strategy for improving the performance of VLSIs is scaling down of electronic devices. According to the ITRS the gate length of MOSFETs will be less than 16 nm in 2016 (ITRS, 2003). If this continues then the MOSFETs will reach its limiting size very soon. Thus the semiconductor industry is searching for different materials to integrate with the current silicon-based technology and in the long run, possibly replace it if required. In this regard the carbon nanotube field effect transistor (CNTFET) will be the most promising alternatives for its unique properties. It was demonstrated long before in 1998 (Tans et al., 1998). Carbon nanotube field-effect transistors offer high mobility for ballistic transport, high mechanical and thermal stability with high resistance to electro migration, attracting strong interest as alternative high device technologies for the future nano electronics applications (Avouris et al., 2007). Recently, a carbon nanotube transistor, which integrates ultra-short channel, thin high-k top gate insulator and excellent Pd source-drain contact is demonstrated using a self-align technique (Javey et al., 2008).

This paper proposes CNTFET with ZrO 2 as gate oxide which is also one of the most promising devices. This paper has been devised into main two sections. In the first section, the mobility of CNTs has been discussed with analyzing the Density of State (DOS) of different types of nanotubes and in the second part, the proposed CNTFET device modeling has been described with its parameters, along with simulation results.


# II.


# Carbon Nanotube

Carbon is an element with symbol C. Its atomic number is 6 (1s 2 2s 2 2p 2 ). Carbon is a group 14 element that resides above silicon on the periodic table. It is nonmetallic and tetravalent making four electrons available to form covalent chemical bonds. Carbon has four electrons in its valance shell like silicon (1s 2 2s 2 2p 6 3s 2 3p 2 ) and germanium (1s 2 2s 2 2p 6 3s 2 3p 6 3d 10 4s 2 4p 2 ). There are several allotropes of carbon like graphite, diamond and amorphous carbon (Carbon materials research group, University of Kentucky). When carbon atoms are arranged in crystalline structures composed of benzene like rings, they form several allotropes that contain totally exceptional electronic properties.

The physical properties of carbon vary widely with the allotropic form (List of thermal conductivities, Wikipedia). Diamond, carbon nanotubes and graphene have the highest thermal conductivity of all known materials (e.g., diamond: 900-2300 Wm ?1 K ?1 , carbon nanotube: 3180-3500 Wm ?1 K ?1 ) (Faisal and Ali, 2015) under normal conditions.

Carbon Nanotubes (CNTs) are an allotrope of carbon. Carbon nanotubes have many forms, differing in length, thickness and in the type of helicity and number of layers. It can be categorized into Single Walled Carbon Nanotube (SWCNT) and Multi Walled Carbon Nanotube (MWCNT) shown in Fig. 1 and 2. The carbon nanotubes have diameters from less than 1nm to 50 nm. These possess excellent mechanical and transport properties too.

The rolled graphene (CNT) can be explained by a coordinate of indices (n, m), which is known as Chiral Vector. It represents whether CNT is metallic or semiconducting and diameter of CNT. The table shown below describes "Chirality of carbon nanotube. The diameter of carbon nanotube is given by:    IV.


# Modelling of Cntfet

The proposed device is formed with a (10, 0) CNT. So the channel diameter =0.782885nm. For gate insulation ZrO 2 (k = 25) is used. Energy gap for a nanotube is given by:
2 c-c a? Eg = channel diameter(2)
Where: ? = The nearest neighbor-hopping parameter (? = 2.5-3.2) Using ? = 3, the energy gap is 1.0882eV. The parameters used in proposed model and calculations are given in Table 3. Conductance between two leads source and drain is defined in terms of current and voltage: I = GV. Using Landauer formula (Nazarov and Blanter, 2009), conductance is expressed by the following equations:


# Global
2 2Te G = h (3)
where, q is the charge of electron and h is the Planck's constant. T is known as the transmission function in terms of energy that represents the probability of an electron injected at one end of a conductor will emit at the other end. T can be expressed as:
r a S 0 D 0 T = trace T G Î?" G ? ? ? ?(4)
G 0 r G 0 a represents the retarded and advanced Green's function of the nanotube and Ð?" D , Ð?" S are the coupling of the CNT to the source and the drain. The retarded Green's function is calculated by: ( )
-1 r 0 S D G = EI - ? --? ? (5)
where, E is Fermi energy, I is the identity matrix, H is the Hamiltonian of the nanotube. ?S, ?D is the self-energy terms at the source and drain coupling of the contacts are the calculated using the broadening function of the self-energy terms at the source and drain. The nanotube behaves as the conducting channel in the CNTFET from the source to drain; it depends on the current density of the tube. The current density is a measure of the density of flow of an electric current per unit area across a section. The current density is an area density described by J. The current through an area A is simply the flux of the current density through that area as shown below: ? I = J.dA (6) Using the charge density within the device, the NEGF transport equation is solved teratively with the posison equation until self-consistant potential distribution is found. Finally the current is calculated using the Landauer Böuttiker expression:
( ) ( ) ( ) s d d 4d T E f E -f E dE I = h ? ? ? ? ?(7)
T is the transmission probability across the source/drain; f S and f D are the source/drain Fermi-Dirac distribution functions consistent potential; The equation is solved simultaneously to evaluate and characterize the performance of these devices.

V.


# Simulations

Hafnia (HfO 2 ) adopts the same structure as zirconia (ZrO 2 , K=~25). Unlike TiO 2 (k = 40), which features six-coordinate Titanium in all phases, zirconia and HfO 2 consists of seven-coordinate metal centers (Miikkulainen et al., 2013;Faisal and Ali, 2012). Hafnium-based oxides were introduced by Intel in 2007 as a replacement for silicon oxide as a gate insulator in field-effect transistors (Source: INTEL). We simulate the I-V Characteristics of CNTFET using ZrO 2 as gate insulator for proposed model. The high-K gate insulator and bigger CNT diameter allows higher drain current.

Figure 7 shows the output characteristics of the proposed CNTFET. The channel allows the current to flow when the gate voltage is greater than 0.3 V. So the on current is 70 ?A at Vg = 2.0 V and Vd = 1.0 V and the off current is 6.61e-05 ?A at Vg = 0V and Vd = 1.0 V.


# Material

Young's modulus (GPa) Tensile strength (GPa) Electrical conductivity (mho/m)  In order to achieve a relatively large transconductance the CNT must have large channel diameter. The larger the transconductance, the greater the gain it will deliver. As the diameter gets smaller this reduces the carrier mobility, changing the transconductance. The transconductance behavior is obtained at 0.78 nm diameter, with different drain voltage (Fig. 8). The transconductance varies by a factor of 10/V depending on the amount of voltage applied to the gate. However, the increase of VG will reduce the allowed voltage signal through the drain. Quantum capacitance is associated with the properties of channel material. As the density of state is finite in a semiconductor quantum well, the Fermi level needs to move up above the conduction band edge as the charge in the quantum well increases. This movement of Fermi level requires energy and this conceptually corresponds to quantum capacitance. Figure 9 shows the quantum capacitance versus the gate voltage at different drain voltages. It is clear that a higher quantum capacitance can be found at a gate voltage 0.42 or 0.57 volt (for proposed model).


# Fig. 11: Mobile charge behavior at drain voltage

As insulator thickness approaches the nanometer range, the insulator capacitance becomes comparable to the inversion layer capacitance, which means that the QC and the centroid capacitance start to affect the gate capacitance.

Figure 10 shows the mobile charge behavior as a function of gate voltage. It is noticed that increasing the drain voltage beyond a specific value has no longer an effect on the shape of the curves since the mobile charge remains constant. It is also observed that low drain voltage produces higher mobile charge and high drain voltage produces lower mobile charge. Also, it has been noticed that the mobile charge increases with the reduction in gate insulator thickness. Figure 11 shows the mobile charge behavior as a function of drain voltage.


# VI.


# Conclusion

The proposed parameters and gate dielectric of CNTFET make the transistor a challenge to develop and control the aspects of it such maximum transconductance. We found two regions for maximum transconductance. Zirconia is used in optical coatings and in DRAM capacitors as a high-k dielectric and in advanced metal-oxide semiconductor devices. The advantage for proposed CNTFET is its high dielectric constant: The dielectric constant of ZrO 2 is 4-6 times higher than that of SiO 2 . In recent years, zirconium oxide (as well as doped and oxygen-deficient zirconium oxide) attracts additional interest as a possible candidate for resistive-switching memories (Lin, 2011).

VII.
![Performance Analysis of Enhanced Carbon Nanotube Field Effect Transistor (CNTFET) using Zirconia as](image-2.png "F")
![c = 0.142 nm is the carbon-carbon bond length Figure3and 4 shows the Density of State (DOS) of different types of nanotubes. The simulated end states are within the energy gap of semiconducting carbon nanotubes, implying that the end states are a 1-D analogy with conventional surface states. Since the band gaps of carbon nanotubes are small, CNTs are either metallic or semi conductive. The energy band structures of carbon atom provide an occupied energy level in the band gap depending upon the density of states and types of CNT. The (10, 0) nanotube acts as semi conducting material since it has energy gap between conduction and valence band whereas the (8, 8) nanotube acts as conducting material as the valance and conduction bands are overlapping.](image-3.png "")
12![Fig. 1: Single walled carbon nanotube](image-4.png "Fig. 1 :Fig. 2 :")
3![Fig. 3: DOS vs. Energy for(8,8) ](image-5.png "Fig. 3 :")
5![Fig. 5: Planner CNTFET](image-6.png "Fig. 5 :")
78![Fig. 7: Id vs. Vd (Output characteristics) curve at different Vg](image-7.png "Fig. 7 :Fig. 8 :")
910![Fig. 9: Quantum capacitance vs. Gate voltage](image-8.png "Fig. 9 :Fig. 10 :")
1Performance Analysis of Enhanced Carbon Nanotube Field Effect Transistor (CNTFET) using Zirconia asGate DielectricYear 201752II Version IJournal of Researches in Engineering ( ) Volume XVII Issue F
2
3Energy gap1.0882 eVGate oxide thickness1.6 nmCNT diameter0.78 nmGate dielectric (ZrO2)25
			© 2017 Global Journals Inc. (US)
		
		

			

## Acknowledgement

The authors' would like to thank Dr. M. Tanseer Ali for his remarks and invaluable advises on different aspects of this work.

			

			

## Funding Information

The authors have no support or funding to report.


## Ethics

The authors' hereby declare, this work is their own contribution and hence there would not be any ethical issues related to this manuscript.


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* 
	
		Carbon-based electronics
		
			PAvouris
		
		
			ZChen
		
		
			VPerebeinos
		
		10.1038/nnano.2007.300
	
	
		Nature Nanotechnol
		
			2
			
			2007
		
	




* 
	
		Electron transport in very clean, as-grown suspended carbon nanotubes
		
			JQCao
		
		
			HWang
		
		
			Dai
		
		10.1038/nmat1478
	
	
		Nature Mater
		
			4
			
			2005
		
	




* 
	
		Externally assembled gate-all-around carbon nanotube field-effect transistor
		
			ZChen
		
		
			DFarmer
		
		
			SXu
		
		
			RGordon
		
		
			PAvouris
		
		10.1109/LED.2007.914069
	
	
		IEEE Electron Device Lett
		
			29
			
			2008
		
	




* 
	
		Simulations of enhanced CNTFET with HfO 2 gate dielectric
		
			AMFaisal
		
		
			TAli
		
	
	
		Int. J. Sci. Res. Public
		
			5
			
			2015
		
	




* 
	
		Atomic layer deposition on suspended single-walled carbon nanotubes via gas-phase noncovalent functionalization
		
			DBFarmer
		
		
			RGGordon
		
		10.1021/nl052453d
	
	
		Nano Lett
		
			6
			
			2006
		
	




* 
	
		New one-dimensional conductors: Graphitic microtubules
		
			NHamada
		
		
			SISawada
		
		
			AOshiyama
		
		10.1103/PhysRevLett.68.1579
	
	
		Phys. Rev. Lett
		
			68
			
			1992
		
	




* 
	
		Carbon nanotubes as schottky barrier transistors
		
			SHeinze
		
		
			JTersoff
		
		
			RMartel
		
		
			VDerycke
		
		10.1103/PhysRevLett.89.106801
	
	
		Phy. Rev. Lett
		
			89
			
			2002
		
	




* 
	
		Helical microtubules of graphitic carbon
		
			SIijima
		
		10.1038/354056a0
	
	
		Nature
		
			354
			
			1991
		
	




* 
	
		International Technology Roadmap for Semiconductors
		
			2003
			646
		
	
	1st Edn., ITRS, Austin




* 
	
		Ballistic carbon nanotube field-effect transistors
		
			AJavey
		
		
			JGuo
		
		
			QWang
		
		
			MLundstrom
		
		
			HJDai
		
		10.1038/nature01797
	
	
		Nature
		
			424
			
			2003
		
	




* 
	
		Electrode dependence of filament formation in HfO 2 resistive-switching memory
		
			KLLin
		
		DOI: 10.1063/- 1.3567915
	
	
		J. Applied Phys
		
			109
			
			2011
		
	
	List of thermal conductivities




* 
	
		Crystallinity of inorganic films grown by atomic layer deposition: Overview and general trends
		
			VMiikkulainen
		
		
			MLeskelä
		
		
			MRitala
		
		
			RLPuurunen
		
		10.1063/1.4757907
	
	
		J. Applied Phys
		
			113
			
			2013
		
	




* 
	
		Are fullerene tubules metallic
		
			JWMintmire
		
		
			BIDunlap
		
		
			CTWhite
		
		10.1103/PhysRevLett.68.631
	
	
		Phys. Rev. Lett
		
			68
			
			1992
		
	




* 
	
		Quantum transport: Introduction to Nanoscience. 1st Edn
		
			YVNazarov
		
		
			YMBlanter
		
		
			2009
			Cambridge University Press
			581
			Cambridge
		
	




* 
	
		Simulation of carbon nanotube field effect transistors
		
			RSahoo
		
		
			RRMishra
		
	
	
		Int. J. Electronic Eng. Res
		
			1
			
			2009
		
	




* 
	
		Physical Properties of Carbon Nanotubes
		
			RSaito
		
		
			GDresselhaus
		
		
			MSDresselhau
		
		
			1998
			Imperial College Press
			259
			London
		
	
	2nd Edn.




* 
	
		Electronic structure of chiral graphene tubules
		
			RSaito
		
		
			MFujita
		
		
			GDresselhaus
		
		
			MSDresselhaus
		
		10.1063/1.107080
	
	
		Applied Phys. Lett
		
			60
			
			1992
		
	




* 
	
		Room-temperature transistor based on a single carbon nanotube
		
			SJTans
		
		
			AR MVerschueren
		
		
			CDekker
		
		10.1038/29954
	
	
		Nature
		
			393
			
			1998
		
	




* 
	
		Vertical scaling of carbon nanotube field-effect transistors using top gate electrodes
		
			SJWind
		
		
			JAppenzeller
		
		
			RMartel
		
		
			VDerycke
		
		
			PAvouris
		
		10.1063/1.1480877
	
	
		Applied Phys. Lett
		
			80
			
			2002