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MAHAVEER INSTITUTE OF SCIENCE & TECHNOLOGY(Affiliated to JNTUH Hyderabad and Approved by AICTE)
Vyasapuri, Bandlaguda, Post: KesavagiriHyderabad – 500 005
CERTIFICATE
This is to certify that the Technical Seminar titled “GRAPHENE TRANSISTOR” is
submitted by
C. Sai Kalyan Ram[07E31A0414]
in partial fulfilment for the award of the degree of bachelor of technology in Electronics and
Communication Engineering to the Jawaharlal Nehru Technological University-Hyderabad
during the academic year 2010-2011 is a record of bonafide work carried out under our
supervision
Project Guide Project Coordinator HODMr. D. Sunil Kumar Prof. V. Venkata Narayana Dr B. Visvesvara RaoB.E,M.TECH M.E, P.G.D, M.S.M, F.I.ETE, BE, M.Tech, PhDM.I.S.T.E MISTE, MSEMC (I). Proffesor,Dept. of ECEAsst. Professor Professor,Dept.of ECE (MIST)
(MIST)
ABSTRACT
In modern age Engineers have paved the way for a new generation of faster, more
powerful cell phones, computers and other electronics by developing a practical technique to
replace silicon with carbon on large surface. The capability of silicon, the material at the
heart of computer chips has been harnessed beyond its limits by engineers and carbon has
come up as an integrating replacement for the same.
The material called “Graphene” which is a single layer of atoms arranged in
honeycomb lattice could let electronics to process information and produce radio
transmission many times better than silicon based devices such as transistors. Graphene is a
rapidly rising star on the horizon of materials science and condensed matter physics. This
strictly two-dimensional material exhibits exceptionally high crystal and electronic quality
and, despite its short history, has already revealed a cornucopia of new physics and potential
applications, one of which is a Graphene Transistor briefly discussed here.
Graphene Transistor is a single-electron transistor, which means that a single electron
passes through it at any one time. Graphene transistors could scale to transistor channels as
small as two manometers (nm) with terahertz speeds. More generally, Graphene represents a
conceptually new class of materials that are only one atom thick and, on this basis, offers new
inroads into low-dimensional physics that has never ceased to surprise and continues to
provide a fertile ground for applications.
CHAPTER 1
INTRODUCTION
Graphene is the name given to a flat monolayer of carbon atoms tightly packed into a
two-dimensional (2D) honeycomb lattice, and is a basic building block for graphitic materials
of all other dimensionalities (Figure 1). It can be wrapped up into 0D fullerenes, rolled into
1D nanotubes or stacked into 3D graphite. Theoretically, Graphene (or “2D graphite”) has
been studied for sixty years and widely used for describing properties of various carbon-
based materials. Forty years later, it was realized that Graphene also provides an excellent
condensed-matter analogue of (2+1)-dimensional quantum electrodynamics, which propelled
Graphene into a thriving theoretical toy model. On the other hand, although known as integral
part of 3D materials, Graphene was presumed not to exist in the Free State, being described
as an “academic” material and believed to be unstable with respect to the formation of curved
structures such as soot, fullerenes and nanotubes. All of a sudden, the vintage model turned
into reality, when free-standing Graphene was unexpectedly found and, especially, when the
follow-up experiments confirmed that its charge carriers were indeed massless Dirac
fermions. So, the Graphene “gold rush” has begun.
1.1 BRIEF HISTORY OF GRAPHENE
More than 70 years ago, Landau and Peierls argued that strictly two-dimensional (2D)
crystals were thermodynamically unstable and could not exist. Their theory pointed out that a
divergent contribution of thermal fluctuations in low-dimensional crystal lattices should lead
to such displacements of atoms that they become comparable to interatomic distances at any
finite temperature. The argument was later extended by Mermin and is strongly supported by
a whole omnibus of experimental observations. Indeed, the melting temperature of thin films
rapidly decreases with decreasing thickness, and they become unstable (segregate into islands
or decompose) at a thickness of, typically, dozens of atomic layers. For this reason, atomic
monolayers have so far been known only as an integral part of larger 3D structures, usually
grown epitaxial on top of monocrystals with matching crystal lattices. Without such a 3D
base, 2D materials were presumed not to exist until 2004, when the common wisdom was
flaunted by the experimental discovery of Graphene and other free-standing 2D atomic
crystals (for example, single-layer boron nitride and half-layer BSCCO). These crystals could
be obtained on top of non-crystalline substrates, in liquid suspension, and as suspended
membranes. Importantly, the 2D crystals were found not only to be continuous but to exhibit
high crystal quality. The latter is most obvious for the case of Graphene, in which charge
carriers can travel thousands interatomic distances without scattering. With the benefit of
hindsight, the existence of such one-atom-thick crystals can be reconciled with theory.
Indeed, it can be argued that the obtained 2D crystallites are quenched in a metastable state
because they are extracted from 3D materials, whereas their small size (<<1mm) and strong
interatomic bonds assure that thermal fluctuations cannot lead to the generation of
dislocations or other crystal defects even at elevated temperature
A complementary viewpoint is that the extracted 2D crystals become intrinsically
stable by gentle crumpling in the third dimension on a lateral scale of 10nm. Such 3D
warping observed experimentally leads to again in elastic energy but suppresses thermal
vibrations (anomalously large in 2D), which above a certain temperature can minimize the
total free energy.
1.2 Discovery of Graphene
Graphene, though only recently confirmed experimentally, has been discussed in
conjunction with graphite for many years. Many of its properties had long been studied in
conjunction with the properties of graphite, including its band structure. For example,
graphene was predicted to be a semiconductor with no band gap at the corners of the
reciprocal lattice using the tight-binding approximation. But theoretical studies of graphene
were historically limited entirely to approximations for the properties of graphite. Graphene
as a free substance was largely ignored as a purely academic substance because it was
accepted that thermodynamic stresses prevented the existence of any free one- or two-
dimensional crystals. Additionally, there had been previous attempts to achieve two-
dimensional crystals, but in all cases, it was confirmed that reducing the thickness made the
crystals melt at increasingly low temperatures and it was agreed that two dimensional crystals
were too unstable to exist in a free state. A possible explanation for the disparity between
theory predicting the non-existence of two-dimensional crystals and their experimental
confirmation may be that the graphene monolayers are only approximately two-dimensional
and owe some of their stability to rippling perpendicular to the plane.
Fig 1.1
A representation of the rippling of 2D graphene into 3D. The red arrows are ~800nm long.
But in 2004, graphene was produced experimentally, defying decades of predictions
that it could not exist apart from a crystalline substrate. The procedure for acquiring the
monolayer graphene is comically simple: essentially, graphene is removed from a graphite
sample by using clear adhesive tape to remove layers from graphite. The tape is then stuck to
new clean tape several times to remove additional layers. After a few times, the tape is
dissolved and the graphite remains are examined to sort the graphene mono layers from the
ultrathin graphite films. The difficulty is in sorting the graphene from the graphite.
Fortunately, different thicknesses of graphite are distinguishable under optical microscopy on
a special silicon substrate. The adhesive tape technique produces extremely high quality
crystals of up to 100 micrometers in length, more than sufficient for most laboratory
experiments. And even better, the raw materials are very cheap.
1.3 Graphene’s Electrical Properties
Before viewing about Graphene Transistors, it is useful to define what 2D crystals are
and their relevance to Graphene’s electrical properties. Obviously, a single atomic plane is a
2D crystal, whereas 100 layers should be considered as a thin film of a 3D material. For the
case of Graphene, the situation has recently become reasonably clear. It was shown that the
electronic structure rapidly evolves with the number of layers, approaching the 3D limit of
graphite already at 10 layers. Moreover, only Graphene and, to a good approximation, its
bilayer have simple electronic spectra: they are both zero-gap semiconductors (can also be
referred to as zero-overlap semimetals) with one type of electrons and one type of holes. For
3 and more layers, the spectra become increasingly complicated: Several charge carriers
appear, and the conduction and valence bands start notably overlapping. This allows one to
distinguish between single-, double- and few- (3 to <10) layer Graphene as three different
types of 2D crystals (“Graphene”). Thicker structures should be considered, to all intents and
purposes, as thin films of graphite. From the experimental point of view, such a definition is
also sensible. The screening length in graphite is only 5Å (that is, less than 2 layers in
thickness) and, hence, one must differentiate between the surface and the bulk even for films
as thin as 5 layers. Earlier attempts to isolate Graphene concentrated on chemical exfoliation.
To this end, bulk graphite was first intercalated (to stage I) so that Graphene planes became
separated by layers of intervening atoms or molecules.
This usually resulted in new 3D materials. However, in certain cases, large molecules
could be inserted between atomic planes, providing greater separation such that the resulting
compounds could be considered as isolated Graphene layers embedded in a 3D matrix.
Furthermore, one can often get rid of intercalating molecules in a chemical reaction to obtain
a sludge consisting of restacked and scrolled Graphene sheets. Because of its uncontrollable
character, graphitic sludge has so far attracted only limited interest. There have also been a
small number of attempts to grow Graphene. The same approach as generally used for growth
of carbon nanotubes so far allowed graphite films only thicker than 100 layers. On the other
hand, single- and few-layer Graphene have been grown epitaxial by chemical vapour
deposition of hydrocarbons on metal substrates and by thermal decomposition of SiC. Such
films were studied by surface science techniques, and their quality and continuity remained
unknown. Only lately, few-layer Graphene obtained on SiC was characterized with respect to
its electronic properties, revealing high-mobility charge carriers.
Because it can form single, double and triple bonds, it forms thousands of chemical
compounds, and has numerous elemental structures, or allotropes. The most common
allotropes of carbon are diamond and graphite. Diamond consists of carbon atoms single-
bonded to four other carbon atoms producing a tetrahedral crystal lattice. Its structure leads
to its extreme hardness and thermal conductivity, but diamond is a very poor electrical
conductor. In contrast, graphite consists of stacked layers of carbon sheets. Within an
individual carbon sheet, known as graphene, the carbon atoms are sp2 hybridized and form a
planar hexagonal lattice. The sp2 hybridization means that the carbons are -bonded in the
plane, but are also -bonded above and below the plane. Graphene thus possesses one of the
strongest bonds in nature and has a very high tensile strength. Graphene’s perpendicular p-
orbital lead to electron delocalization because there is no distinction between neighbouring
bonds, as indicated in Figure below.
Fig 1.2 Aromatic hydrocarbons like benzene shown here, share electrons in the p-orbital with many
neighbouring atoms.
This conjugated orbital system permits the electrons to travel freely above and
below the plane of carbon atoms with minimal scattering. Because of the minimal scattering
and strong delocalization of the electrons, graphite is a good conductor along the plane.
However, in graphite, electrostatic forces bind the layers together only very weakly, and
graphite is a very soft mineral. In addition, the other layers interfere with the behaviour of
the single sheets, even if not strongly. An ideal system would be to study free single-layer
graphene, but until a few years ago, two-dimensional systems like free graphene were
believed to be impossible.
In recent years, the two most familiar allotropes of carbon have been joined by a
number of newly discovered graphene-like materials. The first major graphene-related
substance discovered was C60, also known as buckminsterfullerene, buckyball, and fullerene,
a soccer-ball-like configuration of carbon atoms found in common lamp soot and known to
be very stable. Soon, the scientific community encountered similar fullerene-type carbon
structures called carbon nanotubes. Carbon nanotubes are needle-like tubes of rolled up
graphene sheets that exhibit many unusual and useful properties such as extreme tensile
strength and high conductivity. .
Epitaxial growth of Graphene offers probably the only viable route towards electronic
applications and, with so much at stake, a rapid progress in this direction is expected. The
approach that seems promising but has not been attempted yet is the use of the previously
demonstrated epistaxis on catalytic surfaces (such as Ni or Pt.) followed by the deposition of
an insulating support on top of Graphene and chemical removal of the primary metallic
substrate.
Fig 1.3 Mother of all graphitic forms.
“Graphene is a 2D building material for carbon materials of all other dimensionalities. It can
be wrapped up into 0D buckyballs, rolled into 1D nanotube or stacked into 3D graphite.”
In modern age Engineers have paved the way for a new generation of faster, more powerful
cell phones, computers and other electronics by developing a practical technique to replace
silicon with carbon on large surface.
The capability of silicon, the material at the heart of computer chips has been harnessed
beyond its limits by engineers and carbon has come up as an integrating replacement for the
same. The material called “Graphene” which is a single layer of atoms arranged in
honeycomb lattice could let electronics to process information and produce radio
transmission 10 times better than silicon based devices. The new technology through that
they needed “Graphene” material is the same as the silicon used to make chips-a single
crystal of material eight or twelve inches wide and the largest single crystal Graphene sheet
made have not been wider than a couple of millimetre, which is not enough for a single chip.
It is widely used to describe properties of many carbon based material, including graphite,
large fullerences, nanotubes etc. Planer Graphene itself has been presumed not to exist in the
Free State being unstable with respect to formation of curved structure.
CHAPTER 2
TRANSISTORS MADE OF GRAPHENE
A graphene transistor is a Nano scale device based on graphene, a component of
graphite with electronic properties far superior to those of silicon. The device is a single-
electron transistor, which means that a single electron passes through it at any one time. A
research team led by Professor Andre Geim of the Manchester Centre for Mesoscience
and Nanotechnology built a graphene transistor and described it in the March 2007 issue
of Nature magazine. Scientists have predicted that graphene transistors could scale to
transistor channels as small as two nanometres (nm) with terahertz speeds.
Before we go into the details of the working of Graphene based Transistors it is important for
us to look into the electrical properties of Graphene which is base material of the transistor.
2.1 Graphene’s charge carriers are relativistic
But why is there such interest in graphene? Aside from the obvious interest in the
novelty of a two-dimensional crystal, graphene crystals exhibit unusual electrical properties
that may prove useful both theoretically and practically. In particular, Graphene’s charge
carriers are very unusual in that they behave like mass less Dirac fermions and are most
effectively described by the Dirac equation rather than the non-relativistic Schrödinger
equation:
EN = [2ehc2 B(N+1/21/2)]1/2.
2.2 Anomalous Quantum Hall Effect in Graphene
In addition, graphene also exhibits an anomalous quantum hall effect. In classical
electromagnetism, the Hall effect arises when a magnetic field is applied perpendicular to the
surface of a solid carrying a current parallel to the surface. The Lorentz force causes positive
and negative charges to build up on opposite sides of the solid, parallel to the current,
producing a potential difference known as the Hall voltage. The direction the voltage points
determines the charge of the charge carriers in the material. The quantum Hall effect (QHE)
is identical to the classical Hall Effect except that the Hall voltage (and consequently the Hall
resistivity and the Hall conductivity) occurs only in discrete steps equal to an integer times
e2/h. In addition to the integer quantum Hall effect, there is another effect known as the
fractional quantum Hall effect in which the Hall conductivity is equal to e2/h times a rational
fraction that is less well understood. In the presence of a magnetic field, graphene produces
yet another quantum Hall effect known as an anomalous quantum Hall effect. In the case of
graphene, the Hall conductivity occurs in discrete integer steps like the conventional QHE,
but is shifted by one-half of an integer as shown below in figure.
Fig 2.1
A plot of the Hall conductivity xy (red) and the Hall resistivity xy (green) as a function of carrier concentration.
Graphene is an ideal system for examining the quantum Hall effect for a number of
reasons. First, graphene samples are available in such purity that the charge carrier
concentration can be tuned continuously from high concentrations of electrons to high
concentrations of holes simply by changing the gate voltage. Second, the purity of the
graphene samples is so high that the QHE can be observed even at room temperature,
whereas most materials only exhibit the QHE at much lower temperatures. Finally,
graphene’s anomalous quantum Hall effect, by being shifted by half compared to most
systems, exhibits non-zero conductivity even as the charge carriers change from electrons to
holes (the neutrality point or the Dirac point). For most materials, as the charge carrier
concentration tends towards zero, so does the conductivity, so that there is a metal to
insulator transition at no temperatures. But graphene has shown no signs of a metal-insulator
transition even down to liquid helium temperatures.
Aside from the anomalous quantum Hall effect, one of the most exciting prospects for
graphene is that it may eventually prove useful in electronic applications
We start studying about Graphene Transistors by comparing the normal FET characteristics
to that of Graphene.
2.3 FET physics: what really matters?
A FET consists of a gate, a channel region connecting source and drain electrodes,
and a barrier separating the gate from the channel (Fig. 2a). The operation of a conventional
FET relies on the control of the channel conductivity, and thus the drain current, by a voltage,
VGS, applied between the gate and source. For high-speed applications, FETs should respond
quickly to variations in VGS; this requires short gates and fast carriers in the channel.
Unfortunately, FETs with short gates frequently suffer from degraded electrostatics and other
problems (collectively known as shortchannel effects), such as threshold-voltage roll-off,
drain-induced barrier lowering, and impaired drain-current saturation. Scaling theory predicts
that a FET with a thin barrier and a thin gate-controlled region (measured in the vertical
direction in Fig. 2a) will be robust against short-channel effects down to very short gate
lengths (measured in the horizontal direction in Fig. 2a). The possibility of having channels
that are just one atomic layer thick is perhaps the most attractive feature of graphene for use
in transistors. (Mobility, which is often considered to be graphene’s most useful property for
applications in nanoelectronics, is discussed later.) By comparison, the channels in iii–v
HEMTs are typically 10–15 nm thick, and although silicon-on-insulator MOSFETs with
channel (that is, silicon body) thicknesses of less than 2 nm have been reported, rough
interfaces caused their mobility to deteriorate. More importantly, the body of these
MOSFETs showed thickness fluctuations that will lead to unacceptably large threshold-
voltage variations (and similar problems are expected to occur when the thickness of the
channel in a iii–v HEMT is reduced to only a few nanometres). These problems occur at
thicknesses that are many times greater than the thickness of graphene. The series resistances
between the channel and the source and drain terminals are also important, and their adverse
impact on the FET becomes more pronounced as the gate length decreases. Thus, device
engineers devote considerable effort to developing transistor designs in which short-channel
effects are suppressed and series resistances are minimized. Modern digital logic is based on
silicon complementary metal oxide semiconductor (CMOS) technology. CMOS logic gates
consist of both n- and p-channel MOSFETs that can switch between the onstate (with a large
on-current, Ion, and VGS = }� VDD, where VDD is the maximum voltage supplied to the
device) and the off-state (with a small off-current, Ioff, and VGS = 0). In the terminology of
digital logic, a gate is not the gate terminal of a transistor but a combination of two or more
transistors that can perform a certain logic operation. The value of VGS at which the FET is
just on the verge of switching on is the threshold voltage, VTh. Figure 2b shows the transfer
characteristics of an n-channel FET indicating the on-state and the off-state. Useful measures
with which to assess the switching behaviour are the sub threshold swing, S (relevant to the
sub threshold region), and the terminal transconductance, gmt (relevant to the above-threshold
region). In the steady state, a certain number of the MOSFETs in a CMOS logic gate are
always switched off so that no current—except the small Ioff—flows through the gate14. The
ability of silicon MOSFETs to switch off enables silicon CMOS to offer extremely low static
power dissipation (which is the reason why silicon CMOS has bested all competing logic
technologies). Thus, any successor to the silicon MOSFET that is to be used in CMOS-like
logic must have excellent switching capabilities, as well as an on–off ratio, Ion/Ioff, of
between 104 and 107. In a conventional FET, this requires semiconducting channels with a
sizeable band gap, preferably 0.4 eV or more. Moreover, n- and p-channel FETs with
symmetrical threshold voltages, that is, with VTh,n = −VTh,p, are needed for proper CMOS
operation. In radiofrequency applications, however, switch-off is not required per se. In
small-signal amplifiers, for example, the transistor is operated in the on-state and small
radiofrequency signals that are to be amplified are superimposed onto the d.c. gate–source
voltage. To discuss the radiofrequency performance of FETs, I use the equivalent circuit from
Fig. 3a and focus on the cut-off frequency, fT, which is the frequency at which the magnitude
of the small-signal current gain rolls off to unity. The cut-off frequency is the most widely
used figure of merit for radiofrequency devices and is, in effect, the highest frequency at
which a FET is useful in radiofrequency applications. As can be seen from the expression for
fT the cut-off frequency can be maximized by making the intrinsic transconductance, gm, as
large as possible and making the drain conductance, gds, and all the capacitances and
resistances in the equivalent circuit as small as possible. However, the values of all these
quantities vary with the applied D.C. gate–source voltage, VGS, and the applied D.C. drain–
source voltage, VDS. As shown exemplarily for a typical GaAs HEMT15, 16, VDS has a
pronounced effect on the FET performance. For this transistor, fT peaks around VDS = 1 V,
that is, deep in the region of drain-current saturation, where gm is near its peak and gds has
decreased sufficiently. For lower values of VDS, the device operates in the linear regime and
the cut-off frequency is low because gm is small and gds is large. The bottom line for
radiofrequency performance is that although shorter gates, faster carriers and lower series
resistances all lead to higher cut-off frequencies, saturation of the drain current is essential to
reach the maximum possible operating speeds. This point is frequently missed in discussions
of transistor speeds. Drain-current saturation is also necessary to maximize the intrinsic gain,
Gint = gm/gds, which has become a popular figure of merit for mixed-signal circuits.
2.4 Graphene properties relevant to transistors
Single-layer graphene is a purely two-dimensional material. Its lattice consists of
regular hexagons with a carbon atom at each corner. The bond length between adjacent
carbon atoms, Lb, is 1.42 A and the lattice constant, a, is 2.46 A. The first reports on this
material appeared decades ago, even before the name graphene had been coined, but it took
the pioneering 2004 paper by the Manchester group1 to spark the present explosion of
interest in the material. At present, the most popular approaches to graphene preparation are
mechanical exfoliation1, growth on metals and subsequent graphene transfer to insulating
substrates and thermal decomposition of SiC to produce so-called epitaxial graphene on top
of SiC wafers. Exfoliation is still popular for laboratory use but it is not suited to the
electronics industry, whereas the other two options both have the potential for producing
wafer-scale graphene. After the graphene has been prepared, common semiconductor
processing techniques (such as lithography, metallization and etching) can be applied to
fabricate graphene transistors. In this section, I discuss two important aspects of graphene:
the presence (or otherwise) of a band gap, and charge transport (mobility and high-field
transport) at room temperature.
2.4.1 Band gap.
Large-area graphene is a semimetal with zero band gap. Its valence and conduction
bands are cone-shaped and meet at the K points of the Brillion zone (Fig. 4b). Because the
band gap is zero, devices with channels made of large-area graphene cannot be switches off
and therefore are not suitable for logic applications. However, the band structure of graphene
can be modified, and it is possible to open a band gap in three ways: by constraining large-
area graphene in one dimension to form graphene nanoribbons, by biasing bi-layer Graphene
and by applying strain to graphene. It has been predicted that both armchair nanoribbons and
zigzag nanoribbons (the two ideal types of nanoribbon) have a band gap that is, to a good
approximation, inversely proportional to the width of the nanoribbon. The opening of a band
gap in nanoribbons has been verified experimentally for widths down to about 1 nm, and
theory and experiments both reveal bandgaps in excess of 200 meV for widths below 20 nm
(Fig. 4c). However, it should be noted that real nanoribbons have rough edges and widths that
change along their lengths. Even modest edge disorder obliterates any difference in the
bandgap between nanoribbons with different edge geometries, and edge functionalization and
doping can also affect the bandgap. To open a bandgap useful for conventional field-effect
devices, very narrow nanoribbons with well-defined edges are needed. This represents a
serious challenge given the semiconductor processing equipment available at the moment.
Recently, nanoribbons that were uniform in width and had reduced edge roughness were
produced by ‘unzipping’ carbon nanotubes45. However, even a perfect nanoribbon is not
perfect for electronics applications. In general, the larger the bandgap that opens in a
nanoribbon, the more the valence and conduction bands become parabolic (rather thancone-
shaped): this decreases the curvature around the K point and increases the effective mass of
the charge carriers46, which is likelyto decrease the mobility. Bilayer graphene is also
gapless (Fig. 4b), and its valence and conduction bands have a parabolic shape near the K
point. If an electric field is applied perpendicular to the bilayer, a bandgap opens and the
bands near the K point take on the so-called Mexican-hat shape. This opening was predicted
by theory and has been verified in experiments. Theoretical investigations have also shown
that the size of the bandgap depends on the strength of the perpendicular field and can reach
values of 200–250 meV for high fields ((1–3) × 107 V cm−1; refs ). The bandgap of large-
area single-layer epitaxial graphene is at present the subject of controversy. Although some
results suggest a zero bandgap, others report a bandgap of around 0.25 eV . The transfer
characteristics of epitaxial-Graphene MOSFETs show no switch-off, which suggests a zero
bandgap. However, a bandgap is consistently observed for epitaxial bilayer graphene. Finally,
strain has been discussed as a means of opening a band gap in large-area graphene, and the
effect of uniaxial strain on the band structure has been simulated. At present it seems that if it
is possible at all, opening a gap in this way will require a global uniaxial strain exceeding
20%, which will be difficult to achieve in practice. Moreover, little is known about the ways
in which other types of strain, such as biaxial strain and local strain, influence the band
structure of graphene. Thus, although there are a number of techniques for opening a bandgap
in graphene, they are all at the moment some way from being suitable for use in real-world
applications.
2.4.2 Mobility.
The most frequently stated advantage of Graphene is its high carrier mobility at room
temperature. Mobilities of 10,000–15,000 cm2 V−1 s−1 are routinely measured for exfoliated
graphene on SiO2-covered silicon wafers, and upper limits of between 40,000 and 70,000
cm2 V−1 s−1 have been suggested. Moreover, in the absence of charged impurities and
ripples, mobilities of 200,000 cm2 V−1 s−1 have been predicted, and a mobility of 106 cm2
V−1 s−1 was recently reported for suspended graphene. For large-area graphene grown on
nickel and transferred to a substrate, mobilities greater than 3,700 cm2 V−1 s−1 have been
measured. Finally, for epitaxial graphene on silicon carbide, the mobility depends on whether
the graphene is grown on the silicon face or the carbon face of SiC. Although graphene
grown on the carbon face has higher mobility (values of ~5,000 cm2 V−1 s−1 have been
reported, compared with ~1,000 cm2 V−1 s−1 for graphene grown on the silicon face), it is
easier to grow single-layer and bilayer graphene on the silicon face, which makes the silicon
face of SiC more suited for electronic applications. In early graphene MOS structures, the
mobility was affected by the use of a top-gate dielectric. However, the recent demonstration
of mobilities of around 23,000 cm2 V−1 s−1 in top-gated Graphene MOS channels and the
observation of similar mobilities before and after top-gate formation show that high-mobility
Graphene
Fig 2.2Properties of graphene and graphene nanoribbons.
Schematic of an armchair (ac) graphene nanoribbon (GNR) of length Lac and width
Wac. The nanoribbon shown here has N = 9 carbon atoms along its width and thus belongs to
the 3p family, where p is an integer. b, Band structure around the K point of (i) large-area
graphene, (ii) graphene nanoribbons, (iii) unbiased bilayer graphene, and (iv) bilayer
graphene with an applied perpendicular field. Large-area graphene and unbiased bilayer
graphene do not have a bandgap, which makes them less useful for digital electronics. c,
Bandgap versus nanoribbon width from experiments and calculations. By comparison, the
bandgap of Si is above 1 eV. zz: zigzag.
2.5 Graphene transistor
Transistors less than one-quarter the size of the tiniest silicon ones - and potentially
more efficient - can be made using sheets of carbon just one-tenth of a nanometer thick,
research shows. Unlike other experimental nanoscopic transistors, the new components
require neither complex manufacturing nor cryogenic cooling. The transistors are made of
graphene, a sheet of carbon atoms in a flat honeycomb arrangement. Graphene makes
graphite when stacked in layers, and carbon nanotubes when rolled into a tube. Graphene
also conducts electricity faster than most materials since electrons can travel through in
straight lines between atoms without being scattered. This could ultimately mean faster, more
efficient electronic components that also require less power.
Fig. 2.3 Graphene Transistor is built entirely from sheets of graphene
The first graphene transistor was demonstrated in 2004. But this leaked current and
could never switch it off, because electrons hopped too easily between the carbon atoms. We
have now made a graphene transistor that does not leak current that can control the flow of
just a single electron efficiently. The leak-free transistor is made from a "nano-ribbon" of
graphene less than 10 nanometres wide and just a single carbon atom thick (0.1 nm). The
device not only works at room temperature but, unlike other transistors of a similar size, it is
relatively simple to make. The ribbon at the heart of the device, as well as the surrounding
connections, can be cut from a graphene sheet using electron beam lithography - the same
method used to make silicon devices.
2.5.1 Operation of Graphene Transistors at GHz Frequencies
Top-gated graphene transistors operating at high frequencies (GHz) have been
fabricated. The work represents a significant step towards the realization of graphene-based
electronics for high-frequency applications. Graphene is a two-dimensional (2D) material
with great potential for electronics with essentially the same lattice structure as an unwrapped
carbon nanotube, graphene shares many of the advantages of nanotubes, such as the highest
intrinsic carrier mobility at room temperature of any known materials. This makes these
carbon-based electronic materials particularly promising for high-frequency circuits.
However, due to the high impedance of a single carbon nanotube transistor, high-frequency
properties of nanotubes were investigated indirectly using various mixing techniques and
direct ac measurements of these devices at GHz frequencies were realized only recently
enabled by the larger device current in nanotube arrays. In contrast, one distinct advantage of
graphene lies in its 2D nature, so that the drive current of a graphene device, in principle, can
be easily scaled up by increasing the device channel width. This width scaling capability of
graphene is of great significance for realizing high-frequency graphene devices with
sufficient drive current for large circuits and associated measurements. Furthermore, the
planar graphene allows for the fabrication of graphene devices and even integrated circuits
utilizing well-established planar processes in the semiconductor industry. Recently, it was
shown that graphene devices can exhibit current gain in the microwave frequency range .
Despite intense activities on graphene research, the intrinsic high-frequency transport
properties of graphene transistors have not been systematically studied.
This topic presents the first comprehensive experimental studies on the high-
frequency response of top-gated graphene transistors for different gate voltages and gate
lengths. The intrinsic current gain of the graphene transistors was found to decrease with
increasing frequency and follows the ideal 1/f dependence expected for conventional FETs.
This not only verifies the ac measurement and de-embedding procedures used here for
extracting the intrinsic high frequency properties, but also suggests a conventional FET-like
behaviour for grapheme transistors. The cut off frequency fT deduced from S parameter
measurements exhibits strong gate voltage dependence and is proportional to the dc trans
conductance. The peak cut-off frequency is found to be inversely proportional to the square
of the gate length, and for a gate length of 150 nm, a peak fT as high as 26 GHz is obtained.
Fig. 2.4 A Optical image of the device layout
Fig.2.5 Device layout of graphene field-effect transistors
Figure 2.4 shows the device layout of graphene field-effect transistors with probe
pads designed for high-frequency measurements. Graphene was prepared by mechanical
exfoliation on a high resistivity Si substrate (>10 kΩ cm) covered by a layer of 300nm⋅
thermal SiO2, and Raman spectroscopy was employed to count the number of graphene
layers. Fig. 1(B) shows the optical image of a Graphene flake, where the region on the left
was identified to be single-layer graphene. Source and drain electrodes made of 1 nm Ti as
the adhesion layer and 50 nm-thick Pd were defined by e-beam lithography and lift-off. A 12-
nm-thick Al2O3 layer was then deposited by atomic layer deposition (ALD) at 250ºC as the
gate insulator. In order to form a uniform coating of oxide on Graphene, a functionalization
layer consisting of 50 cycles of NO2- TMA (trimethylaluminum) was first deposited prior to
the growth of gate oxide. This NO2-TMA functionalization layer was essential for the ALD
process to achieve thin (<10 nm) gate dielectrics on grapheme without producing pinholes
that cause gate leakage. The dielectric constant of ALD-grown Al2O3 is determined by C-V
measurements and found to be about 7.5. Lastly, 10nm/50nm Pd/Au was deposited and
patterned to form the top gate.
As shown in Fig. 2.4, the source electrodes were designed to overlap the entire
graphene flake (see figure inset) in order to minimize the uncertainty in the de-embedding
process for high-frequency Sparameter measurements, as explained below.
In the device shown in Fig. 2.5, the distance between the source and drain electrodes
is 500 nm, and the top gate under laps the source-drain gap with a gate length LG of 360 nm.
The total gate width (or channel width), including both channels, is ~ 40μm.
Fig. 2.4 shows the optical image of the complete device layout where the standard
ground-signal-ground probing pads are realized for the gate and the drain to allow for
transition from coax to on-chip coplanar waveguide (CPW) electrodes. Measurements of dc
electrical properties of graphene devices were performed in order to gain insight into their
high-frequency response. In addition, the dc electrical characteristics were monitored at each
fabrication step so that issues affecting the final device performance could be identified.
Fig.2.6 Measured output characteristics of the graphene transistor for various top-gate voltages
The dc electrical characteristics of the completed graphene device after the deposition
of the top-gate electrode are shown in Fig. The inset shows the measured current as a
function of (top-gate) voltage VG at a drain bias of VD = 100 mV. Despite the small on/off
ratio, the graphene devices are essentially am bipolar field-effect transistors, as indicated by
the "V"-shape gate dependence in the measured ID-VG curve. In these graphene field-effect
transistors (GFET), the transport is dominated by electrons and holes for positive and
negative gate voltages, respectively, and the conductance minimum is denoted as the Dirac
point where electrons and holes make equal contributions to the transport.
Fig. shows the n-type output characteristics, ID-VD, of the grapheme transistor at
various gate voltages. It is found that the top-gated GFETs studied here exhibit a nearly linear
ID-VD dependence up to 1.6 V for the gate voltage ranges measured. This lack of current
saturation is due to the fact that graphene is a zero-gap semiconductor. It has been suggested
that velocity saturation at higher biases may lead to the current saturation phenomenon in
graphene transistors. However, higher carrier mobility may be required to achieve this
saturation velocity within the drain bias of practical interest.
The de-embedded S parameters constitute a complete set of coefficients to describe
intrinsic input and output behaviours of the graphene device, and can be used to derive other
important electrical properties such as gain.
Fig. 2.7 The current gain h21
In Fig.2.7 the de-embedded current gain h21 decreases with increasing frequency
following the 1/f slope expected for a conventional FET. In a regular FET, this 1/f frequency
dependence of h21, equivalent to a decay slope of -20dB/decade, results from the gate
impedance given by Z = 1/jωCG, where ω = 2πf and CG is the gate capacitance, that
decreases with increasing frequency. Therefore, the 1/f dependence of current gain obtained
in Fig. 2.7 is significant because it not only validates the high-frequency measurements and
the de-embedding procedures used to extract the intrinsic GFET characteristics, but it also
suggests regular FET-like behaviours for graphene transistors as a function of frequency. One
of the important figures of merit for characterizing high-frequency transistors is the cut-off
frequency fT, defined as the frequency where the current gain becomes unity (h21 = 1). In
practice, for a transistor possessing the ideal -20dB/decade slope for h21, the cut-off
frequency fT is determined by the product of h21 and frequency, i.e. f × h21(f), over the
measured frequency range. Thus, for the device shown in Fig. 2.7, the cut-off frequency fT
can be determined by either approach to be ~ 4 GHz. The high-frequency operation of the
graphene transistor is found to be highly dependent on the dc bias condition. Fig. 2.7 shows
the measured cut-off frequency fT of the GFET as a function of gate voltage. At all gate
voltages, the de-embedded current gain h21 exhibits the 1/f frequency dependence similar to
that shown in Fig.2.7 so that the cut-off frequency can be reliably determined. The n-branch
of the graphene transistor is shown here because of the higher transconductance for electrons
than for holes in this device.
These results show that the high-frequency behaviour of these graphene transistors
can be described as an FET with a static, constant gate capacitance within a significant
portion of the bias range. In principle, the maximum cut-off frequency of an FET can be
improved by reducing the gate length. To investigate the length dependence of fT in graphene
devices, graphene transistors with various gate lengths down to 150 nm were fabricated and
investigated for their high-frequency operations.
All of the graphene devices studied here were prepared in one batch and on the same
chip in order to minimize the device-to-device variations introduced in the fabrication
processes. As before, mobility degradation was observed in all devices after ALD oxide
deposition. The maximum fT was found to increase with reduced gate lengths, as expected,
and for the 150-nmgate GFET, a peak cut-off frequency as high as 26 GHz was obtained, as
shown in Fig. 2.7. To the authors’ knowledge, this is the highest value measured for graphene
transistors to date.
In summary, top-gated graphene transistors of various gate lengths were fabricated
and their high-frequency response was directly characterized by standard S-parameter
measurements. The short-circuit current gain showed the ideal 1/f frequency dependence,
confirming the measurement quality and the FET-like behaviour for graphene devices. As the
gate voltage is varied, the measured fT was found to be proportional to the dc trans
conductance gm, following the relation fT = gm/(2π CG). Furthermore, fT was found to
increase with decreasing channel length, with the scaling dependence fT ~ 1/LG 2 for the
GFETs studied here. A peak cut-off frequency fT as high as 26 GHz was measured for a
150-nm-gate graphene transistor, establishing the state of the art for graphene transistors.
These results also indicate that if the high mobility of graphene can be preserved during the
device fabrication process, a cut-off frequency approaching THz may be achieved for
graphene FET with a gate length of just 50nm and carrier mobility of 2000 cm2/V s. ⋅
2.5.2 Graphene Nano ribbon Field-Effect Transistors
Fig. 2.7GNRFET device
Sub-10nm wide graphene Nano ribbon field-effect transistors (GNRFETs) are studied
systematically. All sub-10nm GNRs afforded semiconducting FETs without exception, with
Ion/Ioff ratio up to 106 and on-state current density as high as ~2000μA/μm. We estimated
carrier mobility ~200cm2/Vs and scattering mean free path ~10nm in sub-10nm GNRs.
Scattering mechanisms by edges, acoustic phonon and defects are discussed. The sub-10nm
GNRFETs are comparable to small diameter (d≤~1.2nm) carbon nanotube FETs with Pd
contacts in on-state current density and Ion/Ioff ratio, but have the advantage of producing
all-semiconducting devices.
Since our GNRFETs were Schottky barrier (SB) type FETs where the current was
modulated by carrier tunnelling probability through SB at contacts, high work function metal
Pd was used to minimize the SB height for holes in p-type transistors. In fact we used Ti/Au
as contact and found that Pd did give higher Ion in device with similar dimensions. 10nm
SiO2 gate dielectrics was also important to achieve higher Ion because it significantly
reduced SB width at contacts compared to 300nm in previous work
For wide GNR devices, they all showed metallic behaviour because of vanishingly
small band gaps. Compared to sub-10nm GNRFETs with similar channel length, the current
density in wide GNR devices was usually higher (~3000μA/μm at Vds=1V for the device in.
We note that our wide GNRs showed relatively weak gate dependence in transfer
characteristics, likely due to interaction between layers. The Dirac point was usually not
observed around zero gate bias, indicating p-doping effects at the edges or by physisorbed
species during the chemical treatment steps.
Fig. 2.7
Transfer and output characteristics of the device
We next analyse how close the GNRFET operates to the ballistic performance limits
by comparing experiments with theoretical modelling. The theoretical model computes the
ballistic performance limits by assuming a single ballistic channel and ideal contacts
(sufficiently negative SBs).
Any subsequent edge scattering after OP/ZBP emission has a small direct effect on
the DC current because edge scattering is elastic and does not change the carrier energy. Such
a carrier rattles around in the channel and finally diffuses out of the drain. At high drain
biases, therefore, only elastic scattering near the beginning of the channel matters and the rest
of the channel essentially operates as a carrier absorber.
Our sub-10nm GNRFETs afford all-semiconducting Nano-scale transistors that are
comparable in performance to small diameter carbon nanotube devices. GNRs are possible
candidates for future Nano-electronics. Future work should focus on elucidating the atomic
structures of the edges of our GNRs and correlate with the performances of GNRFETs. The
integration of ultra-thin high dielectrics and more aggressive channel length scaling is also
needed to achieve better electrostatics, higher Ion and ideal sub threshold slope.
2.5.2 Tuneable Graphene Single Electron Transistor
We report electronic transport experiments on a graphene single electron transistor.
The device consists of a graphene island connected to source and drain electrodes via two
narrow grapheme constrictions. It is electro-statically tuneable by three lateral graphene gates
and an additional back gate. The tunnelling coupling is a strongly non-monotonic function of
gate voltage indicating the presence of localized states in the barriers. We investigate energy
scales for the tunnelling gap, the resonances in the constrictions and for the Coulomb
blockade resonances. From Coulomb diamond measurements in different device
configurations (i.e. barrier configurations) we extract a charging energy of _ 3.4 meV and
estimate a characteristic energy scale for the constriction resonances of _ 10 meV.
Fig. 2.8 Graphene single electron transistor (SET)
Fig. 2.9
Schematic illustration of the tuneable SET device with electrode assignment
Here we investigate a fully tuneable single electron transistor (SET) that consists of a
width modulated grapheme structure exhibiting spatially separated transport gaps. SETs
consist of a conducting island connected by tunnelling barriers to two conducting leads.
Electronic transport through the device can be blocked by Coulomb interaction for
temperatures and bias voltages lower than the characteristic energy required to add an
electron to the island. The sample is fabricated based on single-layer grapheme flakes
obtained from mechanical exfoliation of bulk graphite. These flakes are deposited on a highly
doped silicon substrate with a 295 nm silicon oxide layer. Electron beam (e-beam)
lithography is used for patterning the isolated graphene flake by subsequent Ar/O2 reactive
ion etching. Finally, an additional e-beam and lift-off step is performed to pattern Ti/Au (2
nm/50 nm) electrodes.
TABLE I: Capacitances and lever arms of the different gate electrodes, including source and drain contacts, with respect to the graphene island. Most values are independent from the measurement regime, NN or NP. If there is a difference the NP value is given and the NN value is put in brackets.
In conclusion, we have fabricated and characterized a fully tuneable graphene single
electron transistor based on an etched width-modulated graphene nanostructure with lateral
graphene gates. Its functionality was demonstrated by observing electrostatic control over the
tunnelling barriers. From Coulomb diamond measurements it was estimated that the charging
energy of the grapheme island is 3.4 meV, compatible with its lithographic dimensions.
These results give detailed insights into tuneable graphene quantum dot devices and open the
way to study graphene quantum dots with smaller dimensions and at lower temperatures.
2.5.3 Transfer Characteristics in Graphene Field-Effect Transistors with
Co Contacts
Graphene field-effect transistors with Co contacts as source and drain electrodes show
anomalous distorted transfer characteristics. The anomaly appears only in short-channel
devices (shorter than approximately 3 μm) and originates from a contact-induced effect. Band
alteration of a graphene channel by the contacts is discussed as a possible mechanism for the
anomalous characteristics observed.
In order to construct such electronic devices, metallic materials should make a contact
with the grapheme layers. The effect of metal contacts can be detected using the structure of a
field-effect transistor (FET) and measuring the transfer characteristics (drain current, D I , vs.
gate voltage, G V , characteristics). For instance, the difference between the drain currents of
Graphene FETs at exactly opposite charge densities (at the same carrier densities with
opposite charge polarities) has been explained by a metal-contact effect. Charge transfer from
metal to graphene leads to a p-p, n-n or p-n junction in graphene, depending on the polarity of
carriers in the bulk of the graphene sheet. An additional resistance arises as a result of the
density step created along the graphene channel, which causes asymmetry.
In this we analyse the effect of metal contacts on the transfer characteristics of
graphene FETs. In particular, the choice of metal and the gap between the metal contacts
(source and drain electrodes) have been examined by employing a FET structure. It was
found that graphene FETs with Co contacts and short channels display anomalous distorted
transfer characteristics, indicating that the anomaly originates from Co contacts.
Fig. 2.10 Schematic diagram of a graphene FET.
Graphene layers were formed onto a highly-doped Si substrate with a 300 nm thick
thermal oxide layer using conventional mechanical exfoliation. The starting graphite crystal
used was Super Graphite from Kaneka Corporation. The thicknesses of the graphene layers
were determined to be approximately 1nm by atomic force microscopic observations in
tapping mode. These layers were determined to be one-atom thick from the optical contrast.
Metal electrodes (Co and Au) were fabricated onto the grapheme layers by electron beam
lithography and lift off techniques. For the Au electrodes, 5nm thick Cr was deposited as an
adhesive layer prior to Au deposition. The electrodes fabricated in this study had a total
thickness of 50nm. The FET characteristics were measured in low vacuum at room
temperature.
Fig. 2.11Transfer characteristics of a graphene FET with Cr/Au electrodes with channel length 1.5
μm.
Fig 2.12Transfer characteristics of a graphene FET with Co electrodes. The channel length was 2.0
μm
The transfer characteristics are shown in Figs. 1(b) and 1(c) for Cr/Au and Co
source/drain electrodes, respectively. Cr/Au is a conventionally used metallic material for
electronic devices, and Co is a popular material for spin-electronic devices as a source of
spin-polarized current. Although the graphene FET with Cr/Au contacts exhibits
conventional transfer characteristics, as widely reported previously, that with the Co contacts
displays anomalous distorted characteristics, especially in the negatively gated region.
The shorter channel results in lower channel resistance, and the resistance originating
from the contacts should have a more dominant effect on the two-terminal resistance. In fact,
the resistances at the D I minima are not proportional to the ratio of channel length to channel
width, and thus the contact-related effects contribute to the device resistance.
Fig. 2.13 Wide-ranging transfer characteristics of Co-contacted graphene FETs with a channel length
of 3 μm.In the wide-ranging transfer characteristics of the 3 μm channel device decreases in
the current compared with ordinary transfer characteristics can be seen at gate voltages of -70
and +30 V in addition to the minimum at a gate voltage of +2 V. The minimum at +2 V is
considered to be the charge neutrality point (the so-called Dirac point); the other two
anomalous points are therefore a consequence of the metal contacts.
Another possible mechanism is the diffusion of Co atoms into/onto graphene
channels. In a single charge tunnelling device of a single CdTe Nano rod with Cr/Pd contacts,
a chemical transformation was found to occur by the diffusion of Pd atoms 20-30 nm into the
nanorod.20 However, the robust honeycomb lattice structure of graphene and the possibly
strong chemical interactions at Co/graphene interfaces should prevent Co atoms from
diffusing a long distance into and onto graphene channels. In summary, the effect of metallic
electrode materials contacting graphene channel layers was studied using FET structures.
Cr/Au and Co contacts were investigated, and it was found that graphene FETs with Co
contacts and short channels exhibit distorted transfer characteristics that have two peaks at -
0.20 and +0.13 ev. The present study ascertained the metal-induced alteration of the FET
characteristics of graphene. These results indicate particularly crucial issues for the
development of future graphene microelectronics that consist of short-channel devices.
2.5.4 Epitaxial Graphene Transistors on SiC Substrates
This describes the behaviour of top gated transistors fabricated using carbon,
particularly epitaxial graphene on SiC, as the active material. In the past decade research has
identified carbon-based electronics as a possible alternative to silicon-based electronics. This
enthusiasm was spurred by high carbon nanotube carrier motilities. However, nanotube
production, placement, and control are all serious issues. Graphene, a thin sheet of graphitic
carbon, can overcome some of these problems and therefore is a promising new electronic
material.
Although graphene devices have been built before, in this work we provide the first
demonstration and systematic evaluation of arrays of a large number of transistors entirely
produced using standard microelectronics methods. Graphene devices presented feature high-
k dielectric, motilities up to 5000 cm2/Vs and, Ion/Ioff ratios of up to 7, and are methodically
analysed to provide insight into the substrate properties. Typical of graphene, these micron-
scale devices have negligible band gaps and therefore large leakage currents.
2.6 Fabrication Process of GNRFETs
We obtained the graphene suspension in Pm PV/DCE solution. We soaked the 10nm
SiO2/p++ Si substrate with pre-patterned metal markers (2nm Ti/20nm Au) in the solution
for ~20mins, rinsed with isopropanol and blew dry with argon. Then the chip was calcined in
air at 350ºC for ~10mins and annealed in vacuum at 600ºC for ~10mins to further clean the
surface. We used tapping mode AFM to find GNRs around the pre-patterned markers and
recorded the location. Next we used electron beam lithography to pattern the S/D of the
devices. 20nm Pd was then thermally evaporated as contact metal followed by a standard lift-
off process. Finally, we annealed the device in argon at 200ºC for ~15mins to improve the
contact.
2.6.1 Materials and Substrate Preparation
Graphitic films on SiC substrates were prepared by solid-state decomposition of
single crystal 4HSiC (0001) in vacuum. The method involves an inductively heated vacuum
furnace in which 3.5 mm X 4.5 mm X 0.3 mm SiC chips, are heated to about 1400 °C. In this
process, Si sublimes to produce carbon-rich surfaces that subsequently graphitize. The
graphitization produces epitaxial ordered stacked layers of graphene, with a high structural
coherence length. Figure 1 shows this multi-layered epitaxial graphene (MEG) at the
different stages of preparation.
Fig. 2.14 Preparation stages of the G/SiC substrate chips (4.5x3.5mm).
Prior to integration G/SiC chips were characterized using optical and AFM
measurements at MIT LL. It is important to note that SiC is not symmetric, the Si – C bond in
the [0001] direction has an asymmetry just due to the fact that one end is Si and the other is
C. Consider cleaving the SiC lattice by breaking that particular bond along the (0001) plane.
This cleave results in two interfaces, the silicon terminated surface is called the Si-face, and
the carbon terminated surface is called the C-face, figure
Fig.2.15
Crystal structure of SiC showing the two faces of the crystal cut along the (0001) plane.
A typical SiC wafer will have a Si-face in the front with a [0001] normal, and a C-
face in the back with a [000-1] normal. During silicon sublimation graphene layers are
generated on both faces of the SiC wafer, however the film generated on the C-face has
different properties from the film generated on the Si-face.
2.6.2 Device integration:-
After characterization, G/SiC chips were mounted on 150-mm silicon carrier wafers
using epoxy bonding. This was done so that the silicon fabrication tools are able to process
the small chips. First, alignment marks were defined with standard g-line lithography and
etched into the G/SiC with Cl2/He plasma etches. These marks are required because the
active MEG layer is too difficult to see optically for consistent alignment of subsequent
layers. Following the alignment mark etches, the resist was stripped in 80°C sulphuric acid;
this strip did not affect the appearance or resistivity of the MEG layer. Next, the active MEG
layer was patterned using a low energy O2 plasma etches. The source/drain layers were
deposited directly on the MEG film layer and consisted of 2 nm Ti and 20 nm of Pt., defined
using a lift off process. A 40 nm HfO2 layer was then deposited over the entire chip, using
thermal evaporation. The HfO2 film was verified to have a dielectric constant of 23 via a
capacitive measurement of a finished device. Finally, a 100 nm Al gate was deposited and
defined using lift-off. The AFM of a finished device is shown in Figure 2.4.
The mask pattern used in this experiment contained approximately 100 devices, with
different gate lengths, graphene widths, and alignment conditions. The nominal device was a
one with a source to drain spacing of 10 μm, a graphene width of 5 μm, and a 15 μm gate
overlapping the source and drain by 2.5 μm on each face. Hundreds of transistors where
fabricated, with functional yield as high as 95% for some samples.
Fig 2.16 AFM scan of a finished nominal device
Although promising, graphene based electronics faces many obstacles before it can
become a competitive technology. Minimum conduction has to be decreased, device to
device variability has to be controlled, and a stable gate dielectric must be found. However
the chip level integration of hundreds of graphene devices on insulating SiC substrates is a
step towards making graphene technology possible. The main driver for a graphene
technology is clearly mobility. Even in this preliminary experiment motilities up to 5000
cm2/Vs have been achieved. This is already 10 times better than silicon technology which
has had decades of optimization. It doesn’t seem unreasonable to expect that after thorough
investigation and process optimization, graphene devices will have motilities over 10,000
cm2/Vs. The greatest obstacle to a graphene technology is the lack of a band-gap, and thus an
inability to turn off conduction below a certain level. It is likely that some method of
obtaining an on/off ratio for current in the hundreds will be demonstrated in the near future.
CHAPTER 3
CONCLUSION
3.1 Present Applications
Graphene’s high conductivity and its unusual electronic properties may lead to
unexpected advances in processor and electronic technologies. After carbon nanotubes have
so far failed to revolutionize the field, scientists are cautious in advertising the possible future
applications of graphene. For graphene, it is too early to tell whether graphene will
significantly affect the field of commercial electronics, but it’s small scale and unusual
properties may contribute to the development of nanoscopic electronic components or
quantum computing. Graphene has been used to produce a functional transistor even though
this initial proof of concept transistor leaks electrons and is highly inefficient.
3.2The Future Of Graphene
Scientists acknowledge that graphene will be an important material in future
technologies. It might be used to store hydrogen in fuel cells or in batteries as electrodes. It
may serve a use in the production of ultra-thin fabrics that require great strength. If glues are
used between the graphene layers, it might be possible to assemble very strong materials. Its
chemistry can be controlled to change its electrical properties to be conducting, insulating or
semiconducting. It may even prove useful in the possible development of quantum
computing. Graphene’s immense potential is especially exciting considering how easy and
cheap it is to produce.
3.3 Conclusion
Although promising, graphene based electronics faces many obstacles before it can
become a competitive technology. Minimum conduction has to be decreased, device to
device variability has to be controlled, and a stable gate dielectric must be found. However
the chip level integration of hundreds of graphene devices on insulating SiC substrates is a
step towards making graphene technology possible. The main driver for a graphene
technology is clearly mobility.
This seminar report represents the whole knowledge of Graphene Transistor. In
everywhere in industries programmable logic controller is used. We can say that now a days
the grapheme transistor become the back bone of the modern electronic field.
However, many details about the potential performance of graphene transistors in real
applications remain unclear. Here the properties of graphene that are relevant to electron
devices, discuss the trade-offs among these properties and examine their effects on the
performance of graphene transistors in both logic and radiofrequency applications. I conclude
that the excellent mobility of graphene may not, as is often assumed, be its most compelling
feature from a device perspective. Rather, it may be the possibility of making devices with
channels that are extremely thin that will allow Graphene field-effect transistors to be scaled
to shorter channel lengths and higher speeds without encountering the adverse short channel
effects that restrict the performance of existing devices. Outstanding challenges for graphene
transistors include opening a sizeable and well-defined band gap in graphene, making large-
area graphene transistors that operate in the current saturation regime and fabricating
graphene Nano ribbons with well-defined widths and clean edges.