Introduction

Graphene has outstanding electronic properties1,2,3, namely excellent charge-carrier mobilities up to the order of 106 cm2 Vs−1 (ref. 4), extremely high current stability in excess to 4-6 mA μm−1 (refs 5,65,6), high-temperature stability and high thermal conductivity7. These properties make it appealing for applications in electronics. The most immediate applications employ its (semi-)metallic character, for example, as transparent conductive layer, for example, for displays and solar cells. Further, the rather weak switching properties in graphene transistors can be used for analogue amplification at high frequencies8. However, the use of graphene in replacement for a semiconductor fails because of the absence of an electronic bandgap9,10. Many efforts have been undertaken to establish a gap in graphene devices, with a bandgap induced by bilayer graphene11,12,13,14,15, spatial confinement16,17,18, localization19,20 and chemical treatment20,21, resulting in rather small effects remote from technical requirements. It is an open question whether the excellent capabilities of graphene can be maintained after such a modification.

We focus on epitaxial graphene on 6H silicon carbide (SiC) (0001), which provides excellent quality22 and semiconductor technology compatible processing on the wafer scale8. Up to now in graphene experiments mainly semi-insulating SiC has been used to suppress all current paths through the substrate. SiC, as active component of the system, has been widely disregarded. It is a wide bandgap semiconductor for applications in high-voltage and high-power electronics23,24,25,26. Its material properties have been thoroughly investigated27,28,29 and devices are commercially available. The material combination graphene on SiC thus combines two of the most robust materials for electronic applications we are aware of5,30,31 and both materials are in intimate, epitaxially defined contact. In most cases, this contact leads to the formation of a Schottky barrier, with graphene as the metal and SiC as the semiconductor32, which allows basically no exchange of charge carriers. However, this interface can be tailored as an electronically transparent ohmic contact.

We demonstrate a device concept based on a suitable combination of these interfaces. We present a simple fabrication strategy, which leads to normally-on and normally-off transistors. The measurements indicate that they are well suited as fast and efficient switches. In a further step, a complete logic is envisaged.

Results

Device concept and implementation

Figure 1a shows the essential device concept of a single transistor, similar to a metal-semiconductor field-effect transistor: graphene forms the source, drain and gate electrode, and the SiC substrate is the semiconducting transistor channel. In this concept, we intend to guide the current in two layers: charge flows to the transistor in the graphene layer and the semiconducting layer provides the switch to carry the charge from source to drain, when the channel is open. Hence, we need a graphene layer with good charge carrier injection into SiC, which we call 'contact graphene'. It turns out that when growing graphene out of n-type SiC (by thermal decomposition33), the resulting material combination n-type monolayer graphene (MLG) and n-type SiC is one of the few favourable solutions34 for this problem. In MLG, as depicted in Fig. 1b, an electrically active graphene layer with a useful electron density n and mobility μ (n=1013 cm−2, μe=900 cm2 Vs−1 at room temperature) resides on a so-called buffer layer of carbon with R30 symmetry, which is electrically inactive. The outmost Si atoms of the SiC form partly covalent bonds to the buffer layer, partly they have dangling bonds under the buffer layer, which provide Fermi level pinning of the graphene electron system. We will demonstrate that this interface is a good choice for contact graphene. For the gate electrode, however, a good insulation is necessary. This 'gate graphene' can be implemented in many ways35,36. We opted for quasi-freestanding bilayer graphene (QFBLG, see Fig. 1c) on the same n-type SiC, which is obtained from MLG material by hydrogen intercalation37. During this conversion (typically in H2 atmosphere at 850 °C), the covalent bonds between SiC and graphene break up and the dangling bonds are saturated with hydrogen atoms. The buffer layer converts to an additional graphene layer. The result is a positively charged graphene bilayer with hole density p=1013 cm−2, μh=2,000 cm2 Vs−1 at room temperature. As QFBLG forms a Schottky contact with SiC, it serves well as gate graphene.

Figure 1: Two different epitaxial graphene materials combined to a monolithic transistor.
figure 1

We consider the entire system epitaxial graphene employing its constituent graphene, SiC and their common interface. The wide bandgap semiconductor SiC forms the transistor channel. (a) Schematic of the device. Out of a single layer of graphene, two different interfaces are tailored side by side, resulting in ohmic contact graphene for source and drain (b), and Schottky-like gate graphene (c). The currents are guided in two layers from the graphene source through the semiconducting channel to the graphene drain. The channel conductance is modulated by the top-gate voltage. (d) An electron micrograph showing the device geometry. Contact graphene and gate graphene can be distinguished by different grey scales. Scale bar, 100 μm.

An additional challenge is to combine both graphene species side-by-side on a single chip. We start with 6H-SiC (0001), entirely covered with contact graphene. To avoid a complete conversion of the graphene layer, we carry out the hydrogen intercalation process at a reduced temperature. As a consequence, no conversion to gate graphene takes place on the impenetrable graphene surface. However, at lithographically defined edges of the graphene sheet, or at voids, hydrogen can intercalate from the side and slowly converts contact graphene to gate graphene. We have found robust parameter sets for penetration depths dp from 350 nm to 1.5 μm, with no indication for a lower limitation. For the given structure size, T=540 °C with dp=500 nm was adequate. This kinetically controlled process can be used to partially convert small gate structures into gate graphene, whereas the larger source and drain electrodes remain contact graphene, except at their edges. When large area gate graphene is required, a perforation previous to hydrogen treatment is used, in particular for the gate electrode's contact pad. Hence, using a single chip of as-grown graphene, after only one lithography step, we can define two interface functionalities by geometry: contact graphene and gate graphene side-by-side. For our actual research, we used a second lithography step to reduce partially converted areas at the edges of the contact graphene, to ensure well-defined conditions. The two different materials can be distinguished in standard electron microscope images as different grey scales (Fig. 1d). On the stepped off-axis substrate required for epitaxial growth of the pn layers (see below), additionally an undesired conversion to gate graphene occurs along the substrate steps that causes the stripes in the contact graphene areas.

Further, we have to take care for a geometric confinement of the channel in the semiconductor. A vertical confinement is predefined by an epitaxially grown layered pn junction38 that leaves the top surface of the wafer as low doped conducting n-type layer of 2.9 μm depth (out of which graphene is grown). The space charge region of the pn junction suppresses any charge carrier density below this conducting layer. By applying a parametric backgate voltage, the thickness of the space charge region and, complementary, the thickness of the conducting layer can be varied in operandi. It should be stressed that the backgate is a convenient control parameter for our test system, but is not required for the device operation, when doping and thickness of the n-type epilayer are well balanced. Laterally, the channel is confined such that the gate separates the source and drain contact. This is necessary for low off-current level and to avoid crosstalk between two transistors.

Properties of contact graphene and gate graphene

First, we verified the electrical contact properties of the two different graphene/SiC interfaces. Figure 2a displays room temperature resistance measurements taken on circular transfer length method (CTLM) structures fabricated of MLG (left inset) as a function of electrode spacing d. A geometry correction has properly been carried out, following the procedure of ref. 39. Each data point corresponds to the slope of a linear IV, two examples of which are shown in the right inset. No deviation from ohmic IVs was found, even at lowest voltages. From the distance dependence (which is again perfectly linear), we can derive both the contact resistance of ρC=0.063 Ωcm2 and the sheet resistance RS~150 kΩ/ of the n-type SiC layer, the latter in accordance with Hall measurements in a different sample without graphene (μSiC=370 cm2 Vs−1, n=1×1015 cm−3). The remarkable feature of the graphene/SiC contact is its perfectly ohmic behaviour, despite the very low doping concentration of the SiC epilayer, which is absent for metallic contacts (in particular, annealed nickel contacts) on the very same material. The extracted value ρC is on the first sight substantially higher than for state-of-the-art metal ohmic contacts to highly doped SiC40. However, by further CTLM measurements on highly nitrogen (N)-doped 6H SiC material (nitrogen concentration [N]=1019 cm−3), we could verify that additional contact doping can improve ρC by orders of magnitude: contact resistances of ρC=6 μΩcm2 were reached, which are well competitive with state-of-the-art ohmic contacts on SiC41 (we currently run an extensive study on this item). There is an analogy to state-of-the-art metal ohmic contacts to SiC, where carbon is considered as an important mediator for transparent interfaces42. We conclude that MLG is ideally suited as contact graphene.

Figure 2: Characterization of graphene/silicon carbide contacts.
figure 2

(a) We have characterized the ohmic contacts of MLG on SiC. The left inset shows the geometry of the CTLM pattern. The grey ring corresponds to the SiC channel with parametrically varied length d. The inner and outer parts are used as contacts. The right inset corroborates the linearity of the IV characteristics (ohmic contacts), despite a very low doping of the semiconductor. The slope Rcorr (corrected for cylindric geometry39) of the corresponding IV curves is plotted against d in the main figure. From the linear Rcorr(d) dependence contact and sheet resistance, ρC and RS, respectively, are derived. (b) IV characteristics of a QFBLG/SiC junction with ohmic counter electrode. The rectifying Schottky behaviour justifies the use as gate graphene. A Schottky barrier height B,IV=0.9 eV is extracted from the forward characteristics (shaded area, same data shown in upper inset). B,CV=1.57 eV is extracted from CV data (lower inset) on the same device.

Similarly, we carried out CV and I–V measurements on QFBLG contacts on the same SiC material equipped with ohmic nickel counter electrodes (Fig. 2b), resulting in a rectifying behaviour. We could derive a lower limit of the injection barrier B,IV=0.9 eV from the IV measurements (upper inset) and an upper limit B,CV=1.1 eV ... 1.6 eV from CV measurements (lower inset), using a standard evaluation43. These values are comparable to those of metals in contact with SiC44. Hence, QFBLG forms the desired Schottky contact to n-type SiC, which justifies its use as gate graphene. However, the spread of resulting Schottky barrier heights obtained from these two methods and the sample-to-sample fluctuations indicate that this barrier strongly depends on surface quality and may be improved by better process control.

Transistor operation

In a next step, we defined a transistor (Fig. 1) with contact graphene source and drain electrodes and a top-gate electrode made out of gate graphene. We investigated the response of the source-drain current ID on variation of the following parameters: source-drain voltage, VSD; top-gate voltage, VTG; back-gate voltage, VBG; and temperature, T. We present the data in two specific regimes defined by VBG: normally-on and normally-off operation indicated by the switch state at VTG=0 V.

Figure 3a displays the transfer characteristic in the normally-on regime, which was achieved at VBG=−2.5 V. In this state, at VTG=0 V, the channel is open and the current ID between the two ohmic contacts is almost at its maximum value. When applying a negative VTG, the channel becomes depleted by the increasing space charge region of the Schottky contact, which reduces ID. At room temperature, this suppression leads to an on/off ratio of 2,100, with a minimum value of ID=0.36 nA at VTG=−0.8 V. This minimum value and the upturn at even lower VTG is governed by the leakage current ITG of the Schottky contact (Fig. 3b) owing to the rather small effective barrier B of this device. Consequently, the leakage current is strongly reduced towards lower temperatures. At T=220K, the minimal current ID is reduced to 0.6 pA leading to a very high on/off ratio of 46,000. The comparison of the transfer characteristics for different T is shown in Fig. 3a. With reduced T also the on-current is reduced because of charge carrier freeze-out in the SiC channel region45. Below 220K, this effect results in a reduction of the on/off contrast. This indicates that all curves are dominated by semiconductor material properties, which can be engineered by variation of the doping according to the requirements, and by the surface quality. Figure 3c displays the corresponding output characteristics at room temperature. We find a linear rise at low VSD and a quasi-saturated behaviour at higher values. The transistor withstands VSD=5 V without any irreversible change.

Figure 3: Electrical characterization of a monolithic epitaxial graphene transistor.
figure 3

Transfer characteristics (a) and gate leakage currents (b) for various temperatures, and output characteristics (c) at room temperature in the normally-on operation mode. On/off ratios were determined between the current at top-gate voltage VTG=0 V and the minimum drain current ID value (indicated by arrows). (df) Corresponding plots for normally-off operation mode. The current contribution ID increasing towards more negative VTG can be identified as leakage current ITG, which depends on interface quality. In both modes, the largest on/off contrast is achieved at T=220 K.

We now turn to the normally-off operation achieved at VBG=−4 V (Fig. 3d–f). Here at VTG=0 V, the channel is already switched off, because the space-charge regions of the unbiased graphene top-gate and of the pn junction back-gate meet. By applying a positive VTG, we reopen the channel for the source-drain current ID, thereby increasing ID by a factor of 12,000 at room temperature. This maximum is limited by the measurement compliance ITG < 10 nA: the disadvantage of this mode is, that the required positive VTG drives the Schottky gate in forward direction, as can be seen in the leakage current ITG in Fig. 3e. Again at negative VTG, ITG determines ID. Similar to the above reasoning, we try to reduce the influence of leakage by reducing T. The best on/off ratio with a value of 74,000 is again achieved at 220 K. The overall current levels ID are substantially smaller (Fig. 3f) compared with the normally on operation. For all characteristics, hysteresis was essentially absent.

Switching speed

As the device is a unipolar field-effect transistor, it is expected to switch fast46. Although our design did not target high-frequency operation (for example, we used large contact pads, conductive substrate), we measured the AC response ID(f) when a sinusoidal voltage VTG(f) was applied to the top-gate. No significant damping/phase shift and no signal distortion was observed up to 1 MHz. This observation corresponds well with textbook predictions for the cutoff frequency of a metal-semiconductor field-effect transistor43 (at which the AC gate current ITG is equal to the drain current ID): . Here g is the transconductance, which is extracted from the transfer characteristics of our device at room temperature, and CTG, the capacitance of the top-gate. In our proof-of-concept layout, the area that contributes to CTG is unnecessarily large as it includes the bond pad of the gate structure. As the simplest example for a design improvement, we could use semi-insulating SiC for the peripheral regions of the transistor (for example, by vanadium implantation). This should reduce CTG and consequently fT is supposed to increase by a factor of ~30. The route for further speed improvements is obvious: optimization and shrinkage of the geometry, reduction of source, drain resistances, and so on.

Discussion

In summary, we present an integrated scheme for a transistor with high on/off ratios using epitaxial graphene on 6H-SiC (0001). It is monolithic in the sense that it includes and relies on the entire system graphene, SiC and its interfaces, and furthermore, that devices can be carved out of a single epitaxial graphene/SiC chip. With appropriate adaptations, they can be fabricated side-by-side with present epitaxial graphene high-frequency architectures8 (for which it provides the missing switch), and also with existing SiC high-power devices23, with low fabrication effort. We have reached on/off ratios up to 74,000 (or even more than 600,000 when comparing minimum and maximum current ID at UTG=−0.2 V and 0.6 V, respectively, for UBG=−3.5 V, USD=1 V and T=220 K). We consider this device as a proof of concept. The presented device performance is not fundamentally limited and may be tailored according to specific requirements. In particular, the contact resistances can be improved by four orders of magnitude by contact implantation. Different intercalation conditions, variation of off-angle of the substrate, design optimisation, and so on, are expected to lead to uniform and therefore higher effective Schottky barriers. This will allow for higher currents, higher operation speed and higher operation temperatures.

The concept's particular strength, however, lies in the following property: within the same processing steps, many epitaxial graphene transistors can be connected by graphene strip lines (the interface from contact graphene to gate graphene is electrically transparent47,48) along with graphene resistors and graphene/SiC Schottky diodes (Fig. 2b), and therefore complex circuits can be built up. As a special feature of graphene in contrast to semiconductors, we anticipate that even a complete logic is feasible.

Methods

Substrate and graphene growth

A layered 6H-SiC pn junction with a 3-μm thick highly p-doped (2×1018 cm−3 of aluminium) layer underneath a 2.9-μm thick slightly n-doped (1×1015 cm−3 of nitrogen) layer was grown by means of chemical vapour deposition on top of a n-type 6H-SiC wafer 3.5° off the (0001) direction. After a hydrogen etch step (consuming 400 nm of SiC), graphene is grown by thermal decomposition of the SiC substrate at 1,650 °C under argon flux near room pressure33.

Device fabrication

Mesa structures are formed by reactive ion etching, using a lithographically defined mask of gold and nickel to separate the individual transistors and to give access to the p-doped layer. Mask residues were removed with aqueous KI:I2 solution. To partly transform MLG to QFBLG, the samples were annealed in a rapid thermal annealing furnace at 540 °C and 880 mbar with a constant flux of 1 slm of purified hydrogen for 90 min. The conditions are chosen such that the hydrogen only intercalates through a regular pattern of small holes (~200 nm, distance 0.5 μm) prepared in the graphene layer, where conversion is desired. Subsequently, the devices are patterned by electron beam lithography and oxygen plasma etching. Titanium/gold contacts to the MLG and nickel contacts to the QFBLG regions are deposited by electron-beam evaporation and sputtering, respectively. The p-doped substrate layer is contacted via a large area nickel contact.

Characterization

The transistor characteristics were investigated in a continuous-flow cryostat with the sample in helium at 10 mbar using a Keithley 6430 source measurement unit with remote amplifier. Characterization of the contact properties was done in a Lakeshore probe station in vacuum using a 4-probe set-up using an Agilent E5270B measurement frame with 4 E5287A high-resolution source measurement modules and an Agilent E4980A LCR meter.

Additional information

How to cite this article: Hertel, S. et al. Tailoring the graphene/silicon carbide interface for monolithic wafer-scale electronics. Nat. Commun. 3:957 doi: 10.1038/ncomms1955 (2012).