Firdous Basheer scite author profile

The search of a p-type metal contact on MoS2 has remained inconclusive, with high work function metals such as Au, Ni, and Pt showing n-type behavior and mixed reports of n as well as p-type behavior for Pd. In this work, we report quantitative Schottky barrier heights for Au and Pd contacts to MoS2 obtained by analysing low temperature transistor characteristics and contact resistance data obtained using the transfer length method. Both Au and Pd exhibit n-type behavior on multilayer as well as monolayer MoS2 transistors with Schottky barrier heights of 0.126 eV and 0.4 eV, and contact resistances of 42 Ω.mm and 18 × 104 Ω.mm respectively. Scanning photocurrent spectroscopy data is in agreement with the resulting energy band alignment in Au-MoS2-Pd devices further reinforcing the observation that the Fermi-level is pinned in the upper half of MoS2 bandgap.

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Evaluating Au and Pd contacts in mono and multilayer MoS<inf>2</inf> transistors

Kaushik

Nipane

Basheer

et al. 2014

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The search of a p-type metal contact on MoS2 has remained inconclusive, with high work-function metals such as Au, Ni and Pt showing n-type behavior [1] and mixed reports of n as well as p-type behavior for Pd. In this work we report for the first time, quantitative band alignment of Pd and Au-MoS2 interfaces using low temperature and scanning photocurrent measurements on MoS2 transistors with varying metal contacts (Au-Au, Pd-Pd and Au-Pd). Our results indicate n-type behavior for Pd contacts on multilayer as well as monolayer MoS2 b) of nearly 0.5 eV, four times that for Au contacts indicating that the MoS2 Fermi-level is pinned in the upper half of MoS2 bandgap. Molybdenum disulphide (MoS2) has emerged as an attractive candidate for future CMOS applications owing to its graphenelike 2D nature but with a bandgap of nearly 1.2 eV (for multilayer MoS2). High on/off current ratios with sub-threshold slope ~60 mV/decade and high mobility (>100 cm 2 /Vs) have been reported [1][2][3]. The n/p type behavior of MoS2 transistors is controlled by the contacts (electron vs hole injection). Till date p-type MoS2 transistors have been difficult to demonstrate due to the n-type behavior of high workm) metals on MoS2 [1]. However some recent reports of Pd contacts have reported n as well as p-type behavior [4-7] ( Table 1). In this work we have fabricated back-gated (p + -Si/SiO2 300 nm) transistors on exfoliated MoS2 flakes consisting of a single as well as ~20 stacked layers of MoS2. An optical image and a schematic of a fabricated device are shown in Figures 1(a) and (b). Source/drain contacts with different metal configurations (Au-Au, Pd-Pd and Au-Pd) were fabricated using e-beam lithography and e-beam evaporation. Figure 1(c) shows the alignment of Au and Pd work-function with MoS2 energy bands in free and in contact mode. Figures 1(d) and (e) show the Raman and XPS spectroscopy signatures of monolayer MoS2 measured on fabricated devices respectively. For multilayer flakes, AFM (not shown) measurements were carried out to estimate the number of device layers (~20). Figures 2 and 3 show the ID-VD characteristics of multi and monolayer MoS2 at fixed Vgs indicating (a) different Schottky barrier heights for Au and Pd due to the asymmetric nature of the Aub for Pd/MoS2 interface vs Au due to the higher resistance of the Pd-Pd device. Figure 4 shows the ID-VG transfer characteristics indicating the n-type behavior of Au and Pd contacts irrespective of the thickness of the MoS2 channel layer. Figures 5 and 6 show variable temperature ID-VG and Arrhenius plots (ID vs 1000/T) for the Au-MoS2-Au device respectively. Similar measurements on Pd devices were used to extract the Pd/MoS2 and Au/MoS2 b GS plots as shown in Figure 7 [1]. The effective b for Pd/MoS2 is 0.5 eV, nearly four times that for the Au/MoS2 interface (0.12 eV). Inspite of the b, Pd makes an n-type contact on MoS2, since the band gap for bulk MoS2 is 1.2 eV. Scanning photocurrent microscopy on Au-Au and Au-Pd devices ( Figure 8) further helps to identify the rela...

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High Performance 400 °C p⁺/n Ge Junctions Using Cryogenic Boron Implantation

Bhatt

Swarnkar

Basheer

et al. 2014

IEEE Electron Device Lett.

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Cryogenic implantation for source/drain junctions in Ge p-channel (Fin)FETs

Bhatt

Swarnkar

Mittal

et al. 2014

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Firdous Basheer

Schottky barrier heights for Au and Pd contacts to MoS2

Evaluating Au and Pd contacts in mono and multilayer MoS<inf>2</inf> transistors

High Performance 400 °C p⁺/n Ge Junctions Using Cryogenic Boron Implantation

Cryogenic implantation for source/drain junctions in Ge p-channel (Fin)FETs

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Firdous Basheer

Schottky barrier heights for Au and Pd contacts to MoS2

Evaluating Au and Pd contacts in mono and multilayer MoS<inf>2</inf> transistors

High Performance 400 °C p+/n Ge Junctions Using Cryogenic Boron Implantation

Cryogenic implantation for source/drain junctions in Ge p-channel (Fin)FETs

Contact Info

Product

Resources

About

High Performance 400 °C p⁺/n Ge Junctions Using Cryogenic Boron Implantation