2021
DOI: 10.1021/acsaelm.0c01108
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Schottky Barrier Height Modulation of Metal/n-GeSn Contacts Featuring Low Contact Resistivity by in Situ Chemical Vapor Deposition Doping and NiGeSn Alloy Formation

Abstract: GeSn complementary metal-oxide-semiconductor (CMOS) devices have attracted much attention for future VLSI technology nodes due to high carrier mobility. However, Fermilevel pinning in metal/n-GeSn contacts leads to high contact resistivity and limits GeSn CMOS devices for high-performance logic applications. In this work, we investigate Schottky characteristics and contact resistivity in the metal/n-GeSn contacts. Highquality n-GeSn layers were epitaxially grown by chemical vapor deposition with an in situ dop… Show more

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Cited by 14 publications
(6 citation statements)
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“…The effective doping concentration is defined as N*=(NAND)normal/(NA+ND)${N^{\rm{*}}} = \left( {{N_{\rm{A}}}{N_{\rm{D}}}} \right){\rm{/}}\left( {{N_{\rm{A}}} + {N_{\rm{D}}}} \right)$, where N A and N D are the doping concentrations of the p‐type and n‐type layers, respectively. Room‐temperature NDR is achieved for all devices due to high doping activation rates, [ 18 ] the sharp doping abruptness at the p–n junction interface, and the suppressed DAT, which is attributed to the high material quality of GeSn epitaxial layers. All devices show clear NDR with high PVCRs of 1.8–5.5, which suggests that the peak current is dominated by the BTBT mechanism.…”
Section: Resultsmentioning
confidence: 99%
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“…The effective doping concentration is defined as N*=(NAND)normal/(NA+ND)${N^{\rm{*}}} = \left( {{N_{\rm{A}}}{N_{\rm{D}}}} \right){\rm{/}}\left( {{N_{\rm{A}}} + {N_{\rm{D}}}} \right)$, where N A and N D are the doping concentrations of the p‐type and n‐type layers, respectively. Room‐temperature NDR is achieved for all devices due to high doping activation rates, [ 18 ] the sharp doping abruptness at the p–n junction interface, and the suppressed DAT, which is attributed to the high material quality of GeSn epitaxial layers. All devices show clear NDR with high PVCRs of 1.8–5.5, which suggests that the peak current is dominated by the BTBT mechanism.…”
Section: Resultsmentioning
confidence: 99%
“…While increasing the doping concentrations is expected to increase the electric field and the BTBT rate, the tunneling current might not be enhanced effectively owing to the reduced activation rates of dopants at concentrations higher than 10 20 cm −3 . [18,19] On the other hand, reducing the bandgap energy can lower the tunnel barrier to increase BTBT rates. With similar effective doping concentrations of 1.4 to 1.5 × 10 19 cm −3 , the peak current density of a GeSn Eskai diode is larger than that of a Ge Esaki diode by a factor of 12 (Figure 3b).…”
Section: Resultsmentioning
confidence: 99%
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“…The high density of dislocations/defects in GeSn enhance twostep trap-assisted tunneling (TAT) or variable-range-hopping (VRG) conduction mechanisms [29]. Two-step TAT is the process where the carriers in the metal are excited thermally and tunnel via the trap states in the Schottky barrier to reach the conduction/valence bands.…”
Section: A Dark Current Analysismentioning
confidence: 99%
“…However in practice, metals form Schottky contacts irrespective of work function because the Fermi level of metal is pinned at a certain energy level at the semiconductor interface. This Fermi-level pinning arises from the surface states of the semiconductor. Thus, we need new and approachable routes to achieve an ideal MS junction where the metal’s work function aligns with the conduction or valence band of the semiconductor without Fermi-level pinning. By introducing a graphene layer in between the MS junction, the Schottky properties can be altered to Ohmic and reduce the Fermi-level pinning of the semiconductor. The graphene layer also modulates its work function via doping of metal impurities which reduces the Schottky height and facilitates charge transport in both directions. , The work function of graphene can also be modified by the functionalization of some chemical elements …”
Section: Introductionmentioning
confidence: 99%