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Paper detail

High Current Density 2D/3D Esaki Tunnel Diodes

The integration of two-dimensional materials such as transition metal dichalcogenides with bulk semiconductors offer interesting opportunities for 2D/3D heterojunction-based novel device structures without any constraints of lattice matching. By exploiting the favorable band alignment at the GaN/MoS2 heterojunction, an Esaki interband tunnel diode is demonstrated by transferring large area, Nb-doped, p-type MoS2 onto heavily n-doped GaN. A peak current density of 446 A/cm2 with repeatable room temperature negative differential resistance, peak to valley current ratio of 1.2, and minimal hysteresis was measured in the MoS2/GaN non-epitaxial tunnel diode. A high current density of 1 kA/cm2 was measured in the Zener mode (reverse bias) at -1 V bias. The GaN/MoS2 tunnel junction was also modeled by treating MoS2 as a bulk semiconductor, and the electrostatics at the 2D/3D interface was found to be crucial in explaining the experimentally observed device characteristics.

preprint2016arXivOpen access
Sriram KrishnamoorthyEdwin W. Lee IIChoong Hee LeeYuewei ZhangWilliam D. McCullochJared M. JohnsonJinwoo HwangYiying WuSiddharth Rajan
cond-mat.mes-hallphysics.ins-det
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Sriram KrishnamoorthyEdwin W. Lee IIChoong Hee LeeYuewei ZhangWilliam D. McCullochJared M. JohnsonJinwoo HwangYiying WuSiddharth Rajan

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