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Conductivity and size quantization effects in semiconductor $$\delta$$-layer systems

Juan P. Mendez, Denis Mamaluy

2022Scientific Reports17 citationsDOIOpen Access PDF

Abstract

We present an open-system quantum-mechanical 3D real-space study of the conduction band structure and conductive properties of two semiconductor systems, interesting for their beyond-Moore and quantum computing applications: phosphorus [Formula: see text]-layers and P [Formula: see text]-layer tunnel junctions in silicon. In order to evaluate size quantization effects on the conductivity, we consider two principal cases: nanoscale finite-width structures, used in transistors, and infinitely-wide structures, electrical properties of which are typically known experimentally. For devices widths [Formula: see text] nm, quantization effects are strong and it is shown that the number of propagating modes determines not only the conductivity, but the distinctive spatial distribution of the current-carrying electron states. For [Formula: see text] nm, the quantization effects practically vanish and the conductivity tends to the infinitely-wide device values. For tunnel junctions, two distinct conductivity regimes are predicted due to the strong conduction band quantization.

Topics & Concepts

Quantization (signal processing)ConductivityCondensed matter physicsThermal conductionSemiconductorTransistorPhysicsQuantumElectrical resistivity and conductivityElectrical conductorMaterials scienceQuantum mechanicsMathematicsAlgorithmVoltageQuantum and electron transport phenomenaSemiconductor materials and devicesAdvancements in Semiconductor Devices and Circuit Design
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