4.6 Article

Space-charge limited current in nanodiodes: Ballistic, collisional, and dynamical effects

Journal

JOURNAL OF APPLIED PHYSICS
Volume 129, Issue 10, Pages -

Publisher

AIP Publishing
DOI: 10.1063/5.0042355

Keywords

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Funding

  1. Air Force Office of Scientific Research (AFOSR) [FA9550-18-1-0061, FA9550-20-1-0409]
  2. Office of Naval Research (ONR) [N00014-20-1-2681]
  3. Singapore Ministry of Education (MOE) Tier 2 Grant [2018-T2-1-007]
  4. U.S. Office of Naval Research Global (ONRG) Grant [N62909-19-1-2047]
  5. Office of Naval Research [N00014-17-1-2702]
  6. Air Force Office of Scientific Research [FA9550-18-1-0218, FA9550-19-1-0101, FA9550-18-1-7011]

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This Perspective reviews the fundamental physics of space-charge interactions and recent developments in the space-charge limited current model. It focuses on theoretical aspects such as nano-scale physics, time-dependent behaviors, higher-dimensional models, and transitions between electron emission mechanisms. Future directions in theoretical modeling and applications of SCLC are highlighted.
This Perspective reviews the fundamental physics of space-charge interactions that are important in various media: vacuum gap, air gap, liquids, and solids including quantum materials. It outlines the critical and recent developments since a previous review paper on diode physics [Zhang et al. Appl. Phys. Rev. 4, 011304 (2017)] with particular emphasis on various theoretical aspects of the space-charge limited current (SCLC) model: physics at the nano-scale, time-dependent, and transient behaviors; higher-dimensional models; and transitions between electron emission mechanisms and material properties. While many studies focus on steady-state SCLC, the increasing importance of fast-rise time electric pulses, high frequency microwave and terahertz sources, and ultrafast lasers has motivated theoretical investigations in time-dependent SCLC. We particularly focus on recent studies in discrete particle effects, temporal phenomena, time-dependent photoemission to SCLC, and AC beam loading. Due to the reduction in the physical size and complicated geometries, we report recent studies in multi-dimensional SCLC, including finite particle effects, protrusive SCLC, novel techniques for exotic geometries, and fractional models. Due to the importance of using SCLC models in determining the mobility of organic materials, this paper shows the transition of the SCLC model between classical bulk solids and recent two-dimensional (2D) Dirac materials. Next, we describe some selected applications of SCLC in nanodiodes, including nanoscale vacuum-channel transistors, microplasma transistors, thermionic energy converters, and multipactor. Finally, we conclude by highlighting future directions in theoretical modeling and applications of SCLC.

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