Drift-diffusion and computational electronics - still going strong after 40 years!

An important class of biological molecules-proteins called ionic channels–conduct ions (like Na+, K+, Cl-) through a narrow tunnel of fixed charge (‘doping’). Ionic channels are the main pathway by which substances move into cells and so are of great biological and medical importance: a substantial fraction of all drugs used by physicians act on channels. Channels can be studied in the tradition of computational electronics. Drift diffusion equations form an adequate model of IV relations of 6 different channel proteins in ̴ 10 solutions over ±150 mV. Ionic channels can also be studied with the powerful techniques of molecular biology. Atoms can be modified one at a time and the location of every atom can be determined. Ionic channels are natural nanotubes that can be controlled more precisely and easily than physical nanostructures but biologists need help if realistic simulations are to be done atomic detail.

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Beyond 'simple' decision making: What can the drift diffusion framework tell us about cognitive control?

PsycEXTRA Dataset ◽

10.1037/e636952013-019 ◽

2013 ◽

Author(s):

Boris Burle ◽

Eric-Jan Wagenmakers

Keyword(s):

Decision Making ◽

Cognitive Control ◽

Drift Diffusion

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Supplemental Material for Caution Follows Fear: Evidence From Hierarchical Drift Diffusion Modelling

Emotion ◽

10.1037/emo0000342.supp ◽

2017 ◽

Keyword(s):

Drift Diffusion ◽

Diffusion Modelling

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Supplemental Material for Using Drift Diffusion Modeling to Understand Inattentive Behavior in Preterm and Term-Born Children

Neuropsychology ◽

10.1037/neu0000590.supp ◽

2019 ◽

Keyword(s):

Diffusion Modeling ◽

Drift Diffusion

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Simulation of ion migration in perovskite solar cells using a kinetic Monte Carlo/drift diffusion numerical model and analysis of the impact on device performance

10.29363/nanoge.hopv.2018.099 ◽

2018 ◽

Author(s):

Alessio Gagliardi ◽

Ajay Singh ◽

Waldemar Kaiser

Keyword(s):

Monte Carlo ◽

Solar Cells ◽

Numerical Model ◽

Kinetic Monte Carlo ◽

Perovskite Solar Cells ◽

Device Performance ◽

Drift Diffusion ◽

Ion Migration ◽

The Impact

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Terahertz Radiators Based on Si~3C-SiC MQW IMPATT Diodes

Nanoscience &Nanotechnology-Asia ◽

10.2174/2210681209666190807154014 ◽

2020 ◽

Vol 10 (4) ◽

pp. 501-506

Author(s):

Monisha Ghosh ◽

Arindam Biswas ◽

Aritra Acharyya

Keyword(s):

High Frequency ◽

Multiple Quantum Well ◽

Multiple Quantum ◽

Noise Performance ◽

Rf Power ◽

Drift Diffusion ◽

Frequency Bands ◽

Atmospheric Window ◽

Lower Noise ◽

Impatt Diodes

Aims:: The potentiality of Multiple Quantum Well (MQW) Impacts Avalanche Transit Time (IMPATT) diodes based on Si~3C-SiC heterostructures as possible terahertz radiators have been explored in this paper. Objective:: The static, high frequency and noise performance of MQW devices operating at 94, 140, and 220 GHz atmospheric window frequencies, as well as 0.30 and 0.50 THz frequency bands, have been studied in this paper. Methods: The simulation methods based on a Self-Consistent Quantum Drift-Diffusion (SCQDD) model developed by the authors have been used for the above-mentioned studies. Results: Thus the noise performance of MQW DDRs will be obviously better as compared to the flat Si DDRs operating at different mm-wave and THz frequencies. Conclusion:: Simulation results show that Si~3C-SiC MQW IMPATT sources are capable of providing considerably higher RF power output with the significantly lower noise level at both millimeter-wave (mm-wave) and terahertz (THz) frequency bands as compared to conventional flat Si IMPATT sources.

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