Physics-based modeling of valence change mechanism memristor
As conventional semiconductor devices encounter limitations, such as the memory wall and power wall, as the Moore’s Law comes to an end soon. A promising semiconductor device known as the “memristor” has emerged to overcome these limitations. The word "memristor" comes from two words which...
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sg-ntu-dr.10356-1736482024-02-23T15:44:10Z Physics-based modeling of valence change mechanism memristor Wei, Mingjiang Zhou Xing School of Electrical and Electronic Engineering RWTH Aachen Technical University of Munich EXZHOU@ntu.edu.sg Engineering As conventional semiconductor devices encounter limitations, such as the memory wall and power wall, as the Moore’s Law comes to an end soon. A promising semiconductor device known as the “memristor” has emerged to overcome these limitations. The word "memristor" comes from two words which are "memory" and "resistor". Memristors have several key features including high density, low power consumption, excellent scalability, and fast operation speed, which making them highly desirable and feasible as a promising device for the future AI hardware and novel memory device. More importantly, the memristor array's neuromorphic property makes it analogous to a single synapse in the human brain. This neuromorphic potential positions memristors to play a significant role in neuromorphic integrated circuits. Nevertheless, memristors still has some challenges for further investigation and research, particularly in developing simulation models for these devices. Simulation methods serve as essential bridges, enabling the translation of continuous real-world physical phenomenon into the numerical realm. The numerical models in this dissertation enable the discretization of continuous equations, such as the Poisson and continuity equations of charge carriers, effectively rendering them interpretable by computers while ensuring an accurate fit with the experimental data. In this dissertation, we present a finite volume method simulation model implemented in C++ for the SrTiO3 VCM memristor. This research strives to enhance our understanding of memristors and the physical mechanism and simulation algorithm of it. Keywords: Memristor, VCM, Simulation model. Master's degree 2024-02-21T02:50:02Z 2024-02-21T02:50:02Z 2023 Thesis-Master by Coursework Wei, M. (2023). Physics-based modeling of valence change mechanism memristor. Master's thesis, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/173648 https://hdl.handle.net/10356/173648 en application/pdf Nanyang Technological University |
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Engineering Wei, Mingjiang Physics-based modeling of valence change mechanism memristor |
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As conventional semiconductor devices encounter limitations, such as the memory wall and power wall, as the Moore’s Law comes to an end soon. A promising semiconductor device known as the “memristor” has emerged to overcome these limitations. The word "memristor" comes from two words which are "memory" and "resistor". Memristors have several key features including high density, low power consumption, excellent scalability, and fast operation speed, which making them highly desirable and feasible as a promising device for the future AI hardware and novel memory device. More importantly, the memristor array's neuromorphic property makes it analogous to a single synapse in the human brain. This neuromorphic potential positions memristors to play a significant role in neuromorphic integrated circuits. Nevertheless, memristors still has some challenges for further investigation and research, particularly in developing simulation models for these devices. Simulation methods serve as essential bridges, enabling the translation of continuous real-world physical phenomenon into the numerical realm. The numerical models in this dissertation enable the discretization of continuous equations, such as the Poisson and continuity equations of charge carriers, effectively rendering them interpretable by computers while ensuring an accurate fit with the experimental data. In this dissertation, we present a finite volume method simulation model implemented in C++ for the SrTiO3 VCM memristor. This research strives to enhance our understanding of memristors and the physical mechanism and simulation algorithm of it.
Keywords: Memristor, VCM, Simulation model. |
| author2 |
Zhou Xing |
| author_facet |
Zhou Xing Wei, Mingjiang |
| format |
Thesis-Master by Coursework |
| author |
Wei, Mingjiang |
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Wei, Mingjiang |
| title |
Physics-based modeling of valence change mechanism memristor |
| title_short |
Physics-based modeling of valence change mechanism memristor |
| title_full |
Physics-based modeling of valence change mechanism memristor |
| title_fullStr |
Physics-based modeling of valence change mechanism memristor |
| title_full_unstemmed |
Physics-based modeling of valence change mechanism memristor |
| title_sort |
physics-based modeling of valence change mechanism memristor |
| publisher |
Nanyang Technological University |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/173648 |
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