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You searched for +publisher:"University of Notre Dame" +contributor:("X. Sharon Hu, Committee Chair"). Showing records 1 – 2 of 2 total matches.

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University of Notre Dame

1. Shiliang Liu. Design and Modeling for Nanomagnet Logic Circuits and Architectures</h1>.

Degree: PhD, Computer Science and Engineering, 2013, University of Notre Dame

As a possible replacement or supplementary technology for Complimentary Metal- Oxide-Semiconductor (CMOS) technology, Nanomagnet Logic (NML) employs near- est neighbor dipole-dipole interactions for logic operations. NML has the benefits of low power consumption, non-volatility, radiation hardness, etc. To leverage the benefits of NML, the research in this dissertation has helped advance the state of the art of design and modeling of NML circuits and architectures. The work in this dissertation has shown that the integration of NML with CMOS is feasible through magnetic-electrical interface (MEI) designs based on magnetic tunnel junction. These MEI designs are especially important as hybrid NML and CMOS architectures are approached. As an extension from the MEI work, designs of magnetic content ad- dressable memory based on current induced domain wall motion are compact and energy efficient without sacrificing speed, overcoming a major challenge faced by content addressable memory designs. As much of NML studies need designs and simulations, an NML layout design methodology using energy states tackles the side effect of next nearest neighbor couplings in NML circuits, and a software package developed for assisting simulation is practical and effective for automating NML sim- ulation processes and saving time. Advisors/Committee Members: Michael T. Niemier, Committee Member, Joseph J. Nahas, Committee Member, X. Sharon Hu, Committee Chair, Gyorgy Csaba, Committee Co-Chair, Gary H. Bernstein, Committee Member.

Subjects/Keywords: Simulation; Magnetic-Electrical Interface; Nanomagnet Logic; Modeling; Magnetic Tunnel Junction; Design

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APA · Chicago · MLA · Vancouver · CSE | Export to Zotero / EndNote / Reference Manager

APA (6th Edition):

Liu, S. (2013). Design and Modeling for Nanomagnet Logic Circuits and Architectures</h1>. (Doctoral Dissertation). University of Notre Dame. Retrieved from https://curate.nd.edu/show/tb09j388g40

Chicago Manual of Style (16th Edition):

Liu, Shiliang. “Design and Modeling for Nanomagnet Logic Circuits and Architectures</h1>.” 2013. Doctoral Dissertation, University of Notre Dame. Accessed November 17, 2019. https://curate.nd.edu/show/tb09j388g40.

MLA Handbook (7th Edition):

Liu, Shiliang. “Design and Modeling for Nanomagnet Logic Circuits and Architectures</h1>.” 2013. Web. 17 Nov 2019.

Vancouver:

Liu S. Design and Modeling for Nanomagnet Logic Circuits and Architectures</h1>. [Internet] [Doctoral dissertation]. University of Notre Dame; 2013. [cited 2019 Nov 17]. Available from: https://curate.nd.edu/show/tb09j388g40.

Council of Science Editors:

Liu S. Design and Modeling for Nanomagnet Logic Circuits and Architectures</h1>. [Doctoral Dissertation]. University of Notre Dame; 2013. Available from: https://curate.nd.edu/show/tb09j388g40


University of Notre Dame

2. Jarett T DeAngelis. Spin-Valve Interface for Magnetic Quantum Dot Cellular Automata</h1>.

Degree: MSin Computer Science and Engineering, Computer Science and Engineering, 2008, University of Notre Dame

CMOS technology is reaching its physical limits in terms of scaling, and this is leading many researchers to investigate alternative computing technologies. As the industry moves away from CMOS and toward other technologies, it will be necessary to explore new ways of transporting data. This thesis explores a novel application of two relatively new technologies, magnetic quantum dot cellular automata and spin-valve technology, with a focus on existing work in magnetic random access memory. To move forward in the real-life implementation of new computing technologies, some new engineering will be necessary to bridge the gap between extant CMOS computing technology and this new area of magnetic logic and storage. With a view toward promoting this, the spin-valve-based Magnetic- Electric Interface (MEI) was developed. Topics covered in this thesis include the state of the art of the technology behind MQCA as well as the reasons for using it, spin-valve technology such as MRAM, the reasons for development of, rationale for and design behind the MEI, and potential applications of the technology for development of MQCA computing systems. Advisors/Committee Members: X. Sharon Hu, Committee Chair, Michael Niemier, Committee Member, Gary H. Bernstein, Committee Member.

Subjects/Keywords: qca; gmr; mqca; nanomagnets; mram; tmr

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APA · Chicago · MLA · Vancouver · CSE | Export to Zotero / EndNote / Reference Manager

APA (6th Edition):

DeAngelis, J. T. (2008). Spin-Valve Interface for Magnetic Quantum Dot Cellular Automata</h1>. (Masters Thesis). University of Notre Dame. Retrieved from https://curate.nd.edu/show/tb09j388f9d

Chicago Manual of Style (16th Edition):

DeAngelis, Jarett T. “Spin-Valve Interface for Magnetic Quantum Dot Cellular Automata</h1>.” 2008. Masters Thesis, University of Notre Dame. Accessed November 17, 2019. https://curate.nd.edu/show/tb09j388f9d.

MLA Handbook (7th Edition):

DeAngelis, Jarett T. “Spin-Valve Interface for Magnetic Quantum Dot Cellular Automata</h1>.” 2008. Web. 17 Nov 2019.

Vancouver:

DeAngelis JT. Spin-Valve Interface for Magnetic Quantum Dot Cellular Automata</h1>. [Internet] [Masters thesis]. University of Notre Dame; 2008. [cited 2019 Nov 17]. Available from: https://curate.nd.edu/show/tb09j388f9d.

Council of Science Editors:

DeAngelis JT. Spin-Valve Interface for Magnetic Quantum Dot Cellular Automata</h1>. [Masters Thesis]. University of Notre Dame; 2008. Available from: https://curate.nd.edu/show/tb09j388f9d

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