Low power on-chip clocking for nanomagnetic logic circuits

Low power on-chip clocking for nanomagnetic logic circuits

It is demonstrated that it is possible to switch the magnetisation of nanomagnets by employing the exchange interaction between magnets. This can implement on-chip clocking for nanomagnetic logic circuits by using a current-carrying copper wire circularly wrapped by ferromagnetic cladding. This sche...

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Veröffentlicht in:Micro & nano letters 2014-10, Vol.9 (10), p.753-755
Hauptverfasser: Zhang, Mingliang, Cai, Li, Yang, Xiaokuo, Cui, Huanqing, Wang, Zhichun, Feng, Chaowen, Wang, Sen
Format: Artikel
Sprache:eng
Schlagworte:
Cladding
claddings
Copper
current‐carrying copper wire
Energy management
Exchange
exchange interaction
exchange interactions (electron)
external magnetic field
ferromagnetic cladding
ferromagnetic materials
Ferromagnetism
functional state
Logic circuits
low power on‐chip clocking
magnetic switching
magnetisation
magnetisation switching
Maxwell simulation
micromagnetic simulation
micromagnetics
nanomagnetic chain
nanomagnetic logic circuits
nanomagnetics
Nanostructure
power consumption
Regular papers
Simulation
Wire
yoked cladding clocking
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Beschreibung
Zusammenfassung:It is demonstrated that it is possible to switch the magnetisation of nanomagnets by employing the exchange interaction between magnets. This can implement on-chip clocking for nanomagnetic logic circuits by using a current-carrying copper wire circularly wrapped by ferromagnetic cladding. This scheme is potentially more energy efficient than yoked cladding clocking using an external magnetic field for magnetisation switching. Maxwell simulation shows that current flowing through copper wire can be reduced by about one hundred times compared with yoked clocking, which means power consumption could be lowered by 104 times. Micromagnetic simulation shows that the nanomagnetic chain aligned on the proposed clocking can achieve a correct functional state.
ISSN:1750-0443
1750-0443
DOI:10.1049/mnl.2014.0323