Reliability analysis of magnetic logic interconnect wire subjected to magnet edge imperfections

Nanomagnet logic (NML) devices have been proposed as one of the best candidates for the next generation of integrated circuits thanks to its substantial advantages of nonvolatility, radiation hardening and potentially low power. In this article, errors of nanomagnetic interconnect wire subjected to magnet edge imperfections have been evaluated for the purpose of reliable logic propagation. The missing corner defects of nanomagnet in the wire are modeled with a triangle, and the interconnect fabricated with various magnetic materials is thoroughly investigated by micromagnetic simulations under different corner defect amplitudes and device spacings. The results show that as the defect amplitude increases, the success rate of logic propagation in the interconnect decreases. More results show that from the interconnect wire fabricated with materials, iron demonstrates the best defect tolerance ability among three representative and frequently used NML materials, also logic transmission errors can be mitigated by adjusting spacing between nanomagnets. These findings can provide key technical guides for designing reliable interconnects.

[1]  D Petit,et al.  Magnetic Domain-Wall Logic , 2005, Science.

[2]  Dong Ik Suh,et al.  A Single Magnetic Tunnel Junction Representing the Basic Logic Functions—NAND, NOR, and IMP , 2015, IEEE Electron Device Letters.

[3]  Supriyo Bandyopadhyay,et al.  Experimental Clocking of Nanomagnets with Strain for Ultralow Power Boolean Logic. , 2014, Nano letters.

[4]  W. Porod,et al.  On-Chip Clocking of Nanomagnet Logic Lines and Gates , 2012, IEEE Transactions on Nanotechnology.

[5]  A Imre,et al.  Majority Logic Gate for Magnetic Quantum-Dot Cellular Automata , 2006, Science.

[6]  G. Tóth,et al.  Quantum computing with quantum-dot cellular automata , 2001 .

[7]  D. Litvinov,et al.  Micromagnetics of signal propagation in magnetic cellular logic data channels , 2008 .

[8]  Wolfgang Porod,et al.  Device and Architecture Outlook for Beyond CMOS Switches , 2010, Proceedings of the IEEE.

[9]  V. Roychowdhury,et al.  Performance of Magnetic Quantum Cellular Automata and Limitations Due to Thermal Noise , 2009, IEEE Transactions on Nanotechnology.

[10]  L. Hu,et al.  Micromagnetic Investigation of the S-State Reconfigurable Logic Element , 2012, IEEE Transactions on Magnetics.

[11]  Sanjukta Bhanja,et al.  Landauer Clocking for Magnetic Cellular Automata (MCA) Arrays , 2011, IEEE Transactions on Very Large Scale Integration (VLSI) Systems.

[12]  Li Cai,et al.  Micromagnetic simulation of exploratory magnetic logic device with missing corner defect , 2015 .

[13]  W. Porod,et al.  Shape Engineering for Controlled Switching With Nanomagnet Logic , 2012, IEEE Transactions on Nanotechnology.

[14]  W. Porod,et al.  Nanomagnet Fabrication Using Nanoimprint Lithography and Electrodeposition , 2013, IEEE Transactions on Nanotechnology.

[15]  Madalina Colci,et al.  Dipolar Coupling Between Nanopillar Spin Valves and Magnetic Quantum Cellular Automata Arrays , 2012, IEEE Transactions on Nanotechnology.

[16]  Li Cai,et al.  Reliability and Performance Evaluation of QCA Devices With Rotation Cell Defect , 2012, IEEE Transactions on Nanotechnology.

[17]  G. Csaba,et al.  Compensation of orange-peel coupling effect in magnetic tunnel junction free layer via shape engineering for nanomagnet logic applications , 2014 .

[18]  R. Allenspach,et al.  Magnetologic devices fabricated by nanostencil lithography , 2010, Nanotechnology.

[19]  Kaushik Roy,et al.  Spin-Transfer Torque Devices for Logic and Memory: Prospects and Perspectives , 2016, IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems.