Magnetism and Spin Transport of Carbon Chain between Armchair Graphene Nanoribbon electrodes

TL;DR

This study investigates the magnetic and spin transport properties of odd and even carbon chains between graphene nanoribbon electrodes, revealing intrinsic magnetism in odd chains and spin-polarized transmission without external magnetic fields.

Contribution

It demonstrates that odd-numbered carbon chains exhibit intrinsic magnetic moments and spin-polarized transport, with properties depending on chain length and position, without external magnetic fields.

Findings

Odd-numbered chains show intrinsic magnetic moments.

Full spin polarization near Fermi energy in odd chains.

Transport properties depend on chain length and position.

Abstract

The magnetic and spin transport properties of a carbon chain between two armchair graphene nanoribbon (AGNR) electrodes were studied using tight-binding Hamiltonian, mean-field Hubbard model and Landauer-Butikker formalism. The results showed that only odd-numbered carbon chains show intrinsic magnetic moments in chain-graphene junctions. It was also found that the electronic, magnetic and spin transport properties of carbon chain-graphene junctions strongly depend on the position and the length of the carbon chains between AGNR electrodes. Interestingly, we found a fully spin-polarized transmission near the Fermi energy in all odd-numbered carbon chain-graphene junctions, regardless of their lengths and without any magnetic field and magnetic electrodes.