Introduction and pinning of domain walls in 50nm NiFe constrictions using local and external magnetic fields

AbstractAtomically sharp domain walls in ferroelectrics are considered as an ideal platform to realize easy-to-reconfigure nanoelectronic building blocks, created, manipulated and erased by external fields. However, conductive domain walls have been exclusively observed in oxides, where domain wall mobility and conductivity is largely influenced by stoichiometry and defects. Here, we report on giant conductivity of domain walls in the non-oxide ferroelectric GaV4S8. We observe conductive domain walls forming in zig-zagging structures, that are composed of head-to-head and tail-to-tail domain wall segments alternating on the nanoscale. Remarkably, both types of segments possess high conductivity, unimaginable in oxide ferroelectrics. These effectively 2D domain walls, dominating the 3D conductance, can be mobilized by magnetic fields, triggering abrupt conductance changes as large as eight orders of magnitude. These unique properties demonstrate that non-oxide ferroelectrics can be the source of novel phenomena beyond the realm of oxide electronics.

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Suppression of the intrinsic stochastic pinning of domain walls in magnetic nanostripes

Nature Communications ◽

10.1038/ncomms1575 ◽

2011 ◽

Vol 2 (1) ◽

Cited By ~ 30

Author(s):

Manuel Muñoz ◽

José L. Prieto

Keyword(s):

Domain Walls ◽

Pinning Of Domain Walls

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Information storage in permalloy modulated magnetic nanowires

Scientific Reports ◽

10.1038/s41598-021-00165-1 ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Guidobeth Sáez ◽

Pablo Díaz ◽

Eduardo Cisternas ◽

Eugenio E. Vogel ◽

Juan Escrig

Keyword(s):

Magnetic Material ◽

Phase Diagram ◽

Magnetic Fields ◽

Domain Walls ◽

Wire Diameter ◽

Information Storage ◽

Magnetic Nanowires ◽

The Wire ◽

The Stability ◽

Cylindrical Wire

AbstractA long piece of magnetic material shaped as a central cylindrical wire (diameter $$d=50$$ d = 50 nm) with two wider coaxial cylindrical portions (diameter $$D=90$$ D = 90 nm and thickness $$t=100$$ t = 100 nm) defines a bimodulated nanowire. Micromagnetism is invoked to study the equilibrium energy of the system under the variations of the positions of the modulations along the wire. The system can be thought of as composed of five independent elements (3 segments and 2 modulations) leading to $$2^5=32$$ 2 5 = 32 possible different magnetic configurations, which will be later simplified to 4. We investigate the stability of the configurations depending on the positions of the modulations. The relative chirality of the modulations has negligible contributions to the energy and they have no effect on the stability of the stored configuration. However, the modulations are extremely important in pinning the domain walls that lead to consider each segment as independent from the rest. A phase diagram reporting the stability of the inscribed magnetic configurations is produced. The stability of the system was then tested under the action of external magnetic fields and it was found that more than 50 mT are necessary to alter the inscribed information. The main purpose of this paper is to find whether a prototype like this can be complemented to be used as a magnetic key or to store information in the form of firmware. Present results indicate that both possibilities are feasible.

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Driving chiral domain walls in antiferromagnets using rotating magnetic fields

Physical Review B ◽

10.1103/physrevb.97.184418 ◽

2018 ◽

Vol 97 (18) ◽

Cited By ~ 9

Author(s):

Keming Pan ◽

Lingdi Xing ◽

H. Y. Yuan ◽

Weiwei Wang

Keyword(s):

Magnetic Fields ◽

Domain Walls ◽

Rotating Magnetic Fields

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Nanoscale strain engineering of giant pseudo-magnetic fields, valley polarization, and topological channels in graphene

Science Advances ◽

10.1126/sciadv.aat9488 ◽

2020 ◽

Vol 6 (19) ◽

pp. eaat9488 ◽

Cited By ~ 6

Author(s):

C.-C. Hsu ◽

M. L. Teague ◽

J.-Q. Wang ◽

N.-C. Yeh

Keyword(s):

Magnetic Fields ◽

Domain Walls ◽

Quantum Hall ◽

Strain Engineering ◽

Scanning Tunneling ◽

Monolayer Graphene ◽

Tunneling Microscopy ◽

One Dimensional ◽

Valley Polarization ◽

Topological States

The existence of nontrivial Berry phases associated with two inequivalent valleys in graphene provides interesting opportunities for investigating the valley-projected topological states. Examples of such studies include observation of anomalous quantum Hall effect in monolayer graphene, demonstration of topological zero modes in “molecular graphene” assembled by scanning tunneling microscopy, and detection of topological valley transport either in graphene superlattices or at bilayer graphene domain walls. However, all aforementioned experiments involved nonscalable approaches of either mechanically exfoliated flakes or atom-by-atom constructions. Here, we report an approach to manipulating the topological states in monolayer graphene via nanoscale strain engineering at room temperature. By placing strain-free monolayer graphene on architected nanostructures to induce global inversion symmetry breaking, we demonstrate the development of giant pseudo-magnetic fields (up to ~800 T), valley polarization, and periodic one-dimensional topological channels for protected propagation of chiral modes in strained graphene, thus paving a pathway toward scalable graphene-based valleytronics.

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