Focused-Electron-Beam Engineering of 3D Magnetic Nanowires

Magén, Cesar; Pablo-Navarro, Javier

doi:10.3390/nano11020402

Cited by 15 publications

(16 citation statements)

References 77 publications

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“…In particular, slow lateral movement is the key for real 3D architectures as subsequent nanovolumes get vertically deposited with a small lateral displacement. This approach is denoted as 3D-FEBID (or 3D-nanoprinting) and allows additive, direct-write fabrication of even complex geometries and therefore evolved into a very powerful and flexible 3D-nanoprinting technology with applications in nanomagnetics, , plasmonics, and nanoprobe fabrication for scanning probe microscopy, , to name a few. In the past, however, most fabricated 3D structures were meshed or wireframe-like , meaning individual nanowires, which are connected at specific points in 3D space to form certain target structures .…”

Section: Introductionmentioning

confidence: 99%

Expanding FEBID-Based 3D-Nanoprinting toward Closed High-Fidelity Nanoarchitectures

Weitzer

Huth

Kothleitner

et al. 2022

ACS Appl. Electron. Mater.

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3D-nanoprinting via focused electron beam induced deposition (FEBID) is a highly flexible additive-fabrication technique that has gained importance in the past few years for its variable design possibilities on the micro and nanoscale. In this work, we show the transition from mesh-like toward closed (sheetlike) structures and the development of necessary compensations (height correction, temperature compensation, and proximity correction) to minimize deviations between the target structure and the actual deposit. To accomplish this, we investigate the growth behavior, the influence of beam heating, and the electron trajectories in extensive experimental series as well as finite-difference simulations. Out of this, we derive a modular Python tool taking all compensations into account, enabling the controlled and accurate deposition of 3D-nanostructures in an individually adjusted layer-by-layer approach. This approach forms the basis for accurately fabricating closed, sheet-like objects on the nanoscale and lays the foundation for depositing complex nanoarchitectures for various applications in research and development.

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Section: Introductionmentioning

confidence: 99%

Expanding FEBID-Based 3D-Nanoprinting toward Closed High-Fidelity Nanoarchitectures

Weitzer

Huth

Kothleitner

et al. 2022

ACS Appl. Electron. Mater.

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“…The navigation of the electron beam in the XY-plane and the precise adjustment of the dwell times (deposition times in each individual position) ultimately generate the deposit morphology [ 17 ]. Especially 3D-FEBID, where true three-dimensional architectures are built via slow lateral movements, is a very powerful tool that enables novel application concepts for plasmonics [ 12 ], nanomagnetics [ 18 , 19 , 20 ] and 3D-nanoprobe fabrication for scanning probe microscopy [ 21 , 22 ], among others. The technique that was mainly used to build mesh-like structures in the past [ 23 , 24 ], was recently expanded to closed or sheet-like objects, which strongly improved its options in terms of design flexibility [ 25 , 26 , 27 , 28 ].…”

Section: Introductionmentioning

confidence: 99%

Controlled Morphological Bending of 3D-FEBID Structures via Electron Beam Curing

et al. 2022

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Focused electron beam induced deposition (FEBID) is one of the few additive, direct-write manufacturing techniques capable of depositing complex 3D nanostructures. In this work, we explore post-growth electron beam curing (EBC) of such platinum-based FEBID deposits, where free-standing, sheet-like elements were deformed in a targeted manner by local irradiation without precursor gas present. This process diminishes the volumes of exposed regions and alters nano-grain sizes, which was comprehensively characterized by SEM, TEM and AFM and complemented by Monte Carlo simulations. For obtaining controlled and reproducible conditions for smooth, stable morphological bending, a wide range of parameters were varied, which will here be presented as a first step towards using local EBC as a tool to realize even more complex nano-architectures, beyond current 3D-FEBID capabilities, such as overhanging structures. We thereby open up a new prospect for future applications in research and development that could even be further developed towards functional imprinting.

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“…This development has been focused on the optimization of thin magnetic patterns in 2D. More recently, the investigation has been extended to 3D FEBID magnetic deposits [33][34][35], spurred on by promising applications in scanning probe techniques, such as Magnetic Force Microscopy (MFM) [36] and Magnetic Resonance Force Microscopy (MRFM) [37], racetrack-type magnetic memories [14], Hall sensors [11,22], nanomagnetic logic circuits [36,38], superconducting vortex lattice pinning [39], remote magneto-mechanical actuation [40], etc. However, whereas FEBID flexibility allows the production of challenging structures with sophisticated geometries [7,10,12], many applications can be based on the simplest objects, such as vertical straight nanowires.…”

Section: Introduction To Febid and Mfmmentioning

confidence: 99%

Magnetic Functionalization of Scanning Probes by Focused Electron Beam Induced Deposition Technology

2021

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The fabrication of nanostructures with high resolution and precise control of the deposition site makes Focused Electron Beam Induced Deposition (FEBID) a unique nanolithography process. In the case of magnetic materials, apart from the FEBID potential in standard substrates for multiple applications in data storage and logic, the use of this technology for the growth of nanomagnets on different types of scanning probes opens new paths in magnetic sensing, becoming a benchmark for magnetic functionalization. This work reviews the recent advances in the integration of FEBID magnetic nanostructures onto cantilevers to produce advanced magnetic sensing devices with unprecedented performance.

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Focused-Electron-Beam Engineering of 3D Magnetic Nanowires

Cited by 15 publications

References 77 publications

Expanding FEBID-Based 3D-Nanoprinting toward Closed High-Fidelity Nanoarchitectures

Expanding FEBID-Based 3D-Nanoprinting toward Closed High-Fidelity Nanoarchitectures

Controlled Morphological Bending of 3D-FEBID Structures via Electron Beam Curing

Magnetic Functionalization of Scanning Probes by Focused Electron Beam Induced Deposition Technology

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