| Autor: |
Efremova, Maria V., Boer, Lotte, Edelmann, Laurenz, Ruijs, Lieke, Li, Jianing, Verschuuren, Marc A., Lavrijsen, Reinoud |
| Rok vydání: |
2024 |
| Předmět: |
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| Druh dokumentu: |
Working Paper |
| Popis: |
Particles with high anisotropy in their magnetic properties and shape are of increasing interest for mechanobiology, where transducing a remotely applied magnetic field vector to a local mechanical response is crucial. An outstanding challenge is quantifying the mechanical torque of a single nanoparticle, typically in the range of atto- to femto-Newton-meters (Nm). The magneto-mechanical torque manifests due to a misalignment of the external magnetic field vector with the built-in magnetic anisotropy axis, as opposed to a magnetic force, and complicates the measurement scheme. In this work, we developed a method using a commercially available Atomic Force Microscopy setup and cantilevers to quantify the torque generated by a single synthetic antiferromagnetic (SAF) nanoplatelet with high perpendicular magnetic anisotropy. Specifically, we measured 1.6$\pm$0.6$\cdot$10$^{-15}$ Nm torque while applying 373$\pm$5 mT field at 12$\pm$2 degrees to the built-in anisotropy axis exerted by a single circular SAF nanoplatelet with 1.88 $\mu$m diameter and 72 nm thickness, naively translating to a $\approx$ 1.7 nN maximum force at the nanoplatelet apex. This measured torque and derived force of the SAF nanoplatelets is strong enough for most applications in mechanobiology; for example, it can be used to rupture (cancer) cell membranes. Moreover, SAF nanoplatelets open a route for easy tuning of the built-in magnetic anisotropy and size, reducing the torque and allowing for small mechanical stimuli for ion channel activation. This work presents a straightforward and widely applicable method for characterizing magnetic particles' mechanical transduction, which is applied to SAF nanoplatelets with a high PMA. |
| Databáze: |
arXiv |
| Externí odkaz: |
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