Gandía Aguado, David
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Gandía Aguado
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David
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Ciencias
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InaMat2. Instituto de Investigación en Materiales Avanzados y Matemáticas
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Publication Open Access Exploring the complex interplay of anisotropies in magnetosomes of magnetotactic bacteria(American Chemical Society, 2025-04-14) Gandía Aguado, David; Marcano, Lourdes; Gandarias, Lucía; Gubieda, Alicia G.; García-Prieto, Ana; Fernández Barquín, Luis; Espeso, José Ignacio; Martín Jefremovas, E.; Orue, Iñaki; Abad Díaz de Cerio, Ana; Fernández-Gubieda, María Luisa; Alonso Masa, Javier; Ciencias; Zientziak; Institute for Advanced Materials and Mathematics - INAMAT2Magnetotactic bacteria (MTB) are at the forefront of interest for biophysics applications, especially in cancer treatment. Magnetosomes biomineralized by these bacteria are high-quality magnetic nanoparticles that form chains inside the MTB through a highly reproducible, naturally driven process. In particular, Magnetovibrio blakemorei and Magnetospirillum gryphiswaldense MTB exhibit distinct magnetosome morphologies: truncated hexa-octahedral and cuboctahedral shapes, respectively. Despite having identical compositions (magnetite, Fe3O4) and dimensions within a similar size range, their effective uniaxial anisotropies significantly differ at room temperature, with M. blakemorei exhibiting ∼25 kJ/m3 and M. gryphiswaldense ∼ 11 kJ/m3. This prominent anisotropy variance provides a unique opportunity to explore the role of magnetic anisotropy contributions in the magnetic responses of these magnetite-based nanoparticles. This study systematically investigates these responses by examining static magnetization as a function of temperature (M vs T, 5 mT) and magnetic field (M vs μ0H, up to 1 T). Above the Verwey transition temperature (∼110 K), the effective anisotropy is dominated by the shape anisotropy contribution, notably increasing the coercivity for M. blakemorei by up to twofold compared to M. gryphiswaldense. However, below this temperature, the effective uniaxial anisotropy rapidly increases in a nonmonotonic way, significantly changing the magnetic behavior. Computational simulations using a dynamic Stoner–Wohlfarth model provide insights into these phenomena, enabling careful interpretation of experimental data. According to our simulations, below the Verwey temperature, a uniaxial magnetocrystalline contribution progressively emerges, peaking around 22–24 kJ/m3 at 5 K. Our study reveals the complex evolution of magnetocrystalline contributions, which dominate the magnetic response of magnetosomes below the Verwey temperature. This demonstrates the profound impact of anisotropic properties on the magnetic behaviors and applications of magnetite-based nanoparticles and highlights the exceptional utility of magnetosomes as ideal model systems for studying the complex interplay of anisotropies in magnetite-based nanoparticles.Publication Open Access U-shape magnetostrictive harvester: design and experimental validation(IEEE, 2024-07-05) Gandía Aguado, David; Garayo Urabayen, Eneko; Beato López, Juan Jesús; Royo Silvestre, Isaac; Gómez Polo, Cristina; Ciencias; Zientziak; Institute for Advanced Materials and Mathematics - INAMAT2Electromagnetic vibrational harvesters stand out due to their high-power density, long-life robust structure and low-cost design. Moreover, they can be designed using magnetostrictive materials. The mechanical vibrations cause stress on the magnetostrictive material, leading to variations in its magnetization. This, in turn, induces an electromotive force (EMF) in a well-designed pick-up coil system, thereby transforming mechanical energy into electrical energy. In spite of the potentiality of these electromagnetic harvesters, their practical implementation is limited due to the difficulties in the design optimization in terms of the device dimensions, effective stresses on the magnetostrive material, distribution and magnetic field strength of the permanent magnets and pick-up coil characteristics. Finite Element Methods (FEM) enable the estimation of the induced voltage and thus the output power as a function of harvester design parameters, allowing us to experiment with different configurations and identify optimal parameters.