Publicacións en colaboración con investigadores/as de Instituto de Ciencia de Materiales de Madrid (49)

2024

  1. Beyond Newton's law of cooling in evaluating magnetic hyperthermia performance: a device-independent procedure

    Nanoscale Advances, Vol. 6, Núm. 16, pp. 4207-4218

  2. Reversible Alignment of Nanoparticles and Intracellular Vesicles During Magnetic Hyperthermia Experiments

    Advanced Functional Materials, Vol. 34, Núm. 40

2021

  1. How size, shape and assembly of magnetic nanoparticles give rise to different hyperthermia scenarios

    Nanoscale, Vol. 13, Núm. 37, pp. 15631-15646

  2. Selective Magnetic Nanoheating: Combining Iron Oxide Nanoparticles for Multi-Hot-Spot Induction and Sequential Regulation

    Nano Letters, Vol. 21, Núm. 17, pp. 7213-7220

2020

  1. An extraordinary chiral exchange-bias phenomenon: Engineering the sign of the bias field in orthogonal bilayers by a magnetically switchable response mechanism

    Nanoscale, Vol. 12, Núm. 2, pp. 1155-1163

  2. Combined Magnetoliposome Formation and Drug Loading in One Step for Efficient Alternating Current-Magnetic Field Remote-Controlled Drug Release

    ACS Applied Materials and Interfaces, Vol. 12, Núm. 4, pp. 4295-4307

  3. Controlling Magnetization Reversal and Hyperthermia Efficiency in Core-Shell Iron-Iron Oxide Magnetic Nanoparticles by Tuning the Interphase Coupling

    ACS Applied Nano Materials, Vol. 3, Núm. 5, pp. 4465-4476

  4. Disentangling local heat contributions in interacting magnetic nanoparticles

    Physical Review B, Vol. 102, Núm. 21

  5. Thermodynamics of interacting magnetic nanoparticles

    Physical Review B, Vol. 101, Núm. 22

2018

  1. Anisotropic magnetic nanoparticles for biomedicine: Bridging frequency separated AC-field controlled domains of actuation

    Physical Chemistry Chemical Physics, Vol. 20, Núm. 48, pp. 30445-30454

  2. Micromagnetic evaluation of the dissipated heat in cylindrical magnetic nanowires

    Applied Physics Letters, Vol. 112, Núm. 21

2017

  1. A colloidally stable water dispersion of Ni nanowires as an efficient: T 2-MRI contrast agent

    Journal of Materials Chemistry B, Vol. 5, Núm. 18, pp. 3338-3347

2016

  1. Distinguishing between heating power and hyperthermic cell-treatment efficacy in magnetic fluid hyperthermia

    Soft Matter, Vol. 12, Núm. 43, pp. 8815-8818

  2. In-situ particles reorientation during magnetic hyperthermia application: Shape matters twice

    Scientific Reports, Vol. 6

  3. Self-consistent description of spin-phonon dynamics in ferromagnets

    Physical Review B, Vol. 94, Núm. 1

2015

  1. A Single Picture Explains Diversity of Hyperthermia Response of Magnetic Nanoparticles

    Journal of Physical Chemistry C, Vol. 119, Núm. 27, pp. 15698-15706

  2. Extraordinary exchange-bias effects in coupled SmCo5 (perpendicular)/CoFeB (in-plane) bilayers

    2015 IEEE International Magnetics Conference, INTERMAG 2015

  3. Orientation of the magnetization easy axes of interacting nanoparticles: Influence on the hyperthermia properties

    Journal of Magnetism and Magnetic Materials, Vol. 380, pp. 321-324

  4. The landau-lifshitz-bloch equation for quantum spin

    Springer Proceedings in Physics

  5. The role of size polydispersity in magnetic fluid hyperthermia: Average vs. local infra/over-heating effects

    Physical Chemistry Chemical Physics, Vol. 17, Núm. 41, pp. 27812-27820