TY - BOOK ID - 133567162 TI - Magnetic Nanomaterials PY - 2022 PB - Basel MDPI - Multidisciplinary Digital Publishing Institute DB - UniCat KW - Technology: general issues KW - History of engineering & technology KW - disordered magnetism KW - super-spin glass KW - glassy correlation length KW - magnetic freezing KW - nanogranular Au/Fe-oxide KW - Fe-oxide nanocrystallites KW - synthetic antiferromagnet KW - exchange bias KW - interlayer exchange coupling KW - vibrating sample magnetometry KW - CoFeB KW - thermally assisted magnetic scanning probe lithography KW - magnetron sputtering KW - nanoparticles KW - sol-gel KW - Raman spectroscopy KW - UV-blue photoluminescence KW - ZnNiO KW - Kubelka-Munk function KW - Burstein-Moss shift KW - substitutional doping KW - FePd alloy KW - electrodeposition technique KW - magnetic properties KW - structural characterisation KW - ferrimagnetic materials KW - superparamagnetism KW - magnetic hysteresis KW - magnetic materials KW - magnetic nanoparticles KW - nanocomposites KW - nanowires KW - martensitic transition KW - Heusler alloys KW - magnetic shape memory alloys KW - twin boundary KW - epitaxial Ni-Mn-Ga films KW - transmission electron microscopy KW - magnetic anisotropy KW - iron nitrides KW - III-nitrides KW - nanocrystals KW - density functional theory KW - magnetic hyperthermia KW - magneto-sonoporation KW - stem cells KW - superparamagnetic iron oxide particles KW - cell labelling KW - ultrasounds KW - osteogenesis KW - bone tissue engineering KW - magnetic aggregates KW - magnetic interactions KW - core/shell nanoparticles KW - multicore nanoparticles KW - hybrid systems KW - mixed nanoparticle systems KW - chemical synthesis KW - magnetic heating UR - https://www.unicat.be/uniCat?func=search&query=sysid:133567162 AB - The constant search for innovative magnetic materials increasingly leads to the creation of highly engineered systems built in different forms (films, wires, particles), structured on the nanoscale in at least one spatial direction, and often characterized by the coexistence of two or more phases that are magnetically and/or structurally different. In magnetic systems, the nanometric structural characteristics of the constituent elements, together with the type and strength of the magnetic interactions between them, determine the overall magnetic behavior and can lead to the appearance of unexpected and amazing magnetic phenomena. Indeed, the study of the magnetic properties of nanomaterials continues to arouse great interest for their intriguing fundamental properties and prospective technological applications. This Special Issue contributes to broadening the knowledge on magnetic nanomaterials, demonstrating the breadth and richness of this research field as well as the growing need to address it through an interdisciplinary approach. The papers collected in this book (two reviews and eight regular articles) report cutting-edge studies on the production and characterization of a variety of novel magnetic nanomaterials (nanoparticles, nanocomposites, thin films and multilayers), which have the potential to play a key role in different technologically advanced sectors, such as biotechnology, nanomedicine, energy, spintronics, data storage, and sensors. ER -