30 research outputs found
Memory effect of MnGe nanomagnets embedded inside a Mn-diluted Ge matrix
Crystalline Mn5Ge3 nanomagnets are formed inside a Mn-diluted Ge matrix using
Mn ion implantation. A temperature-dependent memory effect and slow magnetic
relaxation are observed below the superparamagnetic blocking temperature of
Mn5Ge3. Our findings corroborate that the observed spin-glass-like features are
caused by the size distribution of Mn5Ge3 nanomagnets, rather than by the
inter-particle interaction through the Mn-diluted Ge matrix.Comment: 10 pages, 4 figures,. submitted to Appl. Phys. Let
Ferromagnetic, structurally disordered ZnO implanted with Co ions
We present superparamagnetic clusters of structurally highly disordered
Co-Zn-O created by high fluence Co ion implantation into ZnO (0001) single
crystals at low temperatures. This secondary phase cannot be detected by common
x-ray diffraction but is observed by high-resolution transmission electron
microscopy. In contrast to many other secondary phases in a ZnO matrix it
induces low-field anomalous Hall effect and thus is a candidate for
magneto-electronics applications.Comment: 5 pages, 3 figure
Laser-induced positional and chemical lattice reordering generating ferromagnetism
Atomic scale reordering of lattices can induce local modulations of functional material properties, such as reflectance and ferromagnetism. Pulsed femtosecond laser irradiation enables lattice reordering in the picosecond range. However, the dependence of the phase transitions on the initial lattice order as well as the temporal dynamics of these transitions remain to be understood. This study investigates the laser‐induced atomic reordering and the concomitant onset of ferromagnetism in thin Fe‐based alloy films with vastly differing initial atomic orders. The optical response to single femtosecond laser pulses on selected prototype systems, one that initially possesses positional disorder, Fe60V40, and a second system initially in a chemically ordered state, Fe60Al40, has been tracked with time. Despite the vastly different initial atomic orders the structure in both systems converges to a positionally ordered but chemically disordered state, accompanied by the onset of ferromagnetism. Time‐resolved measurements of the transient reflectance combined with simulations of the electron and phonon temperatures reveal that the reordering processes occur via the formation of a transient molten state with an approximate lifetime of 200 ps. These findings provide insights into the fundamental processes involved in laser‐induced atomic reordering, paving the way for controlling material properties in the picosecond range
Room temperature ferromagnetism in carbon-implanted ZnO
Unexpected ferromagnetism has been observed in carbon doped ZnO films grown
by pulsed laser deposition [Phys. Rev. Lett. 99, 127201 (2007)]. In this
letter, we introduce carbon into ZnO films by ion implantation. Room
temperature ferromagnetism has been observed. Our analysis demonstrates that
(1) C-doped ferromagnetic ZnO can be achieved by an alternative method, i.e.
ion implantation, and (2) the chemical involvement of carbon in the
ferromagnetism is indirectly proven.Comment: 13 pages, 3 figs, accepted for publication at Appl. Phys. Let
Amorphous Li-Al-Based Compounds: A Novel Approach for Designing High Performance Electrode Materials for Li-Ion Batteries
A new amorphous compound with the initial atomic composition Al43Li43Y6Ni8 applied as electrode material for Li-ion batteries is investigated. Unlike other amorphous compounds so-far investigated as anode materials, it already contains Li as a base element in the uncycled state. The amorphous compound powder is prepared by high energy ball milling of a master alloy. It shows a strongly enhanced specific capacity in contrast to amorphous alloys without Li in the initial state. Therewith, by enabling a reversible (de)lithiation of metallic electrodes without the phase transition caused volume changes it offers the possibility of much increased specific capacities than conventional graphite anodes. According to the charge rate (C-rate), the specific capacity is reversible over 20 cycles at minimum in contrast to conventional crystalline intermetallic phases failing by volume changes. The delithiation process occurs quasi-continuously over a voltage range of nearly 4 V, while the lithiation is mainly observed between 0.1 V and 1.5 V. That way, the electrode is applicable for different potential needs. The electrode stays amorphous during cycling, thus avoiding volume changes. The cycling performance is further enhanced by a significant amount of Fe introduced as wear debris from the milling tools, which acts as a promoting element
Strain anisotropy and magnetic domains in embedded nanomagnets
Nanoscale modifications of strain and magnetic anisotropy can open pathways to engineering magnetic domains for device applications. A periodic magnetic domain structure can be stabilized in sub‐200 nm wide linear as well as curved magnets, embedded within a flat non‐ferromagnetic thin film. The nanomagnets are produced within a non‐ferromagnetic B2‐ordered Fe60Al40 thin film, where local irradiation by a focused ion beam causes the formation of disordered and strongly ferromagnetic regions of A2 Fe60Al40. An anisotropic lattice relaxation is observed, such that the in‐plane lattice parameter is larger when measured parallel to the magnet short‐axis as compared to its length. This in‐plane structural anisotropy manifests a magnetic anisotropy contribution, generating an easy‐axis parallel to the short axis. The competing effect of the strain and shape anisotropies stabilizes a periodic domain pattern in linear as well as spiral nanomagnets, providing a versatile and geometrically controllable path to engineering the strain and thereby the magnetic anisotropy at the nanoscale