Overview Research Projects & Highlights the X-Ray View of Next

The Ultrafast Magnetism Lab - Projects

Overview We probe & control material properties relevant for information technology applications. The unique x- ray sources at SLAC, the Stanford Synchrotron Radiation Laboratory (SSRL) and the Linac Coherent Light Source (LCLS), provide us with access to the fundamental properties of the electron, its charge and spin, evolving on the femtosecond (fs) time- and nanometer lengthscale. The picture to the right shows the undulator hall of the LCLS the world’s ﬁrst x-ray free electron laser.

Research Projects & Highlights

The x-ray view of next generation magnetic data storage devices The rapidly shrinking bit dimensions of next generation data storage devices require to ‘soften’ the magnetization before magnetic ﬁelds can switch the bit magnetization. This is done by heating the magnetic bit with a tiny laser integrated into read/write head. We studied the process of laser heating on its fundamental femtosecond time scale and found that the orbital motion of spins around the nuclei is affected much earlier that the spin orientation (Boeglin et al., Nature 465, 458 (2010). Once the bits are hot coherent x-ray scattering studies indicate that ‘spin memory’ is retained differently for smaller magnetic structures (Wu, et al., APL 99, 252505 (2011)). (picture courtesy of G. Bertero Western Digital Co.)

Ultrafast manipulation of exchange coupling Control of the magnetic exchange coupling, the strongest force in a magnetic solid, is crucial for developing novel magnetic data storage strategies. The figure shows our first demonstration that the exchange coupling in antiferrimagnetically aligned 3d transition metal - 4f rare earth alloys can be influenced by optical laser excitation. Our results published in Nature (Radu, et al., Nature 472, 205 (2011)) demonstrated a novel transient ferromagnetic state responsible for magnetic switching. Our recent LCLS experiments identified the ultrafast flow of angular momentum to be the driving force for emergent magnetic order far from equilibrium. The Ultrafast Magnetism Lab - Projects

Making of the femtosecond movie 80 fs short, fully coherent x-ray pulses from the LCLS can capture the structure of 80nm small magnetic domains. The ﬁgure shows a series of single-shot holograms that capture the true magnetic structure. Longer pulses capture the ultimate speed for writing magnetic information. This paves the way for making the ultra-fast movie and directing electrons & spins in future magnetic data storage devices (Wang, et al., PRL 108, 267403 (2012)). The basis of such studies is the development of novel holographic imaging techniques using coherent x-rays from the Stanford Synchrotron Radiation Laboratory.

Competing electronic order in colossal magneto-resistance materials Mixed-valence manganites are well-known for colossal magnetoresistance (CMR), whereby an applied magnetic ﬁeld of a few tesla can increase their conductivity by orders of magnitude. Manganites also exhibit phase separation, where incompatible electronic phases can coexist within a homogeneous material. The origins of these two phenomena, as well as their relationship, are not completely understood, as they must be if manganites are to be used in future oxide-based electronics. We perform complementary imaging and scattering measurements of the ferromagnetic metallic and charge/orbital/ antiferromagnetically ordered insulating phases, respectively. The ﬁgure illustrates the case of La0.35Pr0.275Ca0.375MnO3 where we found that the glassy nature of the ordered insulating phases is responsible for phase separation (Burkhardt, et al., PRL 108, 237202 (2012)).

When does an insulator become a metal? Strongly correlated electron materials display a dazzling interplay between electronic and lattice degrees of freedom giving rise to spectacular functional properties such as metal- insulator transitions, high-temperature superconductivity and colossal magnetoresistance When metallic electrons localize they often order and distort the lattice. We are disentangling this behavior with time resolved x- ray scattering (Pontius, et al., APL 98, 182504 (2011)). Ultimately we aim at establishing transition-metal oxide electronics based on The Ultrafast Magnetism Lab - Projects electric field driven metal-to-insulator phase transitions as one of the most promising avenues towards energy efficient field-effect transistors (see figure).

Magnetism at non-magnetic interfaces Atomic engineering of interfaces can lead to surprising new properties (Bert et al., Nature Communications 3 922 (2012)). In heterostructures of LaAlO3 (LAO) and SrTiO3 (STO), two nonmagnetic insulators, ferromagnetic patches have been imaged with micro-squid microscopy (see image taken from Kalinsky, et al., arXiv:1201.1063v1). The fact that the ferromagnetism appears in isolated patches whose density varies greatly between samples strongly suggests that disorder or local strain induce magnetism in a population of the interface carriers. We recently succeeded in imaging these ferromagnetic patches using X-ray Photo-Electron Emission Microscopy (X- PEEM). This opens the door for element-speciﬁc investigations of the origin of this interface phenomenon and their response to external stimuli such as pulsed electric ﬁelds.

Electrons & spins in strong electric ﬁelds

It is generally assumed that spins react only to magnetic fields. Bits are switched by magnetic fields from read/write heads hovering only tens of nm above the hard disk drives in our computers. However, if switching spins with electric fields were possible completely novel applications could arise. We investigate the magnetic response to intense, ultrashort electric field pulses using table Figure 1. Scanning SQUID images oftop the ferromagnetic fs lasers landscape (see image) with increasing and LAO using thickness. the (a-d) electromagnetic field surrounding relativistic Typical scanning SQUID images of theelectron LAO/STO bunches surface, showingfrom the no FACET ferromagnetic user facility.patches for (a)

annealed STO and (b) 2 uc (unit cell) of LAO, and ferromagnetic patches for (c) 5 uc and (d) 10 uc of LAO,

Towardstaken computingat 4 K. (e-f) Sketch with of spinmagnetic waves imaging of a ferromagnetic patch with scanning SQUID. (e) Sketch

Basedof on a SQUID our experience probe with a in3 µimagingm pickup currentloop near induced the surface of the sample. (f) Sketch of field lines from a magnetic switching in nanopilars (Bernstein, et al., PRB ferromagnetic83, 180410 patch (2011) (conceptually) we are shown investigating here as a small the bar magnet) captured in the pickup loop. (g) spin waves emitted by these devices. Implementing spin-waveImage (data) transistors of the flux (see through schematic) the pickup andloop as other the SQUID is scanned over a typical ferromagnetic logic elements could lead to low-power information 7 processingpatch. ( h) applications Calculated image based for an in on-plane spin dipole waves whose moment is 7x10 Bohr magnetons and (magnons) in the emerging ﬁeld of magnonics. azimuthal angle -20o, as determined by fitting the data in (g) to a point dipole model.