Rotational Excitation Spectroscopy with the STM through Molecular Resonances

We investigate the rotational properties of molecular hydrogen and its isotopes physisorbed on the surfaces of graphene and hexagonal boron nitride ($h$-BN), grown on Ni(111), Ru(0001), and Rh(111), using rotational excitation spectroscopy (RES) with the scanning tunneling microscope. The rotational thresholds are in good agreement with $\Delta J=2$ transitions of freely spinning para-H$_2$ and ortho-D$_2$ molecules. The line shape variations in RES for H$_2$ among the different surfaces can be traced back and naturally explained by a resonance mediated tunneling mechanism. RES data for H$_2$/$h$-BN/Rh(111) suggests a local intrinsic gating on this surface due to lateral variations in the surface potential. An RES inspection of H$_2$, HD, and D$_2$ mixtures finally points to a multi molecule excitation, since either of the three $J=0\rightarrow2$ rotational transitions are simultaneously present, irrespective of where the spectra were recorded in the mixed monolayer

Distinction of Nuclear Spin States with the Scanning Tunneling Microscope

We demonstrate rotational excitation spectroscopy with the scanning tunneling microscope for physisorbed hydrogen and its isotopes hydrogen-deuterid and deuterium. The observed excitation energies are very close to the gas phase values and show the expected scaling with moment of inertia. Since these energies are characteristic for the molecular nuclear spin states we are able to identify the para and ortho species of hydrogen and deuterium, respectively. We thereby demonstrate nuclear spin sensitivity with unprecedented spatial resolution

Targeting burn prevention in the pediatric population : a prospective study of children's burns in the Lausanne area

Rapport de synthèse : But de l'étude : Les accidents domestiques représentent un problème significatif en médecine pédiatrique. Le but de cette étude est de mieux comprendre les mécanismes et causes des brûlures afin de pouvoir cibler la prévention. Méthode : Il s'agit d'une étude prospective d'une durée d'une année, d'Août 2004 à Août 2005. Les patients ayant consulté pour des brûlures à l'Hôpital de l'Enfance de Lausanne (HEL) ou au CHUV ont été répertoriés. Le mécanisme et les circonstances des brûlures ont été analysées, de même que l'environnement et les données psycho-sociales. Résultats : huitante-neuf patients ont été inclus dans l'étude, âgés de 2 mois à 15 ans. Septante-huit pour cent des patients avaient moins de 5 ans. Plus de la moitié étaient des garçons. Les brûlures par échaudement prédominaient. Nous n'avons pas pu mettre en évidence d'incidence augmentée de brûlures chez des patients de familles immigrées ou de niveau social bas. Dans la majorité des cas, un adulte était présent au moment de l'accident. Conclusion : Si l'on devait établir un profil type de l'enfant à risque de se brûler dans notre région, il s'agirait d'un garçon âgé de 15 mois-5ans, se brûlant en se versant une tasse de liquide chaud sur la main, à son domicile, en présence de l'un ou de ses deux parents. Le message de prévention devrait donc s'adresser directement aux parents, toutes nationalités et niveau social confondus afin de leur expliquer les dangers de brûlures présents au quotidien à leur domicile. A chaque contrôle, les pédiatres devraient parler des accidents domestiques aux parents. En insistant sur les dangers que représentent les tasses de café, la porte du four et la plaque de la cuisinière, qui sont des éléments du quotidien et qui méritent une attention à chaque utilisation. Les brûlures chez le petit enfant pourraient ainsi être fortement réduites

On the smoothing property of the Bayes approach to picture reconstruction

The paper is concerned with the reconstruction of a picture density f from a finite number of its strip integrals. It is shown that the Bayes estimate for f is in the Sobolev space H^{3/2} if the isotropic exponential model for f is used. As picture densities are far from being in H^{3/2} (the isotropic exponential model e.g. implies, roughly speaking, only fin H^{1/2}), the Bayes approach can be expected to smooth out peaks and high contrasts. This drawback of the Bayes approach was in fact observed in a comparative numerical test carried out by Herman and Lent [ 6]

Thermal and magnetic field stability of holmium single atom magnets

We use spin-polarized scanning tunneling microscopy to demonstrate that Ho atoms on magnesium oxide exhibit a coercive field of more than 8 T and magnetic bistability for many minutes, both at 35 K. The first spontaneous magnetization reversal events are recorded at 45 K for which the metastable state relaxes in an external field of 8 T. The transverse magnetic anisotropy energy is estimated from magnetic field and bias voltage dependent switching rates at 4.3 K. Our measurements constrain the possible ground state of Ho single atom magnets to either Jz = 7 or 8, both compatible with magnetic bistability at fields larger than 10 mT.Comment: 4 pages and supplemental informatio

Upgrade of a low-temperature scanning tunneling microscope for electron-spin resonance

Electron spin resonance with a scanning tunneling microscope (ESR-STM) combines the high energy resolution of spin resonance spectroscopy with the atomic scale control and spatial resolution of STM. Here we describe the upgrade of a helium-3 STM with a 2D vector-field magnet ($B_z$ = 8.0 T, $B_x$ = 0.8 T) to an ESR-STM. The system is capable of delivering RF power to the tunnel junction at frequencies up to 30 GHz. We demonstrate magnetic field sweep ESR for the model system TiH/MgO/Ag(100) and find a magnetic moment of $(1.004 \pm 0.001)$ $\mu_B$. Our upgrade enables to toggle between a DC mode, where the STM is operated with the regular control electronics, and an ultrafast-pulsed mode that uses an arbitrary waveform generator for pump-probe spectroscopy or reading of spin-states. Both modes allow for simultaneous radiofrequency excitation, which we add via a resistive pick-off tee to the bias voltage path. The RF cabling from room temperature to the 350 mK stage has an average attenuation of 18 dB between 5 and 25 GHz. The cable segment between the 350 mK stage and the STM tip presently attenuates an additional $34_{-3}^{+5}$ dB from 10 to 26 GHz and $38_{-2}^{+3}$ dB between 20 and 30 GHz. We discuss our transmission losses and indicate ways to reduce this attenuation. We finally demonstrate how to synchronize the arrival times of RF and DC pulses coming from different paths to the STM junction, a prerequisite for future pulsed ESR experiments.Comment: 7 figure

Relativistic approach to electromagnetic imaging

A novel imaging principle based on the interaction of electromagnetic waves with a beam of relativistic electrons is proposed. Wave-particle interaction is assumed to take place in a small spatial domain, so that each electron is only briefly accelerated by the incident field. In the one-dimensional case the spatial distribution of the source density can be directly observed in the temporal spectrum of the scattered field. Whereas, in the two-dimensional case the relation between the source and the spectrum is shown to be approximately the Radon transform.Comment: 10 pages, 1 figur

Different realizations of tomographic principle in quantum state measurement

We establish a general principle for the tomographic approach to quantum state reconstruction, till now based on a simple rotation transformation in the phase space, which allows us to consider other types of transformations. Then, we will present different realizations of the principle in specific examples.Comment: 17 pages, Latex file, no figures, accepted by J. of Mod. Op

Weighted Radon transforms for which the Chang approximate inversion formula is precise

We describe all weighted Radon transforms on the plane for which the Chang approximate inversion formula is precise. Some subsequent results, including the Cormack type inversion for these transforms, are also given

Antiferromagnetic MnNi tips for spin-polarized scanning probe microscopy

Spin-polarized scanning tunneling microscopy (SP-STM) measures tunnel magnetoresistance (TMR) with atomic resolution. While various methods for achieving SP probes have been developed, each is limited with respect to fabrication, performance, and allowed operating conditions. In this study, we present the fabrication and use of SP-STM tips made from commercially available antiferromagnetic $\rm{Mn_{88}Ni_{12}}$ foil. The tips are intrinsically SP, which is attractive for exploring magnetic phenomena in the zero field limit. The tip material is relatively ductile and straightforward to etch. We benchmark the conventional STM and spectroscopic performance of our tips and demonstrate their spin sensitivity by measuring the two-state switching of holmium single atom magnets on MgO/Ag(100)