RESUMEN
Boron-based two-dimensional (2D) materials are an excellent platform for nanoelectronics applications. Rhombohedral boron monosulfide (r-BS) is attracting particular attention because of its unique layered crystal structure suitable for exploring various functional properties originating in the 2D nature. However, studies to elucidate its fundamental electronic states have been largely limited because only tiny powdered crystals were available, hindering a precise investigation by spectroscopy such as angle-resolved photoemission spectroscopy (ARPES). Here we report the direct mapping of the band structure with a tiny (â¼20 × 20 µm2) r-BS powder crystal by utilizing microfocused ARPES. We found that r-BS is a p-type semiconductor with a band gap of >0.5 eV characterized by the anisotropic in-plane effective mass. The present results demonstrate the high applicability of micro-ARPES to tiny powder crystals and widen an opportunity to access the yet-unexplored electronic states of various novel materials.
RESUMEN
Angle-resolved photoemission spectroscopy using a micro-focused beam spot [micro-angle-resolved photoemission spectroscopy (ARPES)] is becoming a powerful tool to elucidate key electronic states of exotic quantum materials. We have developed a versatile micro-ARPES system based on the synchrotron radiation beam focused with a Kirkpatrick-Baez mirror optics. The mirrors are monolithically installed on a stage, which is driven with five-axis motion, and are vibrationally separated from the ARPES measurement system. Spatial mapping of the Au photolithography pattern on Si signifies the beam spot size of 10 µm (horizontal) × 12 µm (vertical) at the sample position, which is well suited to resolve the fine structure in local electronic states. Utilization of the micro-beam and the high precision sample motion system enables the accurate spatially resolved band-structure mapping, as demonstrated by the observation of a small band anomaly associated with tiny sample bending near the edge of a cleaved topological insulator single crystal.
RESUMEN
BACKGROUND: Alterations in homeostasis after various cellular stresses, which prevent protein folding and cause an accumulation of misfolding or malfolding proteins in the endoplasmic reticulum (ER), have the potential to induce cellular damage, and are therefore a type of 'ER stress.' To understand the molecular events or cascades underlying the ER stress response regulated by gene transcription and mediated by stress transducers, it is crucial to identify the molecules induced during ER stress and to analyse the roles of these genes. RESULTS: We identified MDG1/ERdj4, a member of the DnaJ protein family, as an inducible gene during ER stress. MDG1/ERdj4 contains the J domain, which is essential for interacting with Hsp70s, at the N-terminal portion and just at the back of the transmembrane domain. Its trypsin digestion and glycosylation of a chimeric protein composed of MDG1/ERdj4 fused with the extracellular domain of the amyloid precursor protein at its C-terminus, showed that its C-terminal portion containing the J domain could be orientated to the ER lumen. Over-expression of it inhibited the cell death induced by ER stress. In contrast, its mutants with the J domain deleted showed no protective effects against cell death. CONCLUSIONS: MDG1/ERdj4 may play roles in stabilizing GRP78/BiP binding to unfolded substrate proteins in a J domain-dependent manner and prevent the accumulation of unfolded proteins in the ER, consequently protecting cells from ER stress.