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p-type Cr2MnO4 with bandgap 3.01 eV was sputter deposited onto (2¯01) and (001) n-type or semi-insulating β-Ga2O3.The heterojunction of p-type CrMnO4 on n-type Ga2O3 is found to be type II, staggered gap, i.e., the band offsets are such that both the conduction and valence band edges of Ga2O3 are lower in energy than those of the Cr2MnO4. This creates a staggered band alignment, which can facilitate the separation of photogenerated electron-hole pairs. The valence band edge of Cr2MnO4 is higher than that of Ga2O3 by 1.82–1.93 eV depending on substrate orientation and doping, which means that holes in Cr2MnO4 would have a lower energy barrier to overcome to move into Ga2O3. Conversely, the conduction band edge of Cr2MnO4 is higher than that of Ga2O3 by 0.13–0.30 eV depending on substrate doping and orientation, which would create a barrier for electrons in Ga2O3 to move into Cr2MnO4. This heterojunction looks highly promising for p-n junction formation for advanced Ga2O3-based power rectifiers. 

While over one-third of the U.S. economy and much of our national security infrastructure directly depends on precision timing, there has been to date no educational workforce development program in the US dedicated to training young talent in the timekeeping technologies that underpin our society. The Alabama Collaborative for Contemporary Education in Precision Timing (ACCEPT) Program is a new, 5-year National Research Traineeship program funded by the National Science Foundation, designed to train the next generation of graduate (MS and PhD) degree holders in a field of critical important to our nation. ACCEPT will provide a comprehensive training and educational opportunity for trainees from physics, mathematics, and engineering. Trainees will combine coursework across these three departments with professional development in critical areas identified by precision timing experts (teamwork, leadership, ethics, communication), and put their training into practice via research experiences with ACCEPT partners, student-led initiatives, and networking at conferences and workshops. In this paper, we present the current objectives, vision, and methodology of our new program, initial steps toward building a comprehensive training facility, and initial research and demonstration projects. 

Modern-day chip manufacturing requires precision in placing chip materials on complex and patterned structures. Area-selective atomic layer deposition (AS-ALD) is a self-aligned manufacturing technique with high precision and control, which offers cost effectiveness compared to the traditional patterning techniques. Self-assembled monolayers (SAMs) have been explored as an avenue for realizing AS-ALD, wherein surface-active sites are modified in a specific pattern via SAMs that are inert to metal deposition, enabling ALD nucleation on the substrate selectively. However, key limitations have limited the potential of AS-ALD as a patterning method. The choice of molecules for ALD blocking SAMs is sparse; furthermore, deficiency in the proper understanding of the SAM chemistry and its changes upon metal layer deposition further adds to the challenges. In this work, we have addressed the above challenges by using nanoscale infrared spectroscopy to investigate the potential of stearic acid (SA) as an ALD inhibiting SAM. We show that SA monolayers on Co and Cu substrates can inhibit ZnO ALD growth on par with other commonly used SAMs, which demonstrates its viability towards AS-ALD. We complement these measurements with AFM-IR, which is a surface-sensitive spatially resolved technique, to obtain spectral insights into the ALD-treated SAMs. The significant insight obtained from AFM-IR is that SA SAMs do not desorb or degrade with ALD, but rather undergo a change in substrate coordination modes, which can affect ALD growth on substrates. 

A timescale algorithm demonstrating a clock ensemble utilizing commercial atomic clocks and multiplexing equipment has been established at the University of Alabama to serve as a testbed for research and student training.