Old School Catalog 1910-11, Chicago College of Dental Surgery

https://scholar.valpo.edu/oldschoolcatalogs/1017/thumbnail.jp

Old School Catalog 1907-08, Chicago College of Dental Surgery

https://scholar.valpo.edu/oldschoolcatalogs/1026/thumbnail.jp

Old School Catalog 1913-14, Chicago College of Dental Surgery

https://scholar.valpo.edu/oldschoolcatalogs/1117/thumbnail.jp

Old School Catalog 1905-06, Chicago College of Dental Surgery

https://scholar.valpo.edu/oldschoolcatalogs/1033/thumbnail.jp

Old School Catalog 1908-09, Chicago College of Dental Surgery

https://scholar.valpo.edu/oldschoolcatalogs/1024/thumbnail.jp

Old School Catalog 1912-13, Chicago College of Dental Surgery

https://scholar.valpo.edu/oldschoolcatalogs/1012/thumbnail.jp

Following the relaxation dynamics of photoexcited aniline in the 273-266 nm region using time-resolved photoelectron imaging

Scanning tunnelling microscopy (STM) and Auger electron spectroscopy (AES) have been used to investigate the growth morphology of ultra-thin Pb films on the Ni3Al(111) face at room temperature. A previous study [K. Miśków and A. Krupski Appl Surf Sci 273, 2013, 554] using low-energy electron diffraction (LEED) and real time Auger intensity recording has demonstrated that an initial two-dimensional growth of the first Pb monolayer thick ‘wetting layer’ takes place. With further deposition and for T = 300 K, flat three atomic-layer-high islands are grown. Above 350 K, the Stranski–Krastanov growth mode was observed. In the current study, the analysis of STM measurements indicate and confirm that for coverage θ = 1.0 ML two-dimensional growth of the first Pb monolayer took place. Above θ > 1.0 ML, a three-dimensional growth of the Pb islands was observed with a strongly preferred atomic-scale ‘magic height (N),’ hexagonal shape and flat-tops. At coverage θ = 3.5 ML, only islands containing N = 3, 5, 7 and 11 atomic layers of Pb are observed. At the higher coverage θ = 5.5 ML, three types of regular hexagonal islands with side lengths of 25, 30 and 45 nm are observed. Furthermore, three different island adsorption configurations rotated by 10° ± 1° and 30° ± 6° with respect to each other were observed. After an annealing at T = 400 K of 5.5 ML of lead deposited at RT on the Ni3Al(111) the morphology of the surface changes. Post-anneal, islands of Pb are observed above the ‘wetting layer’ with an estimated average size and diameter of 768 ± 291 nm2 and 38.17 ± 6.56 nm and constant uniform height of two atomic layers (N = 2)

How many metals does it take to fix N2? A mechanistic overview of biological nitrogen fixation

During the process of biological nitrogen fixation, the enzyme nitrogenase catalyzes the ATP-dependent reduction of dinitrogen to ammonia. Nitrogenase consists of two component metalloproteins, the iron (Fe) protein and the molybdenum-iron (MoFe) protein; the Fe protein mediates the coupling of ATP hydrolysis to interprotein electron transfer, whereas the active site of the MoFe protein contains the polynuclear FeMo cofactor, a species composed of seven iron atoms, one molybdenum atom, nine sulfur atoms, an interstitial light atom, and one homocitrate molecule. This Perspective provides an overview of biological nitrogen fixation and introduces three contributions to this special feature that address central aspects of the mechanism and assembly of nitrogenase

Old School Catalog 1914-15, Chicago College of Dental Surgery

https://scholar.valpo.edu/oldschoolcatalogs/1115/thumbnail.jp