ABSTRACT
Standard plastic scintillating fiber cannot detect low-energy ß-rays as the cladding prevents them from reaching the fiber core. We developed an outer-layer scintillating (OLS) fiber with a plastic scintillator on the outermost layer for low-energy ß-ray detection. The concept of fiber construction is presented. The fundamental optical properties of the OLS fiber, such as the emission spectrum, attenuation length, and scintillation decay time, were evaluated. Here, Ni-63 with a maximum energy of 67.0 keV was used as a low-energy ß-emitting nuclide. Simulation studies on the interaction between low-energy electrons emitted from Ni-63 and a single fiber were performed prior to actual measurements. The data showed that Ni-63 can be measured using silicon photomultiplier photosensors in a coincidence mode. The OLS fiber was effective for low-energy ß-ray detection.
ABSTRACT
allo-Threonine-derived O-aroyl-B-phenyl-N-tosyl-1,3,2-oxazaborolidin-5-ones 1g,n catalyze the asymmetric Mukaiyama-Michael reaction of acyclic enones with a trimethylsilyl ketene S,O-acetal in high enantioselectivity. A range of alkenyl methyl ketones is successfully employed as Michael acceptors affording ee values of 85-90% by using 10 mol % of the catalyst. The use of 2,6-diisopropylphenol and tert-butyl methyl ether as additives is found to be essential to achieve high enantioselectivity in these reactions. The effects of the additives are discussed in terms of the retardation of an Si(+)-catalyzed racemic pathway, which seriously deteriorates the enantioselectivity of asymmetric Mukaiyama-Michael reactions. A working model for asymmetric induction is proposed based on correlation between catalyst structures and enantioselectivities.
