The only naturally occurring isotope of bismuth, 209Bi, is commonly regarded as the heaviest stable isotope. But like most other heavy nuclei abundant in nature and characterized by an exceptionally long lifetime, it is metastable with respect to alpha-decay. However, the decay usually evades observation because the nuclear structure of 209Bi gives rise to an extremely low decay probability and, moreover, generates low-energy alpha-particles difficult to detect. Indeed, dedicated experiments attempting to record the alpha-decay of 209Bi in nuclear emulsions failed. However, scintillating bolometers operated at temperatures below 100 mK offer improved detection efficiency and sensitivity, whereas a broad palette of targets could be available. Here we report the successful use of this method for the unambiguous detection of 209Bi alpha-decay in bismuth germanate detectors cooled to 20 mK. We measure an energy release of 3,137 +/- 1 (statistical) +/- 2 (systematic) keV and a half-life of (1.9 +/- 0.2) x 10(19) yr, which are in agreement with expected values.
Current practical methods for finding the equilibrium dissociation constant, K d ,o fp rotein-small molecule complexes have inherent sources of inaccuracy.I ntroduced here is "accurate constant via transient incomplete separation" (ACTIS), which appears to be free of inherent sources of inaccuracy.C onceptually,as hort plug of the pre-equilibrated protein-small molecule mixture is pressure-propagated in ac apillary,c ausing fast transient incomplete separation of the complex from the unbound small molecule.Asuperposition of signals from these two components is measured near the capillary exit and used to calculate af raction of unbound small molecule,which,inturn, is used to calculate K d . Herein the validity of ACTIS is proven theoretically,i ts accuracy is verified by computer simulation, and its practical use is demonstrated. ACTIS has the potential to become ar eference-standardm ethod for determining K d values of protein-small molecule complexes.Reversible binding of proteins (P) to small-molecule ligands (L) plays an important role in the regulation of cellular processes. [1] In addition, most therapeutic targets are proteins, [2] and drugs are developed to form stable PL complexes with them:Complex stability is characterized by the equilibrium dissociation constant K d ,which is defined as:
Abstract— The photochemical and chemical properties of the four dimers of thymine have been studied. The extinction coefficients, reversal cross‐sections and quantum yields for reversal are presented as a function of wavelength in the range 200–289 nm. At any wavelength, the dimers have different reversal cross‐sections but also different extinction coefficients. The quantum yields for reversal are nearly the same for all four dimers, the values ranging from 0·6 to 0·9 over the wavelength range 200–289 nm. Titration curves for the four dimers show that for each dimer, two groups are involved with two pK's at about 10·5 and 12·2. Dimers A and B are stable at alkali and acid pH's. Dimers C and D are stable from pH 1 to 3 and unstable at other pH's, with thymine the main degradation product.
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