https://www.selleckchem.com/products/Ubenimex(Bestatin).html The specific host-guest interactions in the corresponding complexes of K+ and NH4+ with typical crown ethers were investigated by using FTIR and ultrafast IR spectroscopies. The counteranions, i.e., SCN-, were employed as a local vibrational probe to report the structural dynamics of the complexation. It was found that the vibrational relaxation dynamics of the SCN- was strongly affected by the cations confined in the cavities of the crown ethers. The time constant of the vibrational population decay of SCN- in the complex of NH4+ with the 18-crown-6 was determined to be 6 ± 2 ps, which is ∼30 times faster than that in the complex of K+ with the crown ethers. Control experiments showed that the vibrational population decay of SCN- depended on the size of the cavities of the crown ethers. A theoretical calculation further indicated that the nitrogen atom of SCN- showed preferential coordination to the K+ ions hosted by the crown ethers, while the NH4+ can form hydrogen bonds with the oxygen atoms in the studied crown ethers. The geometric constraints formed in the complex of crown ethers can cause a specific interaction between the NH4+ and SCN-, which can facilitate the intermolecular vibrational energy redistribution of the SCN-.The mechanism, origin of stereoselectivity, and ligand-dependent reactivity of Pd(II)-catalyzed methylene C(sp3)-H alkenylation-aza-Wacker cyclization to form (E)-β-stereogenic γ-lactam have been comprehensively studied by density functional theory (DFT) calculations. The calculated results reveal that the methylene C-H activation assisted by K2CO3 via the concerted metalation-deprotonation mechanism is found to be the most preferred pathway, where the enantioselectivity is distinguished by the orientation of the methyl group of a substrate relative to a chiral ligand. However, the stereochemistry of the olefin moiety in the generated product is mainly determined by the oxidative