Elmi Alex, Bąk Krzysztof M, Cockroft Scott L
EaStCHEM School of Chemistry, University of Edinburgh, Joseph Black Building, Edinburgh, EH9 3FJ, U.K.
Angew Chem Int Ed Engl. 2024 Nov 4;63(45):e202412056. doi: 10.1002/anie.202412056. Epub 2024 Sep 13.
Solvent competition for London dispersion attenuates its energetic significance in molecular recognition processes. By varying both the stacked contact area and the solvent, here we experimentally deconvolute solvent attenuation using molecular balances. Experimental stacking energies (phenyl to pyrene) correlated strongly with calculations only when dispersion was considered. Such calculations favoured stacking by up to -27 kJ mol in the gas phase, but it was weakly disfavoured in our solution-phase experiments (+0.5 to +4.6 kJ mol). Nonetheless, the propensity for stacking increased with contact area and in solvents with lower bulk polarisabilities that compete less for dispersion. Experimental stacking energies per unit change in solvent accessible area ranged from -0.02 kJ mol Å in CS, to -0.05 kJ mol Å in CDCl, but were dwarfed by the calculated gas-phase energy of -0.6 kJ mol Å. The results underscore the challenge facing the exploitation of dispersion in solution. Solvent competition strongly but imperfectly cancels dispersion at molecular recognition interfaces, making the energetic benefits difficult to realise.
伦敦色散力的溶剂竞争削弱了其在分子识别过程中的能量重要性。通过改变堆积接触面积和溶剂,我们在此使用分子天平通过实验对溶剂衰减进行解卷积。仅当考虑色散力时,实验测得的堆积能(苯基与芘之间)与计算结果高度相关。这种计算表明在气相中堆积能高达 -27 kJ mol,但在我们的溶液相实验中则略微不利(+0.5至 +4.6 kJ mol)。尽管如此,堆积倾向随着接触面积的增加以及在对色散竞争较小的低本体极化率溶剂中而增加。每单位溶剂可及面积变化的实验堆积能范围从CS中的 -0.02 kJ mol Å到CDCl中的 -0.05 kJ mol Å,但与计算得到的气相能量 -0.6 kJ mol Å相比则相形见绌。这些结果突显了在溶液中利用色散力所面临的挑战。在分子识别界面处,溶剂竞争强烈但并不完全抵消色散力,使得能量优势难以实现。
