Transient equilibrium mapping: A new tool for measuring the thermodynamics of slowly assembling supramolecular systems

Abstract: Supramolecular chemistry involves the non-covalent assembly of monomers into materials with unique properties and wide-ranging applications. Thermal analysis is one of the key analytical tools in this field, as it provides quantitative thermodynamic information on both the structural stability and nature of the underlying molecular interactions. However there exist many supramolecular systems whose kinetics are so slow under conditions approaching chemical equilibrium that thermodynamic data are inaccessible. … Show more

“…the locus point upon dv ! 0 þ ) [37]. A 'transient equilibrium mapping' model was thereby derived to justify hysteresis of cooling/heating paths and to determine thermodynamic data of slowly (non-covalent) monomer dis/assembling.…”

“…Heating of the sample reverses the process. To gain a more quantitative insight into the hysteretic response we performed the socalled transient equilibrium mapping [37], a spectroscopic method that comprises the rising and lowering of the sample temperature to allow the system to pass through the transient equilibrium on each up-and down-scan (Fig. 2a).…”

Statistical thermodynamics in reversible clustering of gold nanoparticles. A first step towards nanocluster heat engines

“…the locus point upon dv ! 0 þ ) [37]. A 'transient equilibrium mapping' model was thereby derived to justify hysteresis of cooling/heating paths and to determine thermodynamic data of slowly (non-covalent) monomer dis/assembling.…”

“…Heating of the sample reverses the process. To gain a more quantitative insight into the hysteretic response we performed the socalled transient equilibrium mapping [37], a spectroscopic method that comprises the rising and lowering of the sample temperature to allow the system to pass through the transient equilibrium on each up-and down-scan (Fig. 2a).…”

Statistical thermodynamics in reversible clustering of gold nanoparticles. A first step towards nanocluster heat engines