Effect of the Chirality of Counter Anions on the Vapochromic Behavior of Luminescent Pt^II Complexes

Abstract: New luminescent PtII complexes with the chiral counter anions [PtCl(tpy)](l‐Hta) (1‐L) and [PtCl(tpy)](dl‐Hta) (1‐DL; tpy = 2,2′:6′,2′′‐terpyridine; l‐H2ta = l‐tartaric acid; dl‐H2ta = racemic tartaric acid) were synthesized and their vapochromic behavior was evaluated. Single crystal X‐ray analysis revealed that the stacked square‐planar PtII molecules in anhydrous 1‐DL formed a one‐dimensional columnar structure with weak intermolecular Pt···Pt interactions, while in anhydrous 1‐L the PtII molecules were dim… Show more

“…S8, ESI†). Similar MeOH-vapor-induced dehydration phenomena have also been reported for platinum complexes, 26–28 and it is not a particularly rare phenomenon. Upon subsequent re-exposure of the MeOH-treated reddish-brown sample to water vapor, the thermal weight loss was recovered to the original value (∼0.98%, Fig.…”

Near-infrared vapochromism in lipid-packaged mixed-valence coordination polymers

“…S8, ESI†). Similar MeOH-vapor-induced dehydration phenomena have also been reported for platinum complexes, 26–28 and it is not a particularly rare phenomenon. Upon subsequent re-exposure of the MeOH-treated reddish-brown sample to water vapor, the thermal weight loss was recovered to the original value (∼0.98%, Fig.…”

Near-infrared vapochromism in lipid-packaged mixed-valence coordination polymers

“…Phosphorescent organoplatinum­(II) complexes have recently been extensively utilized to construct a wide variety of supramolecular materials because of their unique square-planar geometry and propensity to form noncovalent metal–metal interactions, which would render the molecules to aggregate, resulting in intriguing luminescence properties. − For example, drastic color and emission changes are found to occur during the assembly process, which can be attributed to the formation of noncovalent metal–metal and π–π stacking interactions. − In view of the fascinating spectroscopic properties, platinum­(II) complexes with functional ligands have also been exploited as sensors to afford color or phosphorescence changes in response to microenvironmental changes. − The rich and tunable emission colors and high photoluminescence quantum yields have also rendered them promising candidates for the fabrication of organic light-emitting diodes. − Recently, with the upsurge of research focusing on CPL materials, a few examples of platinum­(II) complexes with chiral groups modified on the bidentate or tridentate ligands have been reported with the amplification of CPL from the molecular level to assembled supramolecular architectures. ,− Apart from this, the decoration of ancillary ligands can also alter the solubility, photophysical, and self-assembly properties of platinum­(II) complexes. − Herein, we designed and synthesized a series of cyclometalated 1,3-di­(2-pyridyl)­benzene platinum­(II) complexes modified with different functional groups on the ancillary alkynyl ligands (Scheme ). They are capable of assembling into different aggregates through isodesmic self-assembly processes.…”

Phosphorescent Cyclometalated Platinum(II) Enantiomers with Circularly Polarized Luminescence Properties and Their Assembly Behaviors

“…Although the effect of vapors in the crystal lattice of 9 could not be elucidated by SCXRD, UV‐vis spectroscopy confirmed the appearance of MMLCT bands upon the uptake of solvent molecules, which proved a decrease in the Pt⋅⋅⋅Pt separation. Similarly, Kato's [70,71] and Sun's [72] groups addressed the effect of counterions in vapochromic Pt(II) complexes.…”

Chromic Platinum Complexes Containing Multidentate Ligands