Copper bis(thiosemicarbazone) Complexes with Pendent Polyamines: Effects of Proton Relays and Charged Moieties on Electrocatalytic HER

Abstract: A series of new bis(thiosemicarbazonato) Cu(II) complexes with pendent polyamines, diacetyl-(N,-dimethylethylenediaminothiosemicarbazonato)-(N'-methyl-3-thio-semicarbazonato)butane-2,3-diimine)-copper(II) (Cu-1), diacetyl-bis (N-dimethylethylenediamino-3-thiosemicarbazonato)butane-2,3-diimine)-copper(II) (Cu-3), and their cationic derivatives Cu-2 and Cu-4, have been synthesized and fully characterized by spectroscopic, electrochemical, and X-ray diffraction methods. Complexes Cu-1-Cu-4 are analogues of Cu(ATS… Show more

“…The CVs of NiL 1 and PdL 1 both exhibit curve crossing when the concentration of HNEt 3 + exceeds 80 equiv. Crossing behavior occurs when the kinetics in the forward sweep are slower than in the reverse sweep and may be indicative of film formation. , Film formation has frequently been reported with M­(BTSC) HER catalysts but there are no prior reports of the curve crossing phenomenon. ,,,− Sequential CV scans for both NiL 1 and PdL 1 under saturating conditions of HNEt 3 + showed an anodic shift in the catalytic wave confirming film formation (Figures S21–S25). The CVs of NiL 1 and PdL 1 with acetic acid and HDBU + also showed an anodic shift in the catalytic wave consistent with film formation after multiple scans, although curve crossing was not always observed.…”

“…Redox-active ligands are of special interest in HER because the ligand can act as an electron reservoir and facilitate two-electron activity with earth-abundant, cost-efficient, first-row transition metals in molecular catalysts. − For several years, we and others have evaluated Zn, , Cu, − Ni, − Pd, and Co , complexes with redox-active bis-thiosemicarbazone (BTSC) ligands (Figure ) as electrocatalysts for the HER. The highly modular nature of BTSCs allows tuning of ligand electronics and basicity.…”

“…This cooperativity between the metal and noninnocent ligand can lead to different H 2 evolution pathways based on the specific metal–ligand combination. As shown for M­(BSTC)­s, pathways include: (1) metal-assisted ligand-centered, where the metal acts as an electron reservoir for bond making/breaking reactions at the ligand; − (2) ligand-assisted metal-centered, where the ligand is an electron reservoir supporting a metal hydride intermediate; , and (3) ligand-centered, where the ligand alone is responsible for the activity with the metal absent or in a structural role. ,− , For ZnL 1 , the reaction follows a ligand-centered pathway as the metal is redox inactive. Herein, we report the synthesis and characterization of nickel­(II) and palladium­(II) derivatives, NiL 1 and PdL 1 , and their respective HER activity in acetonitrile with three different acids.…”

Ligand-Centered Hydrogen Evolution with Ni(II) and Pd(II)DMTH

“…The CVs of NiL 1 and PdL 1 both exhibit curve crossing when the concentration of HNEt 3 + exceeds 80 equiv. Crossing behavior occurs when the kinetics in the forward sweep are slower than in the reverse sweep and may be indicative of film formation. , Film formation has frequently been reported with M­(BTSC) HER catalysts but there are no prior reports of the curve crossing phenomenon. ,,,− Sequential CV scans for both NiL 1 and PdL 1 under saturating conditions of HNEt 3 + showed an anodic shift in the catalytic wave confirming film formation (Figures S21–S25). The CVs of NiL 1 and PdL 1 with acetic acid and HDBU + also showed an anodic shift in the catalytic wave consistent with film formation after multiple scans, although curve crossing was not always observed.…”

“…Redox-active ligands are of special interest in HER because the ligand can act as an electron reservoir and facilitate two-electron activity with earth-abundant, cost-efficient, first-row transition metals in molecular catalysts. − For several years, we and others have evaluated Zn, , Cu, − Ni, − Pd, and Co , complexes with redox-active bis-thiosemicarbazone (BTSC) ligands (Figure ) as electrocatalysts for the HER. The highly modular nature of BTSCs allows tuning of ligand electronics and basicity.…”

“…This cooperativity between the metal and noninnocent ligand can lead to different H 2 evolution pathways based on the specific metal–ligand combination. As shown for M­(BSTC)­s, pathways include: (1) metal-assisted ligand-centered, where the metal acts as an electron reservoir for bond making/breaking reactions at the ligand; − (2) ligand-assisted metal-centered, where the ligand is an electron reservoir supporting a metal hydride intermediate; , and (3) ligand-centered, where the ligand alone is responsible for the activity with the metal absent or in a structural role. ,− , For ZnL 1 , the reaction follows a ligand-centered pathway as the metal is redox inactive. Herein, we report the synthesis and characterization of nickel­(II) and palladium­(II) derivatives, NiL 1 and PdL 1 , and their respective HER activity in acetonitrile with three different acids.…”

Ligand-Centered Hydrogen Evolution with Ni(II) and Pd(II)DMTH

“…Initially poorly basic positions then become proton-responsive and may therefore function as proton relays. Among the catalytic systems that typically promote ligand protonation upon reduction, a number of studies have been dedicated to metal dithiolene ,− and metal thiosemicarbazone ,− complexes. The former initiated early works on redox-active ligands, due to the inability of conventional oxidation-state descriptors to provide a satisfying depiction of their electronic structures …”

Redox-Active Ligands in Electroassisted Catalytic H⁺ and CO₂ Reductions: Benefits and Risks

“…Among these catalysts, we can distinguish Ni‐based complexes with thiosemicarbazone ligands [26–30] . These type of ligands have already been studied and proved to be redox‐active [31–39] . Furthermore, the presence of S‐ and N‐atoms in the ligand permits the protonation of the ligand and can serve as proton relays [40–42] .…”

Nickel Complexes and Carbon Dots for Efficient Light‐Driven Hydrogen Production