Spectroscopy and Dynamics of Phosphonate-Derivatized Ruthenium Complexes on TiO<sub>2</sub>

Giokas, Paul G.; Miller, Stephen A.; Hanson, Kenneth; Norris, Michael R.; Glasson, Christopher R. K.; Concepcion, Javier J.; Bettis, Stephanie E.; Meyer, Thomas J.; Moran, Andrew M.

doi:10.1021/jp310155q

Cited by 45 publications

(87 citation statements)

References 65 publications

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“…An estimated  bET of ~1.3 eV suggests that for (OsT) 2 Rh and OsTRh the 1 GS surface crosses near the bottom of the 3 MMCT (Fig. 7, right), consistent with observation of 3 MMCT→ 1 GS on the timescale of vibrational relaxation ( vc ≈ 15 ps according to [5,40,47]). Back electron transfer for RuBRh and (RuB) 2 Rh is in the Marcus-inverted region, leading to slower return to the 1 GS.…”

Section: Model For Excited State Evolution and Decaysupporting

confidence: 78%

Ultrafast kinetics of supramolecules with a Ru(II)- or Os(II)-polypyridyl light absorber, cis-Rh(III)Cl2-polypyridyl electron collector, and 2,3-bis(2-pyridyl)pyrazine bridge

Zigler

Morseth

White

et al. 2017

Inorganica Chimica Acta

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The femtosecond transient absorption spectra (fsTA) and excited state kinetics for a series of six structurally related mixed-metal polypyridyl supramolecules are reported. Each complex consists of one or two light absorbers (LA) with Ru(II) or Os(II) centers attached to a Rh(III)centered electron collector (EC) by an aromatic bridging ligand (BL). The resulting bimetallic and trimetallic complexes have LA-BL-EC and LA-BL-EC-BL-LA architectures, respectively. Excitation at 470 nm light populates metal-to-bridging ligand charge transfer states (MLCT), showing a transient absorption band near 380 nm due to →* transitions of a bridging ligandlocalized radical anion and a transient bleach around 525 nm resulting from formal oxidation of the LA metal in the excited state. Loss of the ligand localized radical signal during the first 10 ps reflects conversion of the excited state population from an MLCT state into metal-to-metal (i.e. M(d)-to-Rh(d*)) charge transfer states (MMCT). Each complex shares a similar ultrafast component, indicating that the kinetics governing MLCT→MMCT population transfer do not depend on the nature of the LA. Return to the ground state, however, is strongly LA dependent and controlled by the free-energy difference between the MMCT state and ground state, as well as an associated large reorganization energy.

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Section: Model For Excited State Evolution and Decaysupporting

confidence: 78%

Ultrafast kinetics of supramolecules with a Ru(II)- or Os(II)-polypyridyl light absorber, cis-Rh(III)Cl2-polypyridyl electron collector, and 2,3-bis(2-pyridyl)pyrazine bridge

Zigler

Morseth

White

et al. 2017

Inorganica Chimica Acta

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“…Injection from the sensitizer into the TiO 2 occurs on the fs to ns time scale, 51,54,55 with the electrons appearing in the conduction band on the ps to ns time scale. 42 The TRTS scans shown in Figure 4 agree with this picture, with mobile electrons Recombination from the semiconductor occurs in the μs to ms range.…”

Section: ■ Resultsmentioning

confidence: 99%

Proton-Induced Trap States, Injection and Recombination Dynamics in Water-Splitting Dye-Sensitized Photoelectrochemical Cells

McCool

Swierk

Nemes

et al. 2016

ACS Appl. Mater. Interfaces

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Water-splitting dye-sensitized photoelectrochemical cells (WS-DSPECs) utilize a sensitized metal oxide and a water oxidation catalyst in order to generate hydrogen and oxygen from water. Although the Faradaic efficiency of water splitting is close to unity, the recombination of photogenerated electrons with oxidized dye molecules causes the quantum efficiency of these devices to be low. It is therefore important to understand recombination mechanisms in order to develop strategies to minimize them. In this paper, we discuss the role of proton intercalation in the formation of recombination centers. Proton intercalation forms nonmobile surface trap states that persist on time scales that are orders of magnitude longer than the electron lifetime in TiO2. As a result of electron trapping, recombination with surface-bound oxidized dye molecules occurs. We report a method for effectively removing the surface trap states by mildly heating the electrodes under vacuum, which appears to primarily improve the injection kinetics without affecting bulk trapping dynamics, further stressing the importance of proton control in WS-DSPECs.

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“…20 The presence of multiple kinetic components has been observed for other related sensitizers and arises from a number of factors, including the dye-binding motifs, electronic coupling and overlap of the dye donor levels with the TiO 2 acceptor states. [22][23][24] Furthermore, based on the analysis of the transient spectra 25 there is negligible ultrafast (τ<200 fs) electron injection in this complex, and by 1.4 ns the overall injection yield is 45%. 26 Photoexcitation of the PF-Ru-A//TiO 2 film at 450 nm gives rise to similar spectral features as seen for the Model-Ru-A//TiO 2 film at early times (Fig.…”

Section: Fabrication Of Dye Sensitized Solar Cells (Dsscsmentioning

confidence: 94%

Light Harvesting and Charge Separation in a π-Conjugated Antenna Polymer Bound to TiO₂

et al. 2014

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This paper describes photophysical and photoelectrochemical characterization of a light harvesting polychromophore array featuring a polyfluorene backbone with covalently Ru(II) polypyridyl complexes (PF-Ru-A), adsorbed on the surface of mesostructured TiO 2 (PFRu-A//TiO2). The surface adsorbed polymer is characterized by transmission electron microscopy (TEM), scanning electron microscopy (SEM) and attenuated total reflectanceFourier transform infrared (ATR-FTIR) spectroscopy, providing evidence for the morphology of the surface adsorbed polymer and the mode of binding. Photoexcitation of the Ru complexes bound to the metal oxide surface (proximal) results in electron injection into the conduction band of TiO 2 , which is then followed by ultrafast hole transfer to the polymer to form oxidized polyfluorene (PF + ). More interestingly, chromophores that are not directly bound to the TiO 2 interface (distal) that are excited participate in site-to-site energy transfer processes that transport the excited state to surface bound chromophores where charge injection occurs, underscoring the antenna-like nature of the polymer assembly. The charge separated state is long lived and persists for >100 µs, a consequence of the increased separation between the hole and injected electron.

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Spectroscopy and Dynamics of Phosphonate-Derivatized Ruthenium Complexes on TiO₂

Cited by 45 publications

References 65 publications

Ultrafast kinetics of supramolecules with a Ru(II)- or Os(II)-polypyridyl light absorber, cis-Rh(III)Cl2-polypyridyl electron collector, and 2,3-bis(2-pyridyl)pyrazine bridge

Ultrafast kinetics of supramolecules with a Ru(II)- or Os(II)-polypyridyl light absorber, cis-Rh(III)Cl2-polypyridyl electron collector, and 2,3-bis(2-pyridyl)pyrazine bridge

Proton-Induced Trap States, Injection and Recombination Dynamics in Water-Splitting Dye-Sensitized Photoelectrochemical Cells

Light Harvesting and Charge Separation in a π-Conjugated Antenna Polymer Bound to TiO₂

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Spectroscopy and Dynamics of Phosphonate-Derivatized Ruthenium Complexes on TiO2

Cited by 45 publications

References 65 publications

Ultrafast kinetics of supramolecules with a Ru(II)- or Os(II)-polypyridyl light absorber, cis-Rh(III)Cl2-polypyridyl electron collector, and 2,3-bis(2-pyridyl)pyrazine bridge

Ultrafast kinetics of supramolecules with a Ru(II)- or Os(II)-polypyridyl light absorber, cis-Rh(III)Cl2-polypyridyl electron collector, and 2,3-bis(2-pyridyl)pyrazine bridge

Proton-Induced Trap States, Injection and Recombination Dynamics in Water-Splitting Dye-Sensitized Photoelectrochemical Cells

Light Harvesting and Charge Separation in a π-Conjugated Antenna Polymer Bound to TiO2

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About

Spectroscopy and Dynamics of Phosphonate-Derivatized Ruthenium Complexes on TiO₂

Light Harvesting and Charge Separation in a π-Conjugated Antenna Polymer Bound to TiO₂