Your search keyword '"Sazanovich, Igor V."' showing total 266 results

251. Spironaphthoxazine switchable dyes for biological imaging.

Author

Xiong Y, Vargas Jentzsch A, Osterrieth JWM, Sezgin E, Sazanovich IV, Reglinski K, Galiani S, Parker AW, Eggeling C, and Anderson HL

Abstract

Recent developments in super-resolution microscopy have significantly expanded the requirements for switchable dyes, leading to demand for specially designed molecular switches. We report the synthesis and characterization of a spironaphthoxazine photochromic switch (a derivative of palatinate purple) displaying high photoconversion (85-95%) under readily accessible 405 nm light, broad absorption in the visible, and excellent fatigue resistance. The indole substituent on this spironaphthoxazine is twisted out of conjugation with the naphthalene unit, yet it is crucial for activation with visible light. The open colored merocyanine form of the spironaphthoxazine reverts to the closed form with a lifetime of 4.7 s in dichloromethane at 20 °C; this thermal reversion is even faster in more polar solvents. The photochemical quantum yields for ring-opening and ring-closing are approximately 8% and 1%, respectively, in dichloromethane. The ring-opening and ring-closing reactions have been characterized by time-resolved infrared and transient absorption spectroscopies. Ring opening occurs rapidly ( τ = 2.1 ns) and efficiently (∼90%) from the singlet excited state to form an intermediate (assigned as a cisoid merocyanine), which returns to the closed ground state ( τ = 4.5 ns) in competition with relaxation to the transoid open form ( τ = 40 ns). Photochemical ring closing is a faster and simpler process: the excited state proceeds to the closed spirooxazine with a time constant of 0.28 ns. This photochromic switch can be used in conjunction with commercial fluorescent dyes to create a small-molecule switchable fluorescent dyad that shows high contrast and good fatigue resistance in living cells. These properties make the dyads suitable for application in RESOLFT microscopy.

Published

2018

252. Anion-Mediated Photophysical Behavior in a C 60 Fullerene [3]Rotaxane Shuttle.

Author

Barendt TA, Rašović I, Lebedeva MA, Farrow GA, Auty A, Chekulaev D, Sazanovich IV, Weinstein JA, Porfyrakis K, and Beer PD

Abstract

By addressing the challenge of controlling molecular motion, mechanically interlocked molecular machines are primed for a variety of applications in the field of nanotechnology. Specifically, the designed manipulation of communication pathways between electron donor and acceptor moieties that are strategically integrated into dynamic photoactive rotaxanes and catenanes may lead to efficient artificial photosynthetic devices. In this pursuit, a novel [3]rotaxane molecular shuttle consisting of a four-station bis-naphthalene diimide (NDI) and central C 60 fullerene bis-triazolium axle component and two mechanically bonded ferrocenyl-functionalized isophthalamide anion binding site-containing macrocycles is constructed using an anion template synthetic methodology. Dynamic coconformational anion recognition-mediated shuttling, which alters the relative positions of the electron donor and acceptor motifs of the [3]rotaxane's macrocycle and axle components, is demonstrated initially by 1 H NMR spectroscopy. Detailed steady-state and time-resolved UV-vis-IR absorption and emission spectroscopies as well as electrochemical studies are employed to further probe the anion-dependent positional macrocycle-axle station state of the molecular shuttle, revealing a striking on/off switchable emission response induced by anion binding. Specifically, the [3]rotaxane chloride coconformation, where the ferrocenyl-functionalized macrocycles reside at the center of the axle component, precludes electron transfer to NDI, resulting in the switching-on of emission from the NDI fluorophore and concomitant formation of a C 60 fullerene-based charge-separated state. By stark contrast, in the absence of chloride as the hexafluorophosphate salt, the ferrocenyl-functionalized macrocycles shuttle to the peripheral NDI axle stations, quenching the NDI emission via formation of a NDI-containing charge-separated state. Such anion-mediated control of the photophysical behavior of a rotaxane through molecular motion is unprecedented.

Published

2018

253. Variation in LOV Photoreceptor Activation Dynamics Probed by Time-Resolved Infrared Spectroscopy.

Author

Iuliano JN, Gil AA, Laptenok SP, Hall CR, Tolentino Collado J, Lukacs A, Hag Ahmed SA, Abyad J, Daryaee T, Greetham GM, Sazanovich IV, Illarionov B, Bacher A, Fischer M, Towrie M, French JB, Meech SR, and Tonge PJ

Subjects

Binding Sites, Crystallography, X-Ray, Cysteine chemistry, Flavin Mononucleotide chemistry, Hydrogen Bonding, Models, Molecular, Photobleaching, Photochemistry, Photoreceptors, Microbial chemistry, Photoreceptors, Plant chemistry, Protein Conformation, Protein Domains, Protein Structure, Secondary, Recombinant Proteins chemistry, Recombinant Proteins radiation effects, Subtraction Technique, Photoreceptors, Microbial radiation effects, Photoreceptors, Plant radiation effects, Spectroscopy, Fourier Transform Infrared methods

Abstract

The light, oxygen, voltage (LOV) domain proteins are blue light photoreceptors that utilize a noncovalently bound flavin mononucleotide (FMN) cofactor as the chromophore. The modular nature of these proteins has led to their wide adoption in the emerging fields of optogenetics and optobiology, where the LOV domain has been fused to a variety of output domains leading to novel light-controlled applications. In this work, we extend our studies of the subpicosecond to several hundred microsecond transient infrared spectroscopy of the isolated LOV domain AsLOV2 to three full-length photoreceptors in which the LOV domain is fused to an output domain: the LOV-STAS protein, YtvA, the LOV-HTH transcription factor, EL222, and the LOV-histidine kinase, LovK. Despite differences in tertiary structure, the overall pathway leading to cysteine adduct formation from the FMN triplet state is highly conserved, although there are slight variations in rate. However, significant differences are observed in the vibrational spectra and kinetics after adduct formation, which are directly linked to the specific output function of the LOV domain. While the rate of adduct formation varies by only 3.6-fold among the proteins, the subsequent large-scale structural changes in the full-length LOV photoreceptors occur over the micro- to submillisecond time scales and vary by orders of magnitude depending on the different output function of each LOV domain.

Published

2018

254. Directly Coupled Versus Spectator Linkers on Diimine Pt II Acetylides-Change the Structure, Keep the Function?

Author

Archer SA, Keane T, Delor M, Bevon E, Auty AJ, Chekulaev D, Sazanovich IV, Towrie M, Meijer AJHM, and Weinstein JA

Abstract

Modification of light-harvesting units with anchoring groups for surface attachment often compromises light-harnessing properties. Herein, a series of [donor-acceptor-anchor] platinum(II) diimine (bis-)acetylides was developed in order to systematically compare the effect of conjugated versus electronically decoupled modes of attachment of protected anchoring groups on the photophysical properties of light-harvesting units. The first examples of "decoupled" phosphonate diimine Pt II complexes are reported, and their properties are compared and contrasted to those of carboxylate analogues studied by a diversity of methods. Ultrafast time-resolved IR and transient absorption spectroscopy revealed that all complexes have a charge-transfer (CT) lowest excited state with lifetimes between 2 and 14 ns. Vibrational signatures and dynamics of CT states were identified; the assignment of electronic states and their vibrational origin was aided by TDDFT calculations. Ultrafast energy redistribution accompanied by structural changes was directly captured in the CT states. A significant difference between the structures of the electronic ground and CT excited states, as well as differences in the structural reorganisation in the complexes bearing directly attached or electronically decoupled anchoring groups, was discovered. This work demonstrates that decoupling of the anchoring group from the light-harvesting core by a saturated spacer is an easy approach to combine surface attachment with high reduction potential and ten times longer lifetime of the CT excited state of the light-absorbing unit, and retain electron-transfer photoreactivity essential for light-harvesting applications., (© 2017 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

255. Directing the path of light-induced electron transfer at a molecular fork using vibrational excitation.

Author

Delor M, Archer SA, Keane T, Meijer AJHM, Sazanovich IV, Greetham GM, Towrie M, and Weinstein JA

Abstract

Ultrafast electron transfer in condensed-phase molecular systems is often strongly coupled to intramolecular vibrations that can promote, suppress and direct electronic processes. Recent experiments exploring this phenomenon proved that light-induced electron transfer can be strongly modulated by vibrational excitation, suggesting a new avenue for active control over molecular function. Here, we achieve the first example of such explicit vibrational control through judicious design of a Pt(II)-acetylide charge-transfer donor-bridge-acceptor-bridge-donor 'fork' system: asymmetric 13 C isotopic labelling of one of the two -C≡C- bridges makes the two parallel and otherwise identical donor→acceptor electron-transfer pathways structurally distinct, enabling independent vibrational perturbation of either. Applying an ultrafast UV pump (excitation)-IR pump (perturbation)-IR probe (monitoring) pulse sequence, we show that the pathway that is vibrationally perturbed during UV-induced electron transfer is dramatically slowed down compared to its unperturbed counterpart. One can thus choose the dominant electron transfer pathway. The findings deliver a new opportunity for precise perturbative control of electronic energy propagation in molecular devices.

Published

2017

256. Oxygen Mapping of Melanoma Spheroids using Small Molecule Platinum Probe and Phosphorescence Lifetime Imaging Microscopy.

Author

Raza A, Colley HE, Baggaley E, Sazanovich IV, Green NH, Weinstein JA, Botchway SW, MacNeil S, and Haycock JW

Subjects

Cell Line, Tumor, Cell Proliferation, Humans, Immunohistochemistry, Melanoma diagnostic imaging, Melanoma pathology, Microscopy, Fluorescence methods, Spheroids, Cellular, Tumor Burden, Tumor Cells, Cultured, Luminescent Measurements methods, Melanoma metabolism, Molecular Imaging methods, Molecular Probes metabolism, Oxygen metabolism, Platinum metabolism

Abstract

Solid tumours display varied oxygen levels and this characteristic can be exploited to develop new diagnostic tools to determine and exploit these variations. Oxygen is an efficient quencher of emission of many phosphorescent compounds, thus oxygen concentration could in many cases be derived directly from relative emission intensity and lifetime. In this study, we extend our previous work on phosphorescent, low molecular weight platinum(II) complex as an oxygen sensing probe to study the variation in oxygen concentration in a viable multicellular 3D human tumour model. The data shows one of the first examples of non-invasive, real-time oxygen mapping across a melanoma tumour spheroid using one-photon phosphorescence lifetime imaging microscopy (PLIM) and a small molecule oxygen sensitive probe. These measurements were quantitative and enabled real time oxygen mapping with high spatial resolution. This combination presents as a valuable tool for optical detection of both physiological and pathological oxygen levels in a live tissue mass and we suggest has the potential for broader clinical application.

Published

2017

257. Inosine Can Increase DNA's Susceptibility to Photo-oxidation by a Ru II Complex due to Structural Change in the Minor Groove.

Author

Keane PM, Hall JP, Poynton FE, Poulsen BC, Gurung SP, Clark IP, Sazanovich IV, Towrie M, Gunnlaugsson T, Quinn SJ, Cardin CJ, and Kelly JM

Subjects

Base Sequence, Binding Sites, Electron Transport, Guanine chemistry, Intercalating Agents chemistry, Models, Molecular, Molecular Structure, Oxidation-Reduction, Spectrophotometry, Ultraviolet methods, Spectroscopy, Fourier Transform Infrared methods, Stereoisomerism, Structure-Activity Relationship, Thermodynamics, Coordination Complexes chemistry, DNA chemistry, Inosine chemistry, Oxidants, Photochemical chemistry, Ruthenium chemistry

Abstract

Key to the development of DNA-targeting phototherapeutic drugs is determining the interplay between the photoactivity of the drug and its binding preference for a target sequence. For the photo-oxidising lambda-[Ru(TAP) 2 (dppz)] 2+ (Λ-1) (dppz=dipyridophenazine) complex bound to either d{T 1 C 2 G 3 G 4 C 5 G 6 C 7 C 8 G 9 A 10 } 2 (G9) or d{TCGGCGCCIA} 2 (I9), the X-ray crystal structures show the dppz intercalated at the terminal T 1 C 2 ;G 9 A 10 step or T 1 C 2 ;I 9 A 10 step. Thus substitution of the G 9 nucleobase by inosine does not affect intercalation in the solid state although with I9 the dppz is more deeply inserted. In solution it is found that the extent of guanine photo-oxidation, and the rate of back electron-transfer, as determined by pico- and nanosecond time-resolved infrared and transient visible absorption spectroscopy, is enhanced in I9, despite it containing the less oxidisable inosine. This is attributed to the nature of the binding in the minor groove due to the absence of an NH 2 group. Similar behaviour and the same binding site in the crystal are found for d{TTGGCGCCAA} 2 (A9). In solution, we propose that intercalation occurs at the C 2 G 3 ;C 8 I 9 or T 2 G 3 ;C 8 A 9 steps, respectively, with G 3 the likely target for photo-oxidation. This demonstrates how changes in the minor groove (in this case removal of an NH 2 group) can facilitate binding of Ru II dppz complexes and hence influence any sensitised reactions occurring at these sites. No similar enhancement of photooxidation on binding to I9 is found for the delta enantiomer., (© 2017 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

258. Increasing p-type dye sensitised solar cell photovoltages using polyoxometalates.

Author

El Moll H, Black FA, Wood CJ, Al-Yasari A, Reddy Marri A, Sazanovich IV, Gibson EA, and Fielden J

Abstract

Lindqvist polyoxometalate (POM) additives increase V OC in p-type DSSCs by up to 140%, yielding substantial efficiency gains for poorly matched dyes and redox mediators. For better dye/electrolyte combinations, these gains are typically outweighed by losses in J SC . Charge lifetime and transient IR measurements show that this is due to retardation of both recombination and electron transfer to the mediator, and a positive shift in the NiO valence band edge. The POMs also show their own, limited sensitizing effect.

Published

2017

259. Metal Complexes for Two-Photon Photodynamic Therapy: A Cyclometallated Iridium Complex Induces Two-Photon Photosensitization of Cancer Cells under Near-IR Light.

Author

McKenzie LK, Sazanovich IV, Baggaley E, Bonneau M, Guerchais V, Williams JA, Weinstein JA, and Bryant HE

Subjects

Apoptosis drug effects, Cell Line, Tumor, Coordination Complexes chemistry, Humans, Iridium chemistry, Light, Neoplasms metabolism, Photochemotherapy, Photosensitizing Agents chemistry, Singlet Oxygen metabolism, Coordination Complexes pharmacology, Iridium pharmacology, Neoplasms drug therapy, Photosensitizing Agents pharmacology

Abstract

Photodynamic therapy (PDT) uses photosensitizers (PS) which only become cytotoxic upon light-irradiation. Transition-metal complexes are highly promising PS due to long excited-state lifetimes, and high photo-stabilities. However, these complexes usually absorb higher-energy UV/Vis light, whereas the optimal tissue transparency is in the lower-energy NIR region. Two-photon excitation (TPE) can overcome this dichotomy, with simultaneous absorption of two lower-energy NIR-photons populating the same PS-active excited state as one higher-energy photon. We introduce two low-molecular weight, long-lived and photo-stable iridium complexes of the [Ir(N^C) 2 (N^N)] + family with high TP-absorption, which localise to mitochondria and lysosomal structures in live cells. The compounds are efficient PS under 1-photon irradiation (405 nm) resulting in apoptotic cell death in diverse cancer cell lines at low light doses (3.6 J cm -2 ), low concentrations, and photo-indexes greater than 555. Remarkably 1 also displays high PS activity killing cancer cells under NIR two-photon excitation (760 nm), which along with its photo-stability indicates potential future clinical application., (© 2016 The Authors. Published by Wiley-VCH Verlag GmbH & Co. KGaA.)

Published

2017

260. Photoinduced energy- and electron-transfer from a photoactive coordination cage to bound guests.

Author

Piper JR, Cletheroe L, Taylor CG, Metherell AJ, Weinstein JA, Sazanovich IV, and Ward MD

Subjects

Electron Transport, Energy Transfer, Fluorescence, Molecular Structure, Photochemical Processes, Naphthols chemistry

Abstract

In a coordination cage which contains an array of twelve naphthyl chromophores surrounding a central cavity, photoinduced energy or electron-transfer can occur from the chromophore array to the bound guest in supramolecular host/guest complexes.

Published

2016

261. Direct observation by time-resolved infrared spectroscopy of the bright and the dark excited states of the [Ru(phen) 2 (dppz)] 2+ light-switch compound in solution and when bound to DNA.

Author

Poynton FE, Hall JP, Keane PM, Schwarz C, Sazanovich IV, Towrie M, Gunnlaugsson T, Cardin CJ, Cardin DJ, Quinn SJ, Long C, and Kelly JM

Abstract

The [Ru(phen) 2 (dppz)] 2+ complex ( 1 ) is non-emissive in water but is highly luminescent in organic solvents or when bound to DNA, making it a useful probe for DNA binding. To date, a complete mechanistic explanation for this "light-switch" effect is still lacking. With this in mind we have undertaken an ultrafast time resolved infrared (TRIR) study of 1 and directly observe marker bands between 1280-1450 cm -1 , which characterise both the emissive "bright" and the non-emissive "dark" excited states of the complex, in CD 3 CN and D 2 O respectively. These characteristic spectral features are present in the [Ru(dppz) 3 ] 2+ solvent light-switch complex but absent in [Ru(phen) 3 ] 2+ , which is luminescent in both solvents. DFT calculations show that the vibrational modes responsible for these characteristic bands are predominantly localised on the dppz ligand. Moreover, they reveal that certain vibrational modes of the "dark" excited state couple with vibrational modes of two coordinating water molecules, and through these to the bulk solvent, thus providing a new insight into the mechanism of the light-switch effect. We also demonstrate that the marker bands for the "bright" state are observed for both Λ- and Δ-enantiomers of 1 when bound to DNA and that photo-excitation of the complex induces perturbation of the guanine and cytosine carbonyl bands. This perturbation is shown to be stronger for the Λ-enantiomer, demonstrating the different binding site properties of the two enantiomers and the ability of this technique to determine the identity and nature of the binding site of such intercalators.

Published

2016

262. Enantiomeric Conformation Controls Rate and Yield of Photoinduced Electron Transfer in DNA Sensitized by Ru(II) Dipyridophenazine Complexes.

Author

Keane PM, Poynton FE, Hall JP, Clark IP, Sazanovich IV, Towrie M, Gunnlaugsson T, Quinn SJ, Cardin CJ, and Kelly JM

Subjects

Electron Transport, Electrons, Stereoisomerism, DNA chemistry, Ruthenium chemistry

Abstract

Photosensitized oxidation of guanine is an important route to DNA damage. Ruthenium polypyridyls are very useful photosensitizers, as their reactivity and DNA-binding properties are readily tunable. Here we show a strong difference in the reactivity of the two enantiomers of [Ru(TAP)2(dppz)](2+), by using time-resolved visible and IR spectroscopy. This reveals that the photosensitized one-electron oxidation of guanine in three oligonucleotide sequences proceeds with similar rates and yields for bound Δ-[Ru(TAP)2(dppz)](2+), whereas those for the Λ enantiomer are very sensitive to base sequence. It is proposed that these differences are due to preferences of each enantiomer for different binding sites in the duplex.

Published

2015

263. Electrochemistry, chemical reactivity, and time-resolved infrared spectroscopy of donor-acceptor systems [(Q(x))Pt(pap(y))] (Q = substituted o-quinone or o-iminoquinone; pap = phenylazopyridine).

Author

Deibel N, Schweinfurth D, Hohloch S, Delor M, Sazanovich IV, Towrie M, Weinstein JA, and Sarkar B

Abstract

The donor-acceptor complex [((O,N)Q(2-))Pt(pap(0))] (1; pap = phenylazopyridine, (O,N)Q(0) = 4,6-di-tert-butyl-N-phenyl-o-iminobenzoquinone), which displays strong π-bonding interactions and shows strong absorption in the near-IR region, has been investigated with respect to its redox-induced reactivity and electrochemical and excited-state properties. The one-electron-oxidized product [((O,N)Q(•-))Pt(pap(0))](BF4) ([1]BF4) was chemically isolated. Single-crystal X-ray diffraction studies establish the iminosemiquinone form of (O,N)Q in [1](+). Simulation of the cyclic voltammograms of 1 recorded in the presence of PPh3 elucidates the mechanism and delivers relevant thermodynamic and kinetic parameters for the redox-induced reaction with PPh3. The thermodynamically stable product of this reaction, complex [((O,N)Q(•-)) Pt(PPh3)2](PF6) ([2]PF6), was isolated and characterized by X-ray crystallography, electrochemistry, and electron paramagnetic resonance spectroscopy. Picosecond time-resolved infrared spectroscopic studies on complex 1b (one of the positional isomers of 1) and its analogue [((O,O)Q(2-))Pt(pap(0))] (3; (O,O)Q = 3,5-di-tert-butyl-o-benzoquinone) provided insight into the excited-state dynamics and revealed that the nature of the lowest excited state in the amidophenolate complex 1b is primarily diimine-ligand-based, while it is predominantly an interligand charge-transfer state in the case of 3. Density functional theory calculations on [1](n+) provided further insight into the nature of the frontier orbitals of various redox forms and vibrational mode assignments. We discuss the mechanistic details of the newly established redox-induced reactivity of 1 with electron donors and propose a mechanism for this process.

Published

2014

264. Highly efficient visible-light driven photochromism: developments towards a solid-state molecular switch operating through a triplet-sensitised pathway.

Author

Brayshaw SK, Schiffers S, Stevenson AJ, Teat SJ, Warren MR, Bennett RD, Sazanovich IV, Buckley AR, Weinstein JA, and Raithby PR

Abstract

We introduce a new highly efficient photochromic organometallic dithienylethene (DTE) complex, the first instance of a DTE core symmetrically modified by two Pt(II) chromophores [Pt(PEt(3))(2)(C≡C)(DTE)(C≡C)Pt(PEt(3))(2)Ph] (1), which undergoes ring-closure when activated by visible light in solvents of different polarity, in thin films and even in the solid state. Complex 1 has been synthesised and fully photophysically characterised by (resonance) Raman and transient absorption spectroscopy complemented by calculations. The ring-closing photoconversion in a single crystal of 1 has been followed by X-ray crystallography. This process occurs with the extremely high yield of 80%--considerably outperforming the other DTE derivatives. Remarkably, the photocyclisation of 1 occurs even under visible light (>400 nm), which is not absorbed by the non-metallated DTE core HC≡C(DTE)C≡CH (2) itself. This unusual behaviour and the high photocyclisation yields in solution are attributed to the presence of a heavy atom in 1 that enables a triplet-sensitised photocyclisation pathway, elucidated by transient absorption spectroscopy and DFT calculations. The results of resonance Raman investigation confirm the involvement of the alkynyl unit in the frontier orbitals of both closed and open forms of 1 in the photocyclisation process. The changes in the Raman spectra upon cyclisation have permitted the identification of Raman marker bands, which include the acetylide stretching vibration. Importantly, these bands occur in the spectral region unobstructed by other vibrations and can be used for non-destructive monitoring of photocyclisation/photoreversion processes and for optical readout in this type of efficiently photochromic thermally stable systems. This study indicates a strategy for generating efficient solid-state photoswitches in which modification of the Pt(II) units has the potential to tune absorption properties and hence operational wavelength across the visible range., (Copyright © 2011 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2011

265. Structure and ultrafast dynamics of the charge-transfer excited state and redox activity of the ground state of mono- and binuclear platinum(II) diimine catecholate and bis-catecholate complexes: a transient absorption, TRIR, DFT, and electrochemical study.

Author

Best J, Sazanovich IV, Adams H, Bennett RD, Davies ES, Meijer AJ, Towrie M, Tikhomirov SA, Bouganov OV, Ward MD, and Weinstein JA

Subjects

Catechols chemical synthesis, Crystallography, X-Ray, Electrochemistry, Models, Molecular, Molecular Structure, Organoplatinum Compounds chemical synthesis, Oxidation-Reduction, Spectrophotometry, Infrared, Time Factors, Vibration, Catechols chemistry, Organoplatinum Compounds chemistry, Quantum Theory

Abstract

A series of mononuclear complexes of the type [Pt(Bu(2)cat)(4,4'-R(2)-bipy)] [where Bu(2)cat is the dianion of 3,5-(t)Bu(2)-catechol and R = H, (t)Bu, or C(O)NEt(2)] and analogous dinuclear complexes based on the "back-to-back" bis-catechol ligand 3,3',4,4'-tetrahydroxybiphenyl have been studied in detail in both their ground and excited states by a range of physical methods including electrochemistry, UV/vis/near-IR, IR, and electron paramagnetic resonance spectroelectrochemistry, and time-resolved IR (TRIR) and transient absorption (TA) spectroscopy. Density functional theory calculations have been performed to support these studies, which provide a detailed picture of the ground- and excited-state electronic structures, and excited-state dynamics, of these complexes. Notable observations include the following: (i) for the first time, the lowest-energy catecholate → bipyridine (bpy) ligand-to-ligand charge-transfer (LL'CT) excited states of these chromophores have been studied by TRIR spectroscopy, showing a range of transient bands associated with the bpy radical anion and semiquinone species, and back-electron-transfer occurring in hundreds of picoseconds; (ii) strong electronic coupling between the two catecholate units in the bridging ligand of the dinuclear complexes results in a delocalized, planar (class 3) "mixed-valence" catecholate(2-)/semiquinone(•-) state formed by one-electron oxidation of the bridging ligand; (iii) in the LL'CT excited state of the dinuclear complexes, the bridging ligand is symmetrical and delocalized, whereas the bpy radical anion is localized at one terminus of the complex. This study is the first example of an investigation of excited-state behavior in platinum(II) catecholate complexes, performed with the use of picosecond TRIR and femtosecond TA spectroscopy.

Published

2010

266. Structural control of the excited-state dynamics of bis(dipyrrinato)zinc complexes: self-assembling chromophores for light-harvesting architectures.

Author

Sazanovich IV, Kirmaier C, Hindin E, Yu L, Bocian DF, Lindsey JS, and Holten D

Abstract

The replacement of the phenyl rings at the 5,5'-positions of a bis(dipyrrinato)zinc complex with mesityl groups transforms the molecule from a very weak emitter that deactivates rapidly after photoexcitation (Phif = 0.006; tau approximately 90 ps) to a highly fluorescent chromophore with a long-lived singlet excited state (Phif = 0.36; tau approximately 3 ns). The results demonstrate that steric constraints on aryl-ring internal rotation dramatically alter the excited-state properties of 5,5'-substituted bis(dipyrrinato)metal complexes. The insights establish the foundation for tuning the photophysical properties of these chromophores for use in diverse photochemical applications.

Published

2004