Effect of temperature and dynamic fluorescence quenching on proton transfer in 3-hydroxyflavone

The effect of temperature and a fluorescence quencher on the properties of the excited states of 3-hydroxyflavone is considered. The absorption spectra and the spectra of dual fluorescence exited by electromagnetic radiation in the region of the S ₁ absorption band of 3-hydroxyflavone in acetonitrile are measured and analyzed in the temperature range of 20–80°C. The fluorescence lifetimes are also measured at different temperatures. As a quencher of excited states we used the TEMPO spin quencher. The analysis of the fluorescence parameters shows that the heating of the solution to 60°C leads to a considerable (by a factor of 1.24) increase in the proton-transfer rate for the first absorption band. The introduction of a quencher decreases the yield of the two fluorescence bands by the diffusion mechanism and increases the proton-transfer rate with respect to the rate in the pure solvent by a factor of 1.16 at room temperature and 1.65 at T = 80°C.     

Separation of a weak fluorescence signal of 3-hydroxyflavone using dynamic quenching

The spectral and time characteristics of the dual fluorescence of a 3-hydroxyflavone probe in a solution with a fluorescence quencher are studied in the temperature range of 20–80°C. At room temperature, the fluorescence consists of two bands that belong to the normal and tautomeric forms of the luminophore, while heating of the solution results in the appearance of an additional fluorescence band belonging to the anionic form of the luminophore. The additional band is strongly overlapped with the band of the normal form, and its intensity rapidly increases with temperature to exceed the intensity of the normal band. The introduction of the TEMPO spin quencher of excited states into the solution completely quenches the fluorescence of the anionic form, which allows one to record the pure dual fluorescence of 3-hydroxyflavone in the entire temperature range studied. The detection of probe signals in the pure form is important for applications of proton transfer molecular probes using the intensity ratio of the fluorescence bands as the main sensitive parameter.     

Dynamic quenching of the multiband fluorescence of 3-hydroxyflavone

The properties of emission, absorption, and dual fluorescence excitation of 3-hydroxyflavone in acetonitrile are studied under the conditions of dynamic quenching by potassium iodide with concentrations up to 4 × 10^?2 M. The normal and tautomeric forms undergo quenching, which is more efficient for the tautomeric form. An interesting circumstance is that the absorption in the S ₀ → S ₁ and S ₀ → S ₂ singlet bands of the solution increases with increasing quencher concentration in the whole region of concentrations used, the steepest rise being recorded in the concentration region from 0 to 5 × 10^?3 M. The intensities and quantum yields of the two fluorescence bands show rather complicated nonlinear dependences on the quencher concentration. The long-wavelength fluorescence band, which belongs to the tautomeric form of 3-hydroxyflavone, is quenched considerably stronger. The experimental results reveal the kinetic character of the excited-state proton transfer in molecules of 3-hydroxyflavone in acetonitrile.     

Dynamic fluorescence quenching and the highest excited states of molecules

The dynamic fluorescence quenching in organic molecules, or quenching of the second kind according to Vavilov’s classification, is an efficient method of investigating excited states in solutions and is widely used in various fields. The effect of quenching on the intensity of the fluorescence from the first and higher singlet states of organic molecules is studied. The results may serve as a basis for determining the nature of the short-wavelength luminescence and can be used to distinguish the S _n fluorescence from the comparably intense luminescence of impurities, which is a very important problem when investigating such emissions. A method for obtaining dynamic quenching by specially chosen quenchers is proposed. The method is based on an experimentally found strong increase in the constants of bimolecular collisions of luminophore and quencher molecules when the luminophore is excited through the highest singlet states.     

Direct photoexcitation of intramolecular proton transfer states in 3-hydroxyflavone

It is shown that the photoexcitation of 3-hydroxyflavone at the red edge of its absorption spectrum can directly excite luminescing intramolecular proton-transfer forms of molecules of this compound. This offers new possibilities for studying the fundamental properties of molecular objects with intramolecular proton transfer, which are currently considered as promising multiparametric molecular sensors.     

Intramolecular proton transfer from the highest singlet states in 3-hydroxyflavone

It is found that the excitation spectra of the dual fluorescence of 3-hydroxyflavone are different for different recording wavelengths and that the intensity ratio of the emission of the normal and tautomeric (with intramolecular proton transfer) forms upon selective UV excitation in the regions of the S ₁, S ₂, and S ₃ singlet absorption bands strongly depends on the excitation wavelength. The results obtained directly point to the existence of an additional channel of population of the excited state of the tautomeric form and are explained by the intramolecular proton transfer through the S ₂ and S ₃ excited singlet states of fluorophore molecules. The constants of this transfer are estimated using analytical relations for the steady-state fluorescence excitation.     

Spectral properties of anionic form of 3-hydroxyflavone

The spectral and temporal characteristics of the fluorescence of the anionic form of some 3-hydroxiflavones in different solvents are studied. This form is observed under selective excitation in the region of the long-wavelength slope of the main absorption band, and its spectrum consists of a wide structureless band lying between the short- and long-wavelength fluorescence bands of these molecular probes. The fluorescence excitation spectra of the anionic form differ from the corresponding spectra of the normal and tautomeric forms. The addition of water to the solution leads to a gradual fluorescence quenching which is static or belongs to the second kind according to Vavilov’s classification, i.e., occurs in the ground state.     

Electronic properties of fluorenone in the excited states

The electronic spectrum of fluorenone has been studied by means of “molecules in molecules” calculations. Five π-π* transitions can be definitively assigned in the near-ultraviolet region. The electronic properties of the first singlet excited state obtained from solvent effects on the absorption and fluorescence bands are compared with the theoretical results.     

ESIPT reaction starting from S2 and S3 singlet states in 3-hydroxyflavone

Spectra fluorescence at excitation of emission within spectral intervals of S₃, S₂ and S₁ bands of absorption, and excitation at registration of fluorescence at maxima of blue and green bands of emission have been studied in 3-hydroxyflavone solution. A possibility of ESIPT reaction starting from S₃ and S₂ states of parent 3HF molecule was shown for the first time follows from observations of differences in excitation spectra of normal and tautomer forms of 3HF, and from different ratios of these forms intensities upon excitation in different ranges of UV spectra of absorption.     

The properties of 116in excited states

Gamma and conversion electron spectra from the ¹¹⁵In(n, γ)¹¹⁶In reaction in the energy range 20–700 keV and 20–850 keV respectively have been measured with bent crystal and magnetic spectrometers. Gamma-gamma coincidences in the energy range 50–500 keV have been investigated with Ge(Li)-Ge(Li) arrangement. Proton spectra from the 12 MeV deuteron-induced (d, p) reaction taken at the University of Pittsburgh Tandem Van de Graaf accelerator were reanalysed. The ¹¹⁶In level scheme consisting of 56 levels in the energy range 0–1.4 MeV has been constructed. Parity is determined for all the levels introduced. Unique spin values are assigned to 37 levels. The information obtained was used to place limits to the J-values for the rest of the levels. The main components of the wave function are established for 23 levels, considered to be components of p-n multiplets in which the proton hole and odd neutron are in in one of the Z = 28 → 50 and N = 50 → 82 shell states, respectively. Energy splittings of p-n configurations by residual interactions taken as a combination of short range Wigner and singlet forces have been calculated. It is noted that many excited states cannot be described in the framework of two-quasiparticle configurations.     

石墨烯量子点的磁性及激发态性质

利用密度泛函理论在B3LYP/6-31G(d)基组水平上研究了具有zigzag边界的石墨烯量子点,结果表明不同大小的石墨烯量子点的基态都是具有磁性的自旋三重态.其磁性一方面来源于zigzag边界上占有凸出位置的碳原子,另一方面来源于带有孤对电子的碳原子.从整体上看,除6b结构外,其他结构的能隙随着苯环数量的增加逐渐减小,而附加电荷却使体系能隙明显减小.用含时密度泛函理论(TD-DFT)对能隙为3.83 eV的由六个苯环排列成的三角形结构进行了激发态的计算,发现第十七激发态强度最大,能量为3.93 eV,对 关键词： 石墨烯量子点 磁性 能隙 激发态     

Studying reactions that proceed from highest excited states of molecules using fluorescence quenching

The steady-state monochromatic excitation of a luminophore that has fluorescing products is considered. The effect of dynamic quenching of highest excited states on the fluorescence of singlet states under its excitation via singlet S ₁ and S _n (n ≥ 2) states is discussed. It is shown that the use of the method of fluorescence dynamic quenching by foreign impurities opens new possibilities for studying photoreactions that proceed via S _n singlet states. A large number of primary photoprocesses are considered which include the electron density redistribution (the internal electron transfer) in the excited state, protolytic reactions, intramolecular proton transfer (phototautomerization), hydrogen bonding, and formation of excimers and exciplexes. It is shown that, upon dynamic quenching, the bimolecular quenching constant of an excited level depends on the amount of thermal energy released in the luminophore before the occurrence of the light emission event. Based on the experimental measurements of the fluorescence spectra at different quencher contents, the calculation of the Stern-Volmer constant for reaction products is considered in detail. It is shown that this constant can be most reliably determined from the dependence of the fluorescence intensity ratio of the initial reagents and the quencher product rather than from the dependence of the fluorescence intensity of the products on the concentration of the quencher. The relations determined are used in analysis of the experimental fluorescence spectra of solutions of 3-hydroxyflavone excited by radiation with different wavelengths lying in the range of the S ₁ and S ₂ absorption bands. The temperature behavior of the Stern-Volmer constant for different fluorescence bands of 3-hydroxyflavone is considered. It is shown that, if these constants for the normal and tautomeric forms are correctly determined, their temperature dependences are similar.     

The influence of femtosecond laser parameters on the wavepacket and population of the diabatic excited states of NaLi

Using the three-state model and time-dependent wavepacket method, the influence of the parameters of the intense femtosecond laser field on the wavepacket dynamic process of the double-minimum potential state 5¹Σ⁺ and the population of the ground and diabatic electronic states of NaLi are investigated. The calculations show that different femtosecond laser parameters result in different influences on the evolution of the wavepacket and the population of NaLi. With increasing laser intensity and wavelength the diabatic coupling strength between A and B states first strengthens and then weakens. The population interchanges between A and B states when the laser pulse disappears. The above results provide the suggestions and useful information for one to achieve quantum manipulation of the molecule in an experiment.     

Effect of temperature on the dynamic quenching of the dual fluorescence of molecules

The properties of the dual fluorescence of 3-hydroxyflavone in acetonitrile are studied under conditions of dynamic quenching by the spin quencher TEMPO in the temperature range from 20 to 80°C. 3-Hydroxyflavone is characterized by the intramolecular excited state proton transfer and its spectrum consists of two well-spaced fluorescence bands belonging to the normal and tautomeric forms. The fluorescence was selectively excited at wavelengths of 290, 304, and 340 nm, belonging to different absorption bands of the luminophore. The character and degree of the temperature quenching of the fluorescence depend on the excitation wavelength and are considerably different for normal and tautomeric fluorescence bands. The Stern-Volmer constants for both forms, calculated from the experimental data on the assumption of the diffusion mechanism of quenching of the excited states, increase with temperature. Both in the pure solutions and in the solutions with the quencher, the intensity ratio of the fluorescence of the initial form and the product increases with heating in the entire temperature range from 20 to 80°C for all the above excitation wavelengths. Original Russian Text ? V.I. Tomin, 2008, published in Optika i Spektroskopiya, 2008, Vol. 104, No. 6, pp. 926–933.     

The influence of temperature on the migration-accelerated quenching of phosphorescence of naphthalene in glassy toluene

The efficiency of migration-accelerated quenching of triplet excitations of naphthalene by oxygen molecules in an undegassed solution of glassy toluene is investigated as a function of temperature. The temperature dependence of the rate constant of the migration-accelerated quenching is established experimentally, and the activation energy of this process is determined. It is demonstrated that the enhancement of the migration-accelerated quenching with increasing temperature is caused by the reverse migration, i.e., by the increase in the probability of transfer of excitations in the process of their migration to higher energy levels of naphthalene within the limits of the statistical scatter.     

Cohesive properties of mercury clusters in the ground and excited states

Optimized structures and cohesive energies of small mercury clusters (Hg_N; N = 3–7, 13, 19) are calculated with the spin-orbit diatomics-in-molecules method. The theory takes into account the effect of s-p mixing which tends to enhance the binding energies in the ground state. It is shown that excimer clusters have significantly short optimum bond lengths and their atomic geometries differ considerably from those in the ground state. Excitation energy gap depends sensitively on both cluster size and nearest-neighbor separation. Numerical results are compared with other theories and experiments.     

AuZn和AuAl分子基态与低激发态的势能函数与热力学性质

用密度泛函理论B3LYP方法计算研究AuZn和AuAl分子基态与低激发态的结构与势能函数,导出分子的光谱数据.结果表明,AuZn和AuAl分子基态分别为X²Σ和X¹Σ,基态与低激发态的势能函数均可用Murrell-Sorbie函数来表达.AuZn分子低激发态a⁴Σ的绝热激发能为43529kJ/mol,AuAl分子低激发态a³Σ的绝热激发能为19991kJ/mol.计算固体AuZn和AuAl的内能和熵时,近似以气体分子的电子能和振动能代替固体分子的内能,用电子熵和振动熵代替固体分子的熵.在此近似下,计算得到AuZn和AuAl基态与低激发态固态分子生成反应热力学性质与温度的关系. 关键词： AuZn和AuAl B3LYP 热力学性质 势能函数     

Two-mode excited entangled coherent states and their entanglement properties

This paper introduces two types of two-mode excited entangled coherent states (TMEECSs) |Ψ_±(α,m,n)>, studies their entanglement characteristics, and investigates the influence of photon excitations on quantum entanglement. It shows that for the state |Ψ₊(α,m,m)> the two-mode photon excitations affect seriously entanglement character while the state |Ψ_-(α,m,m)> is always a maximally entangled state, and shows how such states can be produced by using cavity quantum electrodynamics and quantum measurements. It finds that the entanglement amount of the TMEECSs is larger than that of the single-mode excited entangled coherent states with the same photon excitation number.