Photoisomerization quantum yield is a fundamental photophysical property that should be accurately determined in the investigation of newly developed photoswitches. Here, we describe a set of procedures to measure the photoisomerization quantum yield of a photochromic hydrazone as a model bistable photoswitch.
Photoswitching organic molecules that undergo light-driven structural transformations are key components to construct adaptive molecular systems, and they are utilized in a wide variety of applications. In most studies employing photoswitches, several important photophysical properties such as maximum wavelengths of absorption and emission, molar attenuation coefficient, fluorescence lifetime, and photoisomerization quantum yield are carefully determined to investigate their electronic states and transition processes. However, measurement of the photoisomerization quantum yield, the efficiency of photoisomerization with respect to the absorbed photons, in a typical laboratory setting is often complicated and prone to error because it requires the implementation of rigorous spectroscopic measurements and calculations based on an appropriate integration method. This article introduces a set of procedures to measure the photoisomerization quantum yield of a bistable photoswitch using a photochromic hydrazone. We anticipate that this article will be a useful guide for the investigation of bistable photoswitches that are being increasingly developed.
Photochromic organic molecules have attracted considerable attention in a wide range of scientific disciplines as light is a unique stimulus that can drive a system away from its thermodynamic equilibrium non-invasively1. Irradiation of light with appropriate energies allows structural modulation of photoswitches with high spatiotemporal precision2,3,4. Thanks to these advantages, various types of photoswitches based on configurational isomerization of the double bonds (e.g., stilbenes, azobenzenes, imines, fumaramides, thioindigos) and ring opening/closure (e.g., spiropyrans, dithienylethenes, fulgides, donor-acceptor Stenhouse adducts) have been developed and utilized as the core components of adaptive materials at various length scales. Representative applications of photoswitches involve photochromic materials, drug delivery, switchable receptors and channels, information or energy storage, and molecular machines5,6,7,8,9,10,11,12. In most studies presenting newly designed photoswitches, their photophysical properties such as λmax of absorption and emission, molar attenuation coefficient (ε), fluorescence lifetime, and photoisomerization quantum yield are characterized thoroughly. The investigation of such properties provides key information on the electronic states and transitions that are crucial for understanding the optical properties and isomerization mechanism.
However, accurate measurement of photoisomerization quantum yield-the number of photoisomerization events that occurred divided by the number of photons at the irradiation wavelength absorbed by the reactant-is often complicated in a typical laboratory setting due to several reasons. Determination of the photoisomerization quantum yield is generally achieved by monitoring the advancement of reaction and measuring the number of absorbed photons during irradiation. The primary concern is that the amount of photon absorption per unit time changes progressively because the total absorption by the solution changes over time as the photochemical reaction proceeds. Therefore, the number of consumed reactants per unit time depends on the time section in which it is measured during the irradiation. Thus, one is obliged to estimate the photoisomerization quantum yield that is defined differentially.
A more troublesome problem arises when both the reactant and photoproduct absorb light at the irradiation wavelength. In this case, the photochemical isomerization occurs in both directions (i.e., a photoreversible reaction). The two independent quantum yields for the forward and backward reactions cannot be obtained directly from the observed reaction rate. Inaccurate light intensity is also a common cause of error. For example, the aging of the bulb gradually changes its intensity; irradiance of the Xenon arc lamp at 400 nm decreases by 30% after 1000 h of operation14. The spreading of non-collimated light makes the actual incident irradiance significantly smaller than the nominal power of the source. Thus, it is crucial to accurately quantify the effective photon flux. Of note, thermal relaxation of the metastable form at room temperature should be sufficiently small to be ignored.
This paper introduces a set of procedures to determine the photoisomerization quantum yield of a bistable photoswitch. A number of hydrazone photoswitches developed by the group of Aprahamian, the pioneering research team in the field, have been in the spotlight thanks to their selective photoisomerization and remarkable stability of their metastable isomers15,16,17. Their hydrazone photoswitches comprise two aromatic rings joined by a hydrazone group, and the C=N bond undergoes selective E/Z isomerization upon irradiation at appropriate wavelengths (Figure 1). They have been successfully incorporated as the motile components of dynamic molecular systems18,19,20,21. In this work, we prepared a new hydrazone derivative bearing amide groups and investigated its photoswitching properties for the determination of the photoisomerization quantum yield.
1. 1H NMR spectrum acquisition at photostationary state (PSS)
2. UV-Vis absorption spectroscopy at PSS
3. Kinetic studies on thermal relaxation
4. Ferrioxalate actinometry
NOTE: All procedures for ferrioxalate actinometry must be performed in the dark or >600 nm light to prevent the influence of ambient light.
5. Determination of the photoisomerization quantum yield
Upon irradiation of 1 in an NMR tube with 436 nm light (Z:E = 54:46 in the initial state), the proportion of 1–E increases due to the dominant Z-to-E isomerization of the hydrazone C=N bond (Figure 1). The isomeric ratio can be readily obtained from the relative signal intensities of distinct isomers in the 1H NMR spectrum (Figure 2). After 5 days of irradiation at 436 nm, the sample reaches PSS containing 92% of 1–E. Prolonged irradiation is required to reach PSS due to the high sample concentration (10 mM) and weak intensity of the light source. Subsequent irradiation at 340 nm induces E-to-Z isomerization, reaching PSS containing 82% of 1–Z after 3 days of irradiation.
A shorter irradiation time is required to reach PSS in the UV-Vis spectroscopy experiment (10 h and 4 h for irradiation at 436 and 340 nm, respectively) due to the lower sample concentration (10 µM). As it is difficult to isolate the pure isomers by chromatography or obtain them by photoisomerization, UV-Vis absorption spectra of 1 in the PSSs are used to deduce the absorption spectra of the pure 1–Z and 1–E (Figure 4). The wavelength of the absorption maximum (λmax, 398 nm for 1–Z and 375 nm for 1–E) and molar attenuation coefficient (ε) can be obtained from the deduced spectra. UV-Vis spectra of the pure isomers suggest that the incomplete photoisomerization is attributed to the reverse photochemical process, i.e., absorption band overlap at the irradiation wavelengths.
For determining the photoisomerization quantum yield, the rate of thermal relaxation and the effective molar photon flux are first investigated. Because the metastable isomer 1–E is highly stable at room temperature, thermally driven E-to-Z isomerization is monitored at elevated temperatures (from 131 to 143 °C) using 1H NMR spectroscopy, and the first-order rate constants of relaxation are estimated (Figure 6). The obtained rate constants at different temperatures are then plotted versus reciprocal temperature and linearly fitted using the Arrhenius equation (Eq (4)) (Figure 7). The rate of thermal relaxation ((2.2 ± 0.5) × 10-10 s-1) and the half-life of 1–E (101 ± 24 years) at room temperature can then be extrapolated. Thus, it is safe to ignore the effect of thermal relaxation in the photoisomerization process at room temperature. One can also use the rearranged Eyring equation (Eq (6)) shown in step 3.11 to estimate the half-life if only one rate constant is available.
For the determination of the effective molar photon flux in the irradiation setup, the fraction of light absorbed by ferrioxalate solution (f) should be measured precisely (Figure 8). Although a 0.006 M ferrioxalate solution is used in this protocol, a 0.15 M solution is recommended if using >440 nm light for irradiation due to the low absorbance25. Once the f is measured, the ferrioxalate solution is subjected to the photoreduction experiment. Upon irradiation, the ferrioxalate is reduced to a ferrous ion (Fe2+) that is subsequently coordinated by three phenanthroline ligands to form the [Fe(phen)3]2+ complex. The degree of photoreduction can then be obtained by measuring the absorption of [Fe(phen)3]2+ complex (Figure 9). The effective molar photon flux can be calculated from the known molar attenuation coefficient of [Fe(phen)3]2+ complex and quantum yield of the photoreduction at the irradiation wavelength. The irradiation power of the light source used in this experiment is enough to calculate the molar photon flux without dilution of the irradiated sample. If the absorbance of the irradiated sample is higher than 1, the ferrioxalate sample should be diluted after irradiation.
Once the effective molar photon flux and molar attenuation coefficients of the pure isomers are obtained, it is now possible to determine the photoisomerization quantum yield. Photoisomerization of 1 is carried out using the same irradiation setup as the actinometry experiment and monitored by UV-Vis spectroscopy. As the photochemical isomerization is reversible at the irradiation wavelengths, individual quantum yields for the forward and backward reactions are entangled in the overall reaction rate and cannot be determined directly. It is thus necessary to first calculate the pseudo quantum yield (Q) at the irradiation wavelength from which the individual quantum yields are extracted afterward. The pseudo quantum yield is defined by Eq (14), which allows the expression of the two linear dependent steps with a linear independent Eq (15) (Supplemental Information).
(14)
(15)
By using Eq (15), the pseudo quantum yield can be obtained from the observed total absorbance and irradiation time at which it is measured (Eq. (15) in the Supplemental Information). F(t), the so-called photokinetic factor, is a time-dependent variable that cannot be integrated directly when both 1–Z and 1–E absorb light at the irradiation wavelength. When the irradiation interval between time t1 and t2 is short, the integration of F(t) from time t1 auf t2 is approximated to (t2 – t1) {F(t1) + F(t2)}/2 to give Eq (11) (step 5.7 and Eq. (27) in the Supplemental Information). The averaged values of the pseudo quantum yield calculated are 43.0 ± 4.6 M-1cm-1 at 436 nm and 405.6 ± 20.3 M-1cm-1 at 340 nm (Table 1).
(11)
The numerical relation between ΦZ→E and ΦE→Z is obtained based on the isomeric ratio at PSS (Eq. (23) in the Supplemental Information) and, finally, the individual quantum yields can be determined by using Eq (12) and Eq (13) (step 5.9).
(12)
(13)
The estimated unidirectional photoisomerization quantum yields are ΦZ→E = 1.3 ± 0.1%, ΦE→Z = 0.6 ± 0.1% under 436 nm irradiation and ΦZ→E = 2.0 ± 0.1%, ΦE→Z = 4.6 ± 0.2% under 340 nm irradiation.
Figure 1: E/Z isomerization of hydrazone switch 1 induced by light and heat. The two isomers 1–Z and 1–E interconvert by photoirradiation at different wavelengths. Metastable 1–E can thermally relax to 1–Z. Please click here to view a larger version of this figure.
Figure 2: 1H NMR spectra of 1 (A) before and after irradiation at (B) 436 nm or (C) 340 nm to reach PSSs in DMSO-d6 at 298.15 K. PSS compositions at 436 and 340 nm consist of 8 and 82% of 1–Z, respectively. Abbreviation: PSSs = photostationary states. Please click here to view a larger version of this figure.
Figure 3: An experimental setup for photoisomerization and ferrioxalate actinometry. The sample solution in a cuvette is placed 1 cm in front of the Xe arc lamp equipped with a bandpass filter. Abbreviation: d = distance. Please click here to view a larger version of this figure.
Figure 4: UV-Vis absorption spectra of 1 (1 × 10-5 M in DMSO). Blue and red solid lines indicate absorption spectra of 1 in PSSs under 436 and 340 nm irradiation, respectively. Blue and red dashed lines indicate deduced absorption spectra of pure 1–E and 1–Z, respectively. Abbreviation: PSSs = photostationary states. Please click here to view a larger version of this figure.
Figure 5: An experimental setup for monitoring the thermal relaxation process. A heating bath circulator is used to maintain the temperature constant during heating of the sample. Please click here to view a larger version of this figure.
Figure 6: Plot of the concentration of 1-E versus heating time in DMSO-d6 at different temperatures. The rate constants of thermal relaxation at different temperatures are obtained from the plots. Please click here to view a larger version of this figure.
Figure 7: Arrhenius plot of the thermal E-to-Z isomerization of 1 in DMSO-d6. Extrapolation of the linear fit suggests that the thermal half-life of 1–E at room temperature is 101 ± 24 years. Abbreviations: k = the rate constant of thermal relaxation; T = temperature. Please click here to view a larger version of this figure.
Figure 8: The fraction of absorbed light by 0.006 M ferrioxalate in 0.05 M aqueous H2SO4 solution. The measured fractions of absorbed light at the photoirradiation wavelengths are used in the ferrioxalate actinometry. Abbreviation: f = fraction of light absorbed. Please click here to view a larger version of this figure.
Figure 9: Absorbance differences between the irradiated (blue line: irradiated at 436 nm, red line: irradiated at 340 nm) and non-irradiated ferrioxalate samples. The absorbance difference at 510 nm (ΔA510) and the known value of molar attenuation coefficient of [Fe(phen)3]2+ complex (ε510 = 11100 M-1cm-1) are used to calculate the molar photon flux. Please click here to view a larger version of this figure.
Figure 10: Monitored UV-Vis spectra upon irradiation. Irradiation with (A) 436 nm and (B) 340 nm irradiation. Plots of the absorbance at 398 nm (λmax of the pure 1-Z) during irradiation at (C) 436 nm and (D) 340 nm versus time. Averaged values of the pseudo quantum yield are obtained using the first ten data points in C and D. Please click here to view a larger version of this figure.
Table 1: Estimated pseudo quantum yields and unidirectional photoisomerization quantum yields under the irradiation wavelengths. Please click here to download this Table.
Supplemental Information: A user guide to choose an appropriate procedure for determining the photoisomerization quantum yield of a bistable switch and characterization of compound 1. Please click here to download this File.
Various strategies to tune the spectral and switching properties of photoswitches have been developed, and the register of photoswitches is rapidly expanding28. It is thus crucial to correctly determine their photophysical properties, and we anticipate the methods summarized in this article will be a helpful guide to experimenters. Provided that the thermal relaxation rate is very slow at room temperature, measurement of PSS compositions at different irradiation wavelengths, molar attenuation coefficients of the pure isomers, effective molar photon flux, sand pseudo quantum yield allows the estimation of the unidirectional photoisomerization quantum yields. Experimental outcomes presented in this work revealed that photophysical properties of 1 are not significantly different from that of the unsubstituted parent molecule15. This result suggests that the amide linkage can be a useful tether to other molecules of interest for their structural modulation.
For the determination of the quantum yield, it is essential to use a proper integration method for the photokinetic factor (see Supplemental Information). Critical factors for choosing the integration method are: (1) whether both the isomers absorb light at the irradiation wavelength (photoreversibility)26, (2) whether the photoirradiation started with a pure isomer29,30, and (3) whether the absorption at the irradiation wavelength is much smaller than 0.1 or bigger than 227. In this work, photochemical isomerization of 1 is reversible at the irradiation wavelengths, and its photoswitching experiments start with isomeric mixtures. Absorption at the irradiation wavelengths is not sufficiently small (0.02366 at 436 nm and 0.06638 at 340 nm) to make an approximation of the photokinetic factor. In this case, integration of the photokinetic factor for a short irradiation interval is approximated by linear interpolation (case 2 in Supplemental Information). For those trying to determine the photoisomerization quantum yield of bistable photoswitches, the derivation of relevant equations in different circumstances is presented in Supplemental Information.
Of note is that the methods described in this article cannot be used for photoswitches with non-uniform photochemical processes (e.g., formation of a long-lived intermediate or multiple photoproducts) or with fast thermal relaxation processes31. Photochemical isomerization of 1 is a uniform process and does not have to take into account the thermal relaxation owing to its bistability. To precisely determine the PSS composition and the rate of thermal process of photoswitches with fast thermal relaxation, a special experimental setup for in situ irradiation during spectroscopic analysis is required (e.g., a UV-Vis spectrophotometer equipped with an additional light source for perpendicular irradiation, optical fiber that can be inserted into the NMR sample)32. It is also important to use a light source with a narrow bandwidth by using a bandpass filter or a laser for uniform energy excitation.
The authors have nothing to disclose.
This work was supported by the Chung-Ang University Research Grants in 2019 and the National Research Foundation of Korea (NRF-2020R1C1C1011134).
1,10-phenanthroline | Sigma-Aldrich | 131377-2.5G | |
340 nm bandpass filter, 25 mm diameter, 10 nm FWHM | Edmund Optics | #65-129 | |
436 nm bandpass filter, 25 mm diameter, 10 nm FWHM | Edmund Optics | #65-138 | |
Anhydrous sodium acetate | Alfa aesar | A13184.30 | |
Dimethyl sulfoxide | Samchun | D1138 | HPLC grade |
Dimethyl sulfoxide-d6 | Sigma-Aldrich | 151874-25g | |
Gemini 2000; 300 MHz NMR spectrometer | Varian | ||
H2SO4 | Duksan | 235 | |
Heating bath | JeioTech | CW-05G | |
MestReNova 14.1.1 | Mestrelab Research S.L., https://mestrelab.com/ | ||
Natural quartz NMR tube | Norell | S-5-200-QTZ-7 | |
Potassium ferrioxalate trihydrate | Alfa aesar | 31124.06 | |
Quartz absorption cell | Hellma | HE.110.QS10 | |
UV-VIS spectrophotometer | Scinco | S-3100 | |
Xenon arc lamp | Thorlabs | SLS205 | Fiber adapter was removed |