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Article

Phosphorescence and Photophysical Parameters of Porphycene in Cryogenic Matrices

1
Institute of Physical Chemistry, Polish Academy of Sciences, Kasprzaka 44/52, 01-224 Warsaw, Poland
2
Faculty of Mathematics and Science, Cardinal Stefan Wyszyński University, Dewajtis 5, 01-815 Warsaw, Poland
*
Author to whom correspondence should be addressed.
Photochem 2022, 2(1), 217-224; https://doi.org/10.3390/photochem2010016
Submission received: 22 February 2022 / Revised: 3 March 2022 / Accepted: 7 March 2022 / Published: 9 March 2022

Abstract

:
Matrix isolation studies were carried out for porphycene, an isomer of porphyrin, embedded in solid nitrogen and xenon. The external heavy atom effect resulted in nearly a 100% population of the triplet state and in the appearance of phosphorescence, with the origin located at 10163 cm−1. This energy is much lower than that corresponding to the T1 position in porphyrin. This difference could be explained by postulating that the orbital origin corresponds in both isomers to the second excited singlet state, which lies much closer to S1 in porphycene. Most of the vibrational frequencies observed in the phosphorescence spectrum correspond to totally symmetric modes, but several ones were assigned to the out-of-plane Bg vibrations. These bands are not observed in fluorescence, which suggests their possible role in vibronic-spin-orbit coupling.

1. Introduction

The detailed characterization of the photophysical characteristics of a chromophore is a prerequisite for successful applications. In particular, the properties of the triplet state, such as its energy, yield of formation via intersystem crossing from the singlet state, lifetime, and the ability to generate singlet oxygen, are crucial when designing new materials, e.g., photosensitizers, photovoltaic cells, or light emitting diodes. Moreover, the triplet state parameters often determine the photostability of a molecule, since photodegradation usually involves the triplet state. It is therefore not surprising that large databases containing triplet state data are available for many popular chromophores [1]. One of them is porphyrin, justly called “pigment of life” [2]. In most porphyrins, the yield of S1-T1 intersystem crossing is high, exceeding 70–80%. The S1-T1 energy separation is about 3500 cm−1. Investigations of parent, unsubstituted porphyrin in xenon matrices yielded values of 3683 and 3687 cm−1, determined from the difference between the origins of absorption [3] and phosphorescence [4] of the two main sites observed in this environment. The triplet lifetimes in argon and xenon, 2.6 and 0.63 ms, respectively [4], are not much different, but the radiative constant of the triplet depopulation dramatically increases in the heavy atom matrix, which allows for the registration of vibronically resolved phosphorescence in the not so readily accessible spectral region of 8000–13,000 cm−1.
Porphycene (Pc)—a structural isomer of porphyrin (Pr) (Scheme 1)—has gained much attention as a model for understanding single and double hydrogen transfer in the ground and electronically excited states [5] and as a promising agent for photodynamic therapy of cancer [6] and photoinactivation of bacteria [7]. Spectral and photophysical data for parent, unsubstituted porphycene and its derivatives are quite rich regarding the singlet state properties, but much less is known about the triplet characteristics. The triplet formation efficiency is lower than in porphyrin [5,8]. Moreover, it can be reduced practically to zero by multiple substitutions at the meso positions [9]. The triplet lifetimes, measured in solution [10,11] or lipid vesicles [12], are of the order of tens of microseconds. The triplet energies are considerably lower than in porphyrin (ca. 10,000 vs. 12,500 cm−1). They were determined for several porphycenes from the emission studies in the near IR region, carried out at room temperature in degassed iodopropane solutions [13]; no spectra have been presented. For the parent porphycene, Nonell et al. reported the phosphorescence by comparing the emission in degassed and aerated bromobenzene solutions at room temperature [14]. The spectrum consisted of two broad bands, centered around 1000 and 1150 nm.
To the best of our knowledge, no vibrationally resolved phosphorescence spectra of porphycenes have been published so far. The goal of our work was to obtain such a spectrum by placing the chromophore in a rare gas matrix. Based on previous observations, xenon was used, in order to enhance the triplet formation yield and, possibly, to increase the radiative constant of T1 depopulation. Next, in order to quantitatively study the external heavy atom effect, we measured the spectra in solid nitrogen. Triplet and singlet lifetimes as well as triplet formation efficiencies were compared for both matrices. Finally, we also performed quantum chemical calculations for porphyrin and porphycene, in order to understand the differences in singlet-triplet energy gaps and to assign the orbital origin of the triplet state.

2. Materials and Methods

Porphycene was synthesized and purified as described previously [15].
Nitrogen and xenon matrices were prepared on a sapphire deposition window attached to the cold finger of a closed-cycle helium cryostat (Displex 202, Advance Research Systems). Porphycene was sublimed into the rare gas by heating up to 390 K. The deposition window was kept at 10 K and 57 K during the deposition of nitrogen and xenon matrices, respectively.
Phosphorescence was measured with a home-made spectrometer based on a BENTHAM DTMc300 double monochromator equipped with a TE cooled photomultiplier (Hamamatsu H10330C-75, 950–1700 nm registration range). Two different laser sources have been used for excitation: (i) a Powerchip 355 nm Laser (Teem Photonics) and (ii) a CW ring laser (Coherent 899), pumped by an argon laser (Coherent Innova 300).
Steady state fluorescence spectra and fluorescence decays were obtained using an Edinburgh FS 900 CDT / FL 900 CDT fluorometer (Edinburgh Analytical Instruments). A NanoLED diode (297 nm, 1 MHz repetition rate) was used for time-resolved measurements.
Absorption spectra were recorded using a Shimadzu UV2700 spectrophotometer.
Calculations were performed using the density functional theory (DFT) and its time-dependent variant (TD DFT), as implemented in the Amsterdam Modeling Suite (version 2021.10-4) [16]. BP86-D functional [17,18] and TZP basis set were used in these simulations.

3. Results and Discussion

Figure 1 shows the absorption spectra of Pc obtained for nitrogen and xenon matrices. The absorption of matrix-isolated Pc has been studied in detail before [19,20,21,22]. The presently obtained spectra are similar to the reported ones. The linewidths are somewhat narrower than in the previously published works, which enables a better resolution of a characteristic multiple-site structure observed in nitrogen. In contrast, only one dominant site, exhibiting a larger bandwidth, is observed for the xenon environment. Transitions to both S1 and S2 are red-shifted in xenon, by 180 and 230 cm−1, respectively. This leads to the S1-S2 energy separation of 887 cm−1 in nitrogen and 837 cm−1 in xenon. The S1-S2 energy gap is thus significantly—nearly four times—smaller than in porphyrin, for which the reported values are about 3270 cm−1 (in argon) and 3100 cm−1 (in xenon).
Fluorescence spectra are shown in Figure 2. This experiment was performed with a broad excitation and low spectral resolution, so that the site structure is no longer observed. The purpose was to compare the intensities in both cases. The emission was much stronger in nitrogen. The relative quantum yields were estimated from the fluorescence decay times measured for both samples. Such a procedure assumes similar values of radiative decay constants in different environments, which has been demonstrated for porphycene [23]. The lifetime of fluorescence (τF) in the nitrogen matrix, 21 ns, was 60 times longer than that measured for the xenon environment (Table 1). The fluorescence lifetimes of Pc measured in room temperature solutions are about 10 ns, whereas the quantum yields vary, depending on the solvent, between 0.39 and 0.50 [23]. This would suggest a rather low triplet formation efficiency in nitrogen. The experimentally obtained value is 0.36. On the other hand, the value obtained for the sample in xenon is practically 1, as could have been expected based on the dramatic shortening of the S1 lifetime caused by the external heavy atom effect.
The triplet decays reveal the opposite behavior (Table 1). The ratio of T1 lifetimes (τT), (2000 μs (N2))/(45 μs (Xe)) is not much different from what is observed for the changes in the T1 ← S1 intersystem crossing rates. Interestingly, while the T1 lifetimes are very similar for Pr in argon and Pc in nitrogen, in xenon it is the Pc triplet that decays much faster. A possible explanation is the larger value of the radiative constant of triplet depopulation in Pc. One should remember that the transition to the S1 state is much weaker in Pr than in Pc.
While the phosphorescence was extremely weak in nitrogen-isolated Pc, it could be readily obtained in xenon matrices (Figure 3). The electronic ground state vibrational frequencies extracted from the phosphorescence spectrum are presented in Table 2. The same table also contains the frequencies previously obtained from the fluorescence of Pc in xenon. Because of the better spectral resolution in the present case, we could observe and assign additional lines, such as combinations of low frequency modes with the strong transition observed at 1554 cm−1 (29 Ag). The assignments in Table 2 are based on our previous work that included frequencies obtained from IR, Raman, fluorescence, and inelastic neutron scattering data combined with quantum chemical calculations and isotopic substitution [24].
Most of the features present in the phosphorescence have their counterparts in the fluorescence spectrum. However, in contrast to fluorescence, which reveals only totally symmetric (Ag) modes, several bands in phosphorescence are assigned to out-of-plane Bg vibrations. This indicates a possible contribution of the vibronic-spin-orbit coupling mechanism [25] to the phosphorescence intensity.
Using the luminescence data available for both chromophores, we are now ready to compare the pattern of low-lying electronic states in Pc and Pr. The most conspicuous difference is the S1-T1 energy gap. While the origins of the S0-S1 transitions differ by less than 500 cm−1 (16,270 cm−1 in Pr vs. 15,821 cm−1 in Pc), the T1 state in Pc is located at an energy that is lower by nearly 2500 cm−1 with respect to Pr (10,134 vs. 12,588 cm−1). An opposite behavior is found for the relative positions of S1 and S2 in the two chromophores. The energy difference between the transitions to S1 (Qx) and S2 (Qy) in a xenon matrix exceeds 3100 cm−1 in porphyrin [4], whereas in porphycene it amounts to only 838 cm−1 [19].
We postulate that the lowering of the S2 energy upon going from Pr to Pc is responsible for the large stabilization of the lowest triplet state in the latter. Calculations suggest that, in both molecules, the lowest triplet state is well described by the same electronic configuration, involving the HOMO–LUMO electron jump (Table 3). Such a configuration is dominant, for both Pr and Pc, in the S0-S2 transition, but not in S0-S1. This implies a larger singlet-triplet splitting for S2. Assuming a similar value of the singlet-triplet splitting in both chromophores, one would expect a difference in the T1 location corresponding to the difference in S2 energies. This is indeed observed experimentally: the T1 energies differ by ca. 2500 cm−1, the energies of S2 by ca. 2700 cm−1.
The calculations accurately predict the difference in the triplet energies of Pr and Pc, (2200 cm−1 vs. 2500 cm−1 obtained in the experiment). They also correctly reproduce the lower energy of S1 in Pc (300 cm−1 vs. the observed value of 450 cm−1). The S1-S2 separation is well reproduced for Pc, but for the S2 state both the energy and the oscillator strength (relative to those of S1) are predicted rather poorly.

4. Summary

Electronic spectroscopy studies of porphycene embedded in xenon matrices enabled an accurate determination of the location of the lowest triplet state. The vibronically resolved phosphorescence was recorded, exhibiting, in contrast to fluorescence, not only totally symmetric modes. The triplet location in porphycene is significantly red-shifted compared to porphyrin. This was explained by assigning the T1 orbital origin to that of S2, a state which is strongly stabilized with respect to S1 upon passing from Pr to Pc.
In view of the crucial role the triplet state plays in various photophysical, photochemical, and photochemical processes, more detailed studies seem worthwhile, focusing on such issues as, e.g., substituent effects that could lead to the inversion of the two lowest lying triplet states in porphyrin and its isomers. Several relatively old papers suggest for Pr that the T1 and T2 states lie very close to each other and that their ordering may depend on the environment [4,26,27,28,29]. The same may be true for porphycene, as suggested by the calculated T1-T2 energy gap, which is even smaller than in porphyrin (Table 3).

Author Contributions

Conceptualization, J.W.; software, J.W.; formal analysis, B.G., A.G. and J.W.; investigation, B.G. and A.G.; writing—original draft preparation, J.W. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Polish National Science Centre, grant numbers 2016/22/A/ST4/00029 and 2020/39/B/ST4/01956.

Data Availability Statement

Data is contained within the article.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Montalti, M.; Credi, A.; Prodi, L.; Gandolfi, M.T. Handbook of Photochemistry, 3rd ed.; Montalti, M., Credi, A., Prodi, L., Gandolfi, M.T., Eds.; Taylor & Francis Group: Abingdon, UK, 2006. [Google Scholar]
  2. Battersby, A.R. Tetrapyrroles: The Pigments of Life. Nat. Prod. Rep. 2000, 17, 507–526. [Google Scholar] [CrossRef] [PubMed]
  3. Radziszewski, J.; Waluk, J.; Michl, J. FT Visible Absorption Spectroscopy of Porphine in Noble Gas Matrices. J. Mol. Spectrosc. 1990, 140, 373–389. [Google Scholar] [CrossRef]
  4. Radziszewski, J.G.; Waluk, J.; Nepraš, M.; Michl, J. Fourier Transform Fluorescence and Phosphorescence of Porphine in Rare Gas Matrices. J. Phys. Chem. 1991, 95, 1963–1969. [Google Scholar] [CrossRef]
  5. Waluk, J. Spectroscopy and Tautomerization Studies of Porphycenes. Chem. Rev. 2017, 117, 2447–2480. [Google Scholar] [CrossRef] [PubMed]
  6. Stockert, J.C.; Cañete, M.; Juarranz, A.; Villanueva, A.; Horobin, R.W.; Borrell, J.; Teixidó, J.; Nonell, S. Porphycenes: Facts and Prospects in Photodynamic Therapy of Cancer. Curr. Med. Chem. 2007, 14, 997–1026. [Google Scholar] [CrossRef]
  7. Polo, L.; Segalla, A.; Bertoloni, G.; Jori, G.; Schaffner, K.; Reddi, E. Polylysine-Porphycene Conjugates as Efficient Photosensitizers for the Inactivation of Microbial Pathogens. J. Photochem. Photobiol. B Biol. 2000, 59, 152–158. [Google Scholar] [CrossRef]
  8. Planas, O.; Gallavardin, T.; Nonell, S. Unusual Properties of Asymmetric Porphycenes. In Handbook of Porphyrin Science; Kadish, K.M., Smith, K.M., Guilard, R., Eds.; World Scientific: Singapore, 2016; Volume 41, pp. 299–349. [Google Scholar]
  9. Gil, M.; Dobkowski, J.; Wiosna-Sałyga, G.; Urbańska, N.; Fita, P.; Radzewicz, C.; Pietraszkiewicz, M.; Borowicz, P.; Marks, D.; Glasbeek, M.; et al. Unusual, Solvent Viscosity-Controlled Tautomerism and Photophysics: Meso-Alkylated Porphycenes. J. Am. Chem. Soc. 2010, 132, 13472–13485. [Google Scholar] [CrossRef]
  10. Aramendia, P.F.; Redmond, R.W.; Nonell, S.; Schuster, W.; Braslavsky, S.E.; Schaffner, K.; Vogel, E. The Photophysical Properties of Porphycenes: Potential Photodynamic Therapy Agents. Photochem. Photobiol. 1986, 44, 555–559. [Google Scholar] [CrossRef]
  11. Levanon, H.; Toporowicz, M.; Ofir, H.; Fessenden, R.W.; Das, P.K.; Vogel, E.; Köcher, M.; Pramod, K. Triplet-State Formation of Porphycenes—Intersystem Crossing Versus Sensitization Mechanisms. J. Phys. Chem. 1988, 92, 2429–2433. [Google Scholar] [CrossRef]
  12. Redmond, R.W.; Valduga, G.; Nonell, S.; Braslavsky, S.E.; Schaffner, K.; Vogel, E.; Pramod, K.; Köcher, M. The Photophysical Properties of Porphycene Incorporated in Small Unilamellar Lipid Vesicles. J. Photochem. Photobiol. B Biol. 1989, 3, 193–207. [Google Scholar] [CrossRef]
  13. Braslavsky, S.E.; Müller, M.; Mártire, D.O.; Pörting, S.; Bertolotti, S.G.; Chakravorti, S.; Koç-Weier, G.; Knipp, B.; Schaffner, K. Photophysical Properties of Porphycene Derivatives (18 π Porphyrinoids). J. Photochem. Photobiol. B Biol. 1997, 40, 191–198. [Google Scholar] [CrossRef]
  14. Nonell, S.; Aramendía, P.F.; Heihoff, K.; Negri, R.M.; Braslavsky, S.E. Laser-Induced Optoacoustics Combined with near-Infrared Emission. An Alternative Approach for the Determination of Intersystem Crossing Quantum Yields Applied to Porphycenes. J. Phys. Chem. 1990, 94, 5879–5883. [Google Scholar] [CrossRef]
  15. Urbańska, N.; Pietraszkiewicz, M.; Waluk, J. Efficient Synthesis of Porphycene. J. Porphyr. Phthalocyanines 2007, 11, 596–600. [Google Scholar] [CrossRef]
  16. te Velde, G.; Bickelhaupt, F.M.; Baerends, E.J.; Fonseca Guerra, C.; van Gisbergen, S.J.A.; Snijders, J.G.; Ziegler, T. Chemistry with ADF. J. Comput. Chem. 2001, 22, 931–967. [Google Scholar] [CrossRef]
  17. Becke, A.D. Density-Functional Exchange-Energy Approximation with Correct Asymptotic Behavior. Phys. Rev. A 1988, 38, 3098–3100. [Google Scholar] [CrossRef]
  18. Perdew, J.P. Density-Functional Approximation for the Correlation Energy of the Inhomogeneous Electron Gas. Phys. Rev. B 1986, 33, 8822–8824, Erratum: Density-Functional Approximation for the Correlation Energy of the Inhomogeneous Electron Gas. Phys. Rev. B 1986, 34, 7406–7406. [Google Scholar] [CrossRef]
  19. Starukhin, A.; Vogel, E.; Waluk, J. Electronic Spectra in Porphycenes in Rare Gas and Nitrogen Matrices. J. Phys. Chem. A 1998, 102, 9999–10006. [Google Scholar] [CrossRef]
  20. Kyrychenko, A.; Waluk, J. Molecular Dynamics Simulations of Matrix Deposition. Iii. Site Structure Analysis for Porphycene in Argon and Xenon. J. Chem. Phys. 2005, 123, 064706. [Google Scholar] [CrossRef]
  21. Kyrychenko, A.; Gawinkowski, S.; Urbańska, N.; Pietraszkiewicz, M.; Waluk, J. Matrix Isolation Spectroscopy and Molecular Dynamics Simulations for 2,7,12,17-Tetra-Tert-Butylporphycene in Argon and Xenon. J. Chem. Phys. 2007, 127, 134501. [Google Scholar] [CrossRef]
  22. Gil, M.; Gorski, A.; Starukhin, A.; Waluk, J. Fluorescence Studies of Porphycene in Various Cryogenic Environments. Low Temp. Phys. 2019, 45, 656–662. [Google Scholar] [CrossRef]
  23. Kijak, M.; Nawara, K.; Listkowski, A.; Masiera, N.; Buczyńska, J.; Urbańska, N.; Orzanowska, G.; Pietraszkiewicz, M.; Waluk, J. 2+2 Can Make Nearly a Thousand! Comparison of Di- and Tetra-Meso-Alkyl-Substituted Porphycenes. J. Phys. Chem. A 2020, 124, 4594–4604. [Google Scholar] [CrossRef] [PubMed]
  24. Gawinkowski, S.; Walewski, Ł.; Vdovin, A.; Slenczka, A.; Rols, S.; Johnson, M.R.; Lesyng, B.; Waluk, J. Vibrations and Hydrogen Bonding in Porphycene. Phys. Chem. Chem. Phys. 2012, 14, 5489–5503. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  25. Penfold, T.J.; Gindensperger, E.; Daniel, C.; Marian, C.M. Spin-Vibronic Mechanism for Intersystem Crossing. Chem. Rev. 2018, 118, 6975–7025. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  26. van Dorp, W.G.; Soma, M.; Kooter, J.A.; van der Waals, J.H. Electron Spin Resonance in the Photo-Excited Triplet State of Free Base Porphin in a Single Crystal of n-Octane. Mol. Phys. 1974, 28, 1551–1568. [Google Scholar] [CrossRef]
  27. Weiss, C.; Kobayashi, H.; Gouterman, M. Spectra of Porphyrins. Part III. Self-Consistent Molecular Orbital Calculations of Porphyrin and Related Ring Systems. J. Mol. Spectrosc. 1965, 16, 415–450. [Google Scholar] [CrossRef]
  28. Knop, J.V.; Knop, A. Quantenchemische Und Spektroskopische Untersuchungen an Porphyrinen. I. Freie Base Porphin Und Metallo-Porphin. Z. Für Naturforsch. 1970, 25, 1720–1725. [Google Scholar] [CrossRef]
  29. Sundbom, M. Semi-Empirical Molecular Orbital Studies of Neutral Porphin, PH2, the Dianion P2- and the Dication PH42+. Acta Chem. Scand. 1968, 22, 1317–1326. [Google Scholar] [CrossRef]
Scheme 1. (Left), porphyrin (porphine); (right), porphycene.
Scheme 1. (Left), porphyrin (porphine); (right), porphycene.
Photochem 02 00016 sch001
Figure 1. Absorption of Pc in (a) nitrogen and (b) xenon matrices. T = 10 K. The arrows mark the origin of the S0-S2 electronic transition.
Figure 1. Absorption of Pc in (a) nitrogen and (b) xenon matrices. T = 10 K. The arrows mark the origin of the S0-S2 electronic transition.
Photochem 02 00016 g001
Figure 2. Fluorescence of Pc in (a) nitrogen and (b) xenon matrices. T = 10 K. Excitation wavelengths: (a) 370 nm and (b) 560 nm.
Figure 2. Fluorescence of Pc in (a) nitrogen and (b) xenon matrices. T = 10 K. Excitation wavelengths: (a) 370 nm and (b) 560 nm.
Photochem 02 00016 g002
Figure 3. Phosphorescence of Pc in xenon matrices measured at three different spectral resolutions. T = 10 K. Excitation wavelength: 631.6 nm, corresponding to the location of the main site (see Figure 1b).
Figure 3. Phosphorescence of Pc in xenon matrices measured at three different spectral resolutions. T = 10 K. Excitation wavelength: 631.6 nm, corresponding to the location of the main site (see Figure 1b).
Photochem 02 00016 g003
Table 1. Photophysical parameters of Pc in N2 and Xe matrices.
Table 1. Photophysical parameters of Pc in N2 and Xe matrices.
τF, ns τT, μs ΦT
N2 21 ± 2 2000 ± 400.36 ± 0.04
Xe 0.35 ± 0.1 45 ± 0.51 ± 0.05
Table 2. Vibrational frequencies (in cm−1) observed in phosphorescence in xenon, compared with the previously reported data [19] obtained from fluorescence in the same matrix.
Table 2. Vibrational frequencies (in cm−1) observed in phosphorescence in xenon, compared with the previously reported data [19] obtained from fluorescence in the same matrix.
PhosphorescenceFluorescenceAssignment a
1791842 Ag
3403363 Ag
3683584 Ag
5115102 Ag + 3 Ag
5415382 Ag + 4 Ag
621 7 Bg
6606657 Ag
6862 × 3 Ag
696 9 Bg
7033 Ag + 4 Ag
7232 × 4 Ag
847 1 Ag + 7 Bg
8639 Ag
881 14 Bg
95996110 Ag
10103 × 3 Ag
1056 14 Ag
10793 × 4 Ag
1192120317 Ag
1253126519 Ag
1322 20 Ag
135421 Ag
1392139523 Ag
1426 25 Ag
1458 26 Ag
1486149727 Ag
1554156229 Ag
1585
161430 Ag
1730 2 Ag + 29 Ag
1891 3 Ag + 29 Ag
1918 4 Ag + 29 Ag
2215 7 Ag + 29 Ag
a based on ref. [24].
Table 3. Calculated transition energies.
Table 3. Calculated transition energies.
S1S2T1T2
Pc17,191 a 18,226 11,89812,449
(0.0927) b(0.1549)
54.4.% sH-L c56.3% H-LH-LsH-L
26% H-L25.0% sH-L
Pr17,505 (0.0007)18,563 (0.0004)14,08714,870
61.5% H-sL57.3% H-L
37.5% sH-L41.4% sH-sLH-LH-sL
a cm−1; b oscillator strength in parentheses; c dominant configurations; H, sH: highest and second highest occupied molecular orbital; L, sL: lowest and second lowest unoccupied molecular orbital.
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Golec, B.; Gorski, A.; Waluk, J. Phosphorescence and Photophysical Parameters of Porphycene in Cryogenic Matrices. Photochem 2022, 2, 217-224. https://doi.org/10.3390/photochem2010016

AMA Style

Golec B, Gorski A, Waluk J. Phosphorescence and Photophysical Parameters of Porphycene in Cryogenic Matrices. Photochem. 2022; 2(1):217-224. https://doi.org/10.3390/photochem2010016

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Golec, Barbara, Aleksander Gorski, and Jacek Waluk. 2022. "Phosphorescence and Photophysical Parameters of Porphycene in Cryogenic Matrices" Photochem 2, no. 1: 217-224. https://doi.org/10.3390/photochem2010016

APA Style

Golec, B., Gorski, A., & Waluk, J. (2022). Phosphorescence and Photophysical Parameters of Porphycene in Cryogenic Matrices. Photochem, 2(1), 217-224. https://doi.org/10.3390/photochem2010016

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