Abstract

INTRODUCTION

Perylene diimide derivatives (PDIs) are promising and versatile electron-poor conjugated aromatic candidates for organic photo-electronic applications such as transistors, solar cells due to their commercial availability, low cost, and significant performance.¹1 Nazari, M.; Cieplechowicz, E.; Welsha, T. A.; Welch, G. C.; New J. Chem. 2019, 43, 5187.^,22 Chueh, C. H. C. C.; Xi, X. X.; Zhong, H. L.; Gao, G. P.; Wang, Z. H.; Pozzo, L. D.; Wen, T. C.; Jen, A. K. Y.; Adv. Fun. Mater. 2015, 25, 5326. The success of PDIs in these applications is fundamentally attributed to the high electron affinity and the ease of reduction into rather stable and delocalized radical anions that are the common features of electron-deficient aromatic diimides.³3 Weng, K. K.; Li, C., Bi, P. Q.; Ryu, H. S.; Guo, Y. K.; Hao, X. T.; Zhao, D. H.; Li, W. W.; Woo, H. Y.; Sun, Y. M.; J. Mater. Chem., A 2019, 7, 3552.^,44 Gregg, B. A.; Cormier, R. A.; J. Am. Chem. Soc. 2001, 123, 7959. PDIs radical anions is getting more and more attentions due to their applications in sensor, photo thermal conversion and reduction of aryl halides etc.⁵5 Wang, J. M.; He, E. F.; Liu, X. Q.; Yu, L.; Wang, H. L.; Zhang, R. J.; Zhang, H. Q.; Sens. Actuators, B 2017, 239, 898.

6 Jiao, Y.; Liu, K.; Wang, G.; Wang, P. Y.; Zhang, X.; Chem. Sci. 2015, 6, 3975.^-77 Ghosh, I.; Ghosh, T.; Bardagi, J. I.; König, B.; Science 2014, 346, 725. The reduction of electrochemistry and the chemical reductant (Na₂S, Na₂S₂O₄, NH₂NH₂, etc ) are the typical method to prepare perylene diimide radical anion.⁸8 Zhong, L.; Xing, F. F.; Shi, W.; Yan, L. M.; Xie, L. Q.; Zhu, S. R.; ACS Appl. Mater. Interfaces 2013, 5, 3401.

9 Shirman, E.; Ustinov, A.; Ben-Shitrit, N.; Weissman, H.; Iron, M. A.; Cohen, R.; Rybtchinski, B.; J. Phys. Chem. B 2008, 112, 8855.^-1010 Wang, J. M.; He, E. F.; Wang, H. L.; Hou, W. L.;Xu, J.; Guo, H. Y.; Wang, X.; Zhang, Z. L.; Zhang, R. J.; Zhang, H. Q.; RSC Adv. 2016, 6, 68402. It is well know that the perylene diimide radical anion as an independent species in the air was not obtained by electrochemistry method due to the reducibility of radical anion.¹¹11 Gosztola, D.; Niemczyk, M. P.; Svec, W.; Lukas, A. S.; Wasielewski, M. R.; J. Phys. Chem. A 2000, 104, 6545. The stable perylene diimide anion in deoxygenated aqueous solution has been developed by the reduction of the chemical reductants in recent year. For example, Rybtchinski and co-workers reported that a core-unsubstituted PDI containing polyethylene glycol chains at the imide positions can be reduced with sodium dithionite (Na₂S₂O₄) in water to its dianion, this species was stable for months in deoxygenated aqueous solution owing to the delocalized aromatic character.¹⁰10 Wang, J. M.; He, E. F.; Wang, H. L.; Hou, W. L.;Xu, J.; Guo, H. Y.; Wang, X.; Zhang, Z. L.; Zhang, R. J.; Zhang, H. Q.; RSC Adv. 2016, 6, 68402. Furthermore, Brochsztain et al. investigated the aggregation behavior of a PDIs dianion generated by Na₂S₂O₄ titration in water-ethanol mixtures.¹²12 Marcon, R. O.; Brochsztain, S.; Langmuir, 2007, 23, 11972. Michael R. W first reported radical anions of the trifluoromethylated perylene diimide with cobaltocene as reducing agent in DMF.¹³13 Roznyatovskiy, V. V.; Gardner, D. M.; Eaton, S.W.; Wasielewski, M. R.; Org. Lett. 2014, 16, 696. Unfortunately, those perylene diimide anions are unstable in the air. Würthner, F. and co-workers reported the first example of an isolable, ambient stable perylene diimide (PDI) dianion by catalytic reduction (Pd/C, H₂) for a highly electron-deficient PDI derivative.¹⁴14 Seifert, S.; Schmidt, D.; Würthner, F.; Chem. Sci. 2015, 6, 1663. However, their methods tend to require the severe preparation conditions (such as: composite catalytic system (Pd/C-H₂), nitrogen atmosphere, etc.) and complex molecular structure, which limits the application of perylene diimide anion. Recently, the preparation method of perylene diimide radical anion salt has been obtained by alkali treatment in DMF and air atmosphere in our research group.¹⁵15 He, E. F.; Wang, J. M.; Xu, H.; He, Z. M.; Wang, H. L.; Zhao, H.; Zhang, Y. Y.; Zhang, R. J.; Zhang, H. Q.; J. Mater. Sci. 2016, 14, 6583. The structure characterization, the effect of solvent on synthetic reaction, and the sensitive to oxidants-acid H⁺ and oxidization metal ions for N,N’-diethylhexyl-1,7-di(pentafluoro-phenoxyl) perylene diimide radical anion have been widely discussed in our study. However, understanding the effects of bay-substituents on synthesis process of perylene diimide radical anion salt, and the difference of response to Cu ²⁺, Hg ²⁺ ion has always been a challenging topic.

In this paper, we reported the synthesis process and properties of two PDIs radical anion salt with electron-withdrawing groups and electron-donating groups ( Synthetic route and structure see Scheme 1).

Scheme 1
Synthetic route and structure of PDIs radical anion salt

EXPERIMENTAL

Material

Materials: All reactions were carried out under an argon atmosphere. All reagents from commercial sources were used without further purification unless otherwise stated. Dimethyl Formamide (DMF) was fractionally distilled under reduced pressure.

Characterization

Infrared measurement with the KBr pellet technique was performed within the 400-4000 cm^-1 on a Perkin Elemer SP100 Fourier transform infrared spectrometer. UV-Vis spectra were measured by Perkin Elemer Lambda 35. Cyclic voltammetry measurements were performed in solution, under argon atmosphere with a computer controlled CHI600E electrochemical workstation in a three electrode single- compartment cell using platinum electrodes and Ag/AgCl electrode as reference electrode, with Fc/Fc* redox couple as internal standard, with a tetrabutyl-ammonium hexafluoro-phosphate (Bu₄NPF₆) solution (0.1 mol L^-1) in DMF at a scan rate of 0.1 V s^-1.

Synthesis of materials

N,N’-diethylhexyl-1,7-di (p-tertbutylphenoxyl) perylene diimide (DBOPDI) and N,N’-diethylhexyl-1,7-dibromo- perylene diimide (DBrPDI) were synthesized in our group.¹⁶16 Zhao, H.; Zhang, Y. Y.; Xu, H.; He, Z. M.; Zhang, Z. L.; Zhang, H. Q.; Tetrahedron 2005, 71, 7752.

DBOPDI radical anion salt

A mixture of N,N’-diethylhexyl-1,7-di (p-tertbutylphenoxyl) perylene diimide (DBOPDI) (0.46 g, 0.5 mmol, 1 eq.) and DMF (17 mL) first undergone stirring on a magnetic stirrer thermostat for 10 min at room temperature. Then add potassium carbonate ( 2 eq.) as a catalyst and the temperature was adjusted to 85 ºC and kept for 24 h. After the reaction, the solvent was removed by rotary evaporation. The solid residue was thoroughly washed with enough water and then was vacuum-dried at 80 ºC for 24 h. Then, the crude product was dissolved in eluent [V (petroleum ether): V (THF) = 3:1] and purified by column chromatography on silica 200-300 to afford the DBOPDI radical anion salt (0.224 g, 0.24 mmol, yield: 48.7%). FT-IR(KBr), υ: 2960 cm^-1, 2933 cm^-1, 2871 cm^-1, 1730 cm^-1, 1697 cm^-1, 1656 cm^-1, 1595 cm^-1, 1506 cm^-1, 1461 cm^-1, 1284 cm^-1,1122 cm^-1,1074 cm^-1. UV-vis: λ_max: 700 nm and 757 nm. EPR: 338.22 G and 338.85 G.

DBrPDI radical anion salt

A mixture of N,N’-diethylhexyl-1,7-dibromo- perylene diimide (DBrPDI) (0.385 g, 0.50 mmol, 1 eq.) and DMF (17 mL) first undergone stirring on a magnetic stirrer thermostat for 10 min at room temperature. Then add potassium carbonate (2 eq.) as a catalyst and the temperature was adjusted to 85 ºC and kept for 24 h. After the reaction, the solvent was removed by rotary evaporation. The solid residue was thoroughly washed with enough water and then was vacuum-dried at 80 ºC for 24h. Then, the crude product was dissolved in eluent [V (petroleum ether): V (THF)= 3:1] and purified by column chromatography on silica 200-300 to afford the DFPDI radical anion salt (0.488 g, 0.302 mmol, yield: 60.5%). FT-IR(KBr), υ: 2956 cm^-1, 2927 cm^-1, 2858 cm^-1, 1720 cm^-1, 1697 cm^-1, 1656 cm^-1, 1585 cm^-1, 1460 cm^-1, 1434 cm^-1, 1402 cm^-1, 1332 cm^-1, 1244 cm^-1, 1186 cm^-1. UV-vis: λ_max: 705 nm and 766 nm. EPR: 339.12 G and 339.71 G.

RESULTS AND DISCUSSION

Synthesis and Structure characterization

DBOPDI and DBrPDI have been synthesized according to relevant literature. The chemical structure of DBOPDI and DBrPDI has been confirmed by ¹H NMR, ¹³C NMR spectroscopy and FT-IR spectrophotometry in our research. Synthetic route for DBOPDI^.-K⁺ and DBrPDI^.-K⁺ are showed in Scheme 1.

FT-IR spectra of the DBOPDI and DBrPDI radical anion was showed in supporting information (^{Figure 1S} SUPPLEMENTARY MATERIAL Figures 1S-4S are freely available at http://quimicanova.sbq.org.br, in pdf format. and ^{Figure 2S} SUPPLEMENTARY MATERIAL Figures 1S-4S are freely available at http://quimicanova.sbq.org.br, in pdf format. ). In contrast with its patent, both the N-C=O and C=C stretch bands somewhat shifted from 1704 and 1667 cm^-1 (N-C=O) to 1696 and 1656 cm^-1 (N-C=O) and from 1600 and 1518 cm^-1 (C=C) to 1594 and 1515 cm^-1 (C=C). The characteristic shift to lower wave-number belongs to the additional amount of electron density that was localized in the C=O π* orbital.

Due to the paramagnetic PDIs radical anion salt, to get signal from ¹H and ¹³C NMR spectroscopy is difficult. However, a favorable evidence to confirm presence of PDIs radical anion salt came from the UV-vis absorption spectra (Figure 1a) and EPR spectroscopy (Figure 1b). The characteristic peak (0-0 transition) of neutral perylene diimide appeared at 525 nm and 545 nm for DBrPDI and DBOPDI, respectively. In contrast, new characteristic peaks were observed at 768 nm ture of Pand 759 nm for DBrPDI^.-k⁺ and DBOPDI^.-k⁺, respectively.¹⁷17 Marcon, R. O.; Brochsztain, S.; J. Phys. Chem. A 2009, 113, 1747. Furthermore, maximal absorption bond (0-0 transition) of neutral perylene diimide disappeared in the absorption spectra for DBrPDI^.-k+ and DBOPDI^.-k+, which was also a favorable evidence for the formation of PDIs radical anion salt.

Figure 1
a: UV-vis spectra of DBrPDI, DBrPDI^.-k⁺, DBOPDI and DBOPDI^.-k⁺ in DMF; b: EPR of DBOPDI^.-k⁺ and DBrPDI^.-k⁺

EPR spectroscopy obtained at room temperature at X-band (9.5 GHz) with 0.02 mT field modulation was further used to obtain information on the spin density distribution within the anion radicals of PDIs (Figure 1b). In agreement with the values reported for paramagnetic PDI radical anion, the strong EPR signals were observed expounding the presence of paramagnetic radical anion.⁹9 Shirman, E.; Ustinov, A.; Ben-Shitrit, N.; Weissman, H.; Iron, M. A.; Cohen, R.; Rybtchinski, B.; J. Phys. Chem. B 2008, 112, 8855.^,1515 He, E. F.; Wang, J. M.; Xu, H.; He, Z. M.; Wang, H. L.; Zhao, H.; Zhang, Y. Y.; Zhang, R. J.; Zhang, H. Q.; J. Mater. Sci. 2016, 14, 6583. The different magnetic field also suggested the strong interactions between the unpaired spin and the electron-withdrawing groups.

Effects of bay-substituents on formation rate of the radical anion

The relationship between reaction time and yield was monitored by UV-vis spectra in order to investigate the effect of withdrawing or donating groups on the formation rate of perylene diimide radical anion salt (Figure 2a, b, c). Absorption peak at 525 nm and 545 for DBrPDI and DBOPDI assigned to 0-0 transition of neutral PDIs.¹⁶16 Zhao, H.; Zhang, Y. Y.; Xu, H.; He, Z. M.; Zhang, Z. L.; Zhang, H. Q.; Tetrahedron 2005, 71, 7752. With increasing reaction time, the UV/Vis-NIR characteristic peaks appeared at around 434 nm and 760 nm for bay-substituted PDI (DBrPDI and DBOPDI) indicating the appearance of the PDIs radical anions.¹⁸18 Lu, W.; Gao, J. P.; Wang, Z. Y.; Qi, Y.; Sacripante, G. G.; Duff, J. D.; Sundararajan, P. R.; Macromolecules 1999, 32, 8880. The ratio of absorption intensity (λ=765 nm and λ= 525 nm) is proportional to the yield of radical anion. Clearly, the formation rate of radical anion of DBOPDI is higher than that of DBrPDI (Figure 2 c) at the same time. The result indicated that the formation rate of PDIs radical anion salt by alkali strongly depend on their chemical structure, that is to say, the introduction of donating groups is conducive to the formation of PDIs radical anion.

Figure 2
UV-vis spectra of DBOPDI and DBrPDI with the different reaction time in DMF, (a) DBOPDI (b) DBrPDI; (c) A comparison of absorption spectra with the same reaction time in DMF; (d) Cycle voltammograms of DBOPDI and DBrPDI recorded in DMF containing 0.1 M n-Bu₄NPF₆ at 0.1 V s^-1

To address the reduction activity of the PDIs in DMF, the reduction potentials of PDIs in DMF were compared, as is showed in Figure 2 d. PDIs exhibits two reversible reduction waves, which is similar to the typical bay-substituted perylene diimide derivatives.¹⁶16 Zhao, H.; Zhang, Y. Y.; Xu, H.; He, Z. M.; Zhang, Z. L.; Zhang, H. Q.; Tetrahedron 2005, 71, 7752. The first reduction potential for DBOPDI and DBrPDI were -0.34 V and -0.17 V, respectively. Thus, the DBrPDI was easier to be reduced to the corresponding radical anion compared to that of DBOPDI. On the contrary, in fact, the formation rate of DBOPDI was larger than that of DBrPDI. This result indicated it is not a simple reduction reaction to prepare to PDIs radical anion salt by leveraging the alkali treatment.

Effects of bay-substituents on UV-vis spectra of PDIs radical anion salt during adding Cu ²⁺

Our study indicated that the reduced PDI species exhibited the optical response to the different metal ions (such as: Cu²⁺, Hg²⁺, Ni²⁺ and Fe³⁺ ) with different sensitivity.¹⁵15 He, E. F.; Wang, J. M.; Xu, H.; He, Z. M.; Wang, H. L.; Zhao, H.; Zhang, Y. Y.; Zhang, R. J.; Zhang, H. Q.; J. Mater. Sci. 2016, 14, 6583. Similar optical response to the different metal ions also was also observed for DBOPDI^.-K⁺ and DBrPDI^.-K⁺ (Supporting information: ^{Figure 3S} SUPPLEMENTARY MATERIAL Figures 1S-4S are freely available at http://quimicanova.sbq.org.br, in pdf format. and ^4S SUPPLEMENTARY MATERIAL Figures 1S-4S are freely available at http://quimicanova.sbq.org.br, in pdf format. ). Here, we considered the effect of Cu²⁺on UV-vis spectra of two radical anion salt, and the result were shown in Figure 3. Obviously, the intensity of absorption peak of radical anion decreased with titration of the metal ions, while the intensity of absorption peak of neutral PDIs increased. The results indicated that the PDIs radical anion changed into corresponding neutral PDIs after metal ions being added. Furthermore, there was a significant linear correlation between the maximal absorption intensity of radical anion or neutral PDIs and the concentration of metal ions (Figure 4). Therefore, we believe that PDIs radical anion may be advantageous for the detection of heavy metal ions by utilizing the UV-vis spectrophotometer.

Figure 3
UV-vis spectra titration of PDIs radica anion salt with different concentration of Cu²⁺, (a: DBOPDI^.-k⁺; b: DBrPDI^.- k⁺ )

Figure 4
a: (I_f-I₀)/I₀ vs concentration of Cu²⁺ (here: I₀: intensity before adding Cu²⁺; I_f: intensity after adding Cu²⁺; l = 555 nm); b: DBOPDI/DBOPDI^.-, DBrPDI/DBrPDI^.-, Cu²⁺/Cu⁺ and Cu²⁺/Cu⁰

Effects of bay-substituents on selectivity of Cu²⁺

Cu²⁺ to the optical sensibility of DBOPDI^.-k⁺ and DBrPDI^.-k⁺ were discussed by (I_f-I₀)/I₀ vs concentration of Cu²⁺ (here: I₀: intensity before adding Cu²⁺; I_f: intensity after adding Cu²⁺; 555 nm), as is showed in Figure 4a. Cu²⁺ to optical sensibility of DBOPDI^.-k⁺was significantly higher than that of DBrPDI^.-k⁺. Here, a more likely explanation for this phenomenon is that redox reactions occurred between PDIs radical anion and Cu²⁺. PDIs radical anion was oxidized to corresponding neutral PDIs and Cu²⁺ was reduced to Cu⁺ or Cu. The similar reaction has been reported by Screttas CG based on chemical reaction between the magnesium chloride and sodium naphthalene radical anion.¹⁹19 Steele, B. R.; Heropoulos, G. A.; Screttas, C. G.; Collect. Czech. Chem. Commun. 2007, 72, 589. Therefore, Cu²⁺ to the optical sensibility of DBOPDI^.-k⁺ and DBrPDI^.-k⁺that the reaction rate between PDIs radical anion and Cu²⁺ depend on the difference between the PDI/PDI^.- and Cu²⁺/cu⁺ or Cu²⁺/cu⁰ (Figure 4b). Clearly, DBOPDI radical anion with Cu²⁺ has a higher reaction rate compared to that of the DBrPDI radical anion.

CONCLUSIONS

Two perylene diimide radical salt with different substituents at bay position were synthesized by using the alkali treatment in DMF solution. The formation rate of radical anion salt, and the difference of response to Cu ²⁺, were depend on bay-substituents. The introduction of electron-donating groups at bay-position of perylene diimide [4-(1,1-dimethylethyl)phenoxyl] is favourable to increasing the formation rate of radical anion salt, and the optical sensitive to metal ions.

SUPPLEMENTARY MATERIAL

Figures 1S-4S are freely available at http://quimicanova.sbq.org.br, in pdf format.

ACKNOWLEDGEMENTS

This work was supported by the National Natural Science Foundation of China (No: 51673157, 51472214).

REFERENCES

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