D-A type polymer donor material based on benzodithiophene and benzotriazole and preparation method thereof
1. A D-A type polymer donor material based on benzodithiophene and benzotriazole is characterized by having a chemical structure shown as a general formula I:
wherein, the heteroatom X connected with the beta position of the benzothiophene side chain thiophene is H, Cl or F.
2. The preparation method of the benzodithiophene and benzotriazole-based D-A type polymer donor material according to claim 1, which is characterized by comprising the following steps:
(1) taking 3-fluoro-2 carboxylic thiophene and iodine simple substance as raw materials, and carrying out nucleophilic substitution under the condition that potassium phosphate and acetonitrile are used as solvents to prepare an intermediate 1, wherein the structure is as follows:
(2) the intermediate 1 and triethylchlorosilane react to prepare an intermediate 2, and the structure is as follows:
(3) and reacting the intermediate 2 with tributyltin chloride to obtain an intermediate 3, wherein the structure is as follows:
(4) the intermediate 3 and 4, 7-dibromo-5, 6-difluoro-2- (2-hexyldecyl) -2H-benzo [ d ] [1,2,3] triazole are subjected to Stille coupling under the action of a catalyst to obtain an intermediate 4, and the structure of the intermediate is as follows:
(5) and performing deprotection on the intermediate 4 and tetrabutylammonium fluoride under the action of a catalyst to obtain an intermediate 5, wherein the structure is as follows:
(6) and carrying out bromination reaction on the intermediate 5 and NBS to obtain an intermediate 6, wherein the structure is as follows:
(7) the intermediate 6 and the intermediate M are subjected to Stille coupling under the action of a catalyst to obtain the D-A type polymer donor material based on the benzodithiophene and the benzotriazole;
wherein the intermediate M is BDT75, BDT77 or BDT 76;
when the intermediate M is BDT75, the target polymer J52FH is obtained, and the structure of the target polymer is as follows:
when the intermediate M is BDT77, a target polymer J52FCl is obtained, and the structure of the target polymer is as follows:
when the intermediate M is BDT76, the target polymer J52FF is obtained, and the structure of the target polymer is as follows:
3. the benzodithiophene and benzotriazole-based D-A type polymer donor material of claim 2, which is characterized in that: in the steps (1) - (7), the reaction medium of the reaction is one or multiple mixture of acetonitrile, tetrahydrofuran, toluene and chlorobenzene.
4. The benzodithiophene and benzotriazole-based D-A type polymer donor material of claim 2, which is characterized in that: in the steps (4), (5) and (7), the catalyst used in the reaction is one or a mixture of more of tetrakis (triphenylphosphine) palladium and tetrabutylammonium fluoride.
5. The benzodithiophene and benzotriazole-based D-A type polymer donor material of claim 2, which is characterized in that: in the step (1), the alkali is potassium phosphate.
6. The benzodithiophene and benzotriazole-based D-A type polymer donor material of claim 2, which is characterized in that: in the step (1), the molar ratio of the iodine simple substance to the potassium phosphate is 1: 1.5-1: 3.
7. The benzodithiophene and benzotriazole-based D-A type polymer donor material of claim 2, which is characterized in that: in the steps (1) - (7), the reaction temperature of the reaction is-78-110 ℃.
8. The benzodithiophene and benzotriazole-based D-A type polymer donor material of claim 2, which is characterized in that: in the steps (1) to (7), the reaction time is 2 to 60 hours.
Background
Organic Polymer Solar Cells (PSCs) have attracted a great deal of research attention over the past because of their advantages of being foldable, inexpensive, and adjustable in molecular energy levels.
Up to now, the photoelectric conversion efficiency of organic solar cells with polymers as donor active materials has exceeded 18%. With the continuous development of related researches, the photovoltaic performance of both donor materials and acceptor materials is continuously improved. Among the factors affecting the performance of photovoltaic devices, the introduction of functional atoms has been an important strategy for improving the photoelectric performance of active layer materials. Many previous studies have demonstrated that the introduction of fluorine atoms into polymer acceptor units having a conjugated structure of D-a is an effective method for improving photoelectric conversion efficiency. Fluorinated organic semiconductor units generally have several advantages: firstly, fluorine-containing molecules can simultaneously reduce the HOMO energy level and the LUMO energy level without causing large steric hindrance, which is beneficial to improving the open-circuit voltage of a device; secondly, the fluorinated molecules generally have an interaction of non-covalent bonds such as F … H, F … F, which can improve the intramolecular and intermolecular interactions, which helps to improve the crystallinity of the molecules and thus the charge transfer efficiency; third, fluorinated molecules have higher absorption coefficients and polarizabilities than non-fluorinated semiconductors, reducing the coulombic potential between holes and electrons. However, the existing D-A type polymer donor materials still have no great progress in photoelectric properties.
Disclosure of Invention
In order to overcome the defects and shortcomings in the prior art, the invention aims to provide a D-A type polymer donor material based on benzodithiophene and benzotriazole, and a D-A type polymer donor material is designed by taking Benzodithiophene (BDT) as an electron donor unit, 3-fluorothiophene as a pi bridge and benzotriazole (BTz) as an acceptor unit from the design concepts of conjugated skeleton design, side chain modification and heteroatom introduction. The material has the advantages of novel target molecular structure, simple synthesis and excellent photoelectric property.
The invention also aims to provide a preparation method of the D-A type polymer donor material based on the benzodithiophene and the benzotriazole, which is a preparation method of the D-A type polymer donor material with 3-thiophene as a bridging bridge, BDT as an electron donating unit and BTz as an electron accepting unit.
The purpose of the invention is realized by the following technical scheme: a D-A type polymer donor material based on benzodithiophene and benzotriazole has a chemical structure shown as a general formula I:
wherein, the heteroatom X connected with the beta position of the benzothiophene side chain thiophene is H, Cl or F.
The other purpose of the invention is realized by the following technical scheme: the preparation method of the D-A type polymer donor material based on the benzodithiophene and the benzotriazole comprises the following steps:
(1) taking 3-fluoro-2 carboxylic thiophene and iodine simple substance as raw materials, and carrying out nucleophilic substitution under the condition that potassium phosphate and acetonitrile are used as solvents to prepare an intermediate 1, wherein the structure is as follows:
(2) the intermediate 1 and triethylchlorosilane react to prepare an intermediate 2, and the structure is as follows:
(3) and reacting the intermediate 2 with tributyltin chloride to obtain an intermediate 3, wherein the structure is as follows:
(4) the intermediate 3 and 4, 7-dibromo-5, 6-difluoro-2- (2-hexyldecyl) -2H-benzo [ d ] [1,2,3] triazole are subjected to Stille coupling under the action of a catalyst to obtain an intermediate 4, and the structure of the intermediate is as follows:
(5) and performing deprotection on the intermediate 4 and tetrabutylammonium fluoride under the action of a catalyst to obtain an intermediate 5, wherein the structure is as follows:
(6) and carrying out bromination reaction on the intermediate 5 and NBS to obtain an intermediate 6, wherein the structure is as follows:
(7) the intermediate 6 and the intermediate M are subjected to Stille coupling under the action of a catalyst to obtain the D-A type polymer donor material based on the benzodithiophene and the benzotriazole;
wherein the intermediate M is BDT75, BDT77 or BDT 76;
when the intermediate M is BDT75, the target polymer J52FH is obtained, and the structure of the target polymer is as follows:
when the intermediate M is BDT77, a target polymer J52FCl is obtained, and the structure of the target polymer is as follows:
when the intermediate M is BDT76, the target polymer J52FF is obtained, and the structure of the target polymer is as follows:
the synthesis method comprises the steps of carrying out substitution reaction, silane group protection group adding, stannyl group adding, Stille coupling, deprotection and NBS bromination reaction on 3-fluoro-2-carboxylic thiophene serving as a raw material to obtain an intermediate 6, and finally coupling the intermediate 6 with purchased intermediates BDT75, BDT76 and BDT 77. The BDT and BTz-based organic solar cell polymer donor material is simple in synthesis and purification method, easy to control reaction conditions, high in yield, universal in applicability and capable of being synthesized efficiently.
The invention redesigns an efficient synthetic route aiming at the problems of easy volatilization, low yield, long synthetic route and the like of an important intermediate of 3-fluorothiophene, and designs and synthesizes three D-A type polymer donor materials taking BDT as an electron donor unit, 3-fluorothiophene as a pi bridge and BTz as an acceptor unit, namely J52FH, J52FCl and J52 FF. Meanwhile, the influence of fluorine atoms introduced into the pi bridge and the synergistic effect between different atoms of the main chain and the side chain on the thermal stability, absorption spectrum, electrochemistry, the morphology of the active layer and photovoltaic performance of the photovoltaic material is systematically researched.
In the above technical solution, in the steps (1) to (7), the reaction medium of the reaction is one or more of acetonitrile, tetrahydrofuran, toluene, and chlorobenzene.
In the above technical means, preferably, in the steps (4), (5) and (7), the catalyst used in the reaction is one or more of tetrakis (triphenylphosphine) palladium and tetrabutylammonium fluoride.
Preferably, in the step (1), the base is potassium phosphate.
Preferably, in the step (1), the molar ratio of the iodine to the potassium phosphate is 1: 1.5-1: 3.
Preferably, in the steps (1) to (7), the reaction temperature of the reaction is-78 to 110 ℃.
In the above-mentioned means, the reaction time in the steps (1) to (7) is preferably 2 to 60 hours.
The invention has the beneficial effects that:
(1) the invention synthesizes important fluorine-containing intermediate 1 by a high-efficiency simple method, and obtains a D-A type polymer donor material which takes 3-thiophene as bridging, BDT as an electron-donating unit and BTz as an electron-accepting unit on the basis of silane-based protecting group, stannyl, Stille coupling, deprotection and NBS bromination reaction;
(2) the synthesis method provided by the invention has the advantages of mild reaction, easy control, simple purification process and low synthesis cost;
(3) the three polymers show stronger light absorption in the wavelength range of 400-650nm, and can form complementary ultraviolet-visible light absorption with corresponding acceptor materials. The EQE of the photovoltaic device based on the three polymer donor materials in the wave band of 450-680nm basically reaches more than 80%, and the effective absorption of the corresponding active layer to light energy is shown. The PL curve shows that the blended active layers all show good quenching effect, which indicates that effective exciton dissociation and charge transfer exist between the donor material and the acceptor material.
(4) Electrochemical studies have shown that the HOMO level of the donor polymer can be greatly reduced by implementing a fluorination strategy on the backbone, thereby helping to raise the V of the photovoltaic deviceoc. From the DFT, it can be seen that all three polymers have excellent planarity, giving the acceptor fragments almost on the same plane. AFM results were shown to be at the mostThe blending film under the condition of a good device forms an interpenetrating network structure. These benefit primarily from the non-covalent synergistic interaction between the backbone fluorine atoms and the side chain groups, resulting in a relatively smooth surface topography of the active layer.
(5) The performance test result of the photovoltaic device shows that the three polymers have excellent performance, and the solar cell PCE based on J52FF reaches 13.93 percent, and the V of the solar cell PCEoc、JscAnd FF of 0.89V and 22.27mA cm-2And 70.3% is the highest level currently achievable based on BDT-pi-BTz type polymer donor materials. This result indicates that fluorination on the polymer backbone is an effective strategy to achieve high performance organic polymer solar cells.
Drawings
FIG. 1 is a nuclear magnetic hydrogen spectrum of intermediate 6;
FIG. 2 is a nuclear magnetic carbon spectrum of intermediate 6;
FIG. 3 is a mass spectrum of intermediate 6;
FIG. 4 is a nuclear magnetic hydrogen spectrum of J52 FH;
FIG. 5 is a nuclear magnetic hydrogen spectrum of J52 FCl;
FIG. 6 is a nuclear magnetic hydrogen spectrum of J52 FF;
FIG. 7 is a thermogravimetric plot of three target polymers;
FIG. 8 is the UV-VIS absorption of three target polymers in chloroform solution (a);
FIG. 9 is UV-VIS absorption of three target polymers in the thin film state (b);
FIG. 10 is a height and phase diagram of an atomic force microscope for active layer, J52FH: ITIC (a, d), J52FCl: IT-4F (b, e), J52FF: IT-4F (c, F);
FIG. 11 is a J-V curve (a) for three target polymers;
fig. 12 is the EQE curve (b) for the three target polymers.
Detailed Description
For the understanding of those skilled in the art, the present invention will be further described with reference to the following examples and drawings, which are not intended to limit the present invention.
Example 1
A preparation method of a D-A type polymer donor material based on benzodithiophene and benzotriazole comprises the following steps:
synthesis of intermediate 1
3-fluoro-2-carboxylic acid thiophene (1.46g, 10mmol) and elementary iodine (I)2) (10.16g, 40mmol) and potassium phosphate (4.25g, 20mmol) were added sequentially to a 100mL three-necked flask and dissolved in 50mL acetonitrile. And carrying out reflux reaction on the system for 24h under the nitrogen atmosphere and at the temperature of 100 ℃, pouring the reaction solution into 100mL of distilled water after cooling to room temperature, extracting with ethyl acetate, and washing the organic layer with sodium bisulfite aqueous solution to obtain orange color. The upper organic solution was collected and then dried over anhydrous magnesium sulfate, filtered through filter paper and then distilled under reduced pressure to remove the solvent, and the residue was purified by column chromatography (200-300 mesh) with petroleum ether as an eluent to give intermediate 1 as a brown oily liquid (2.05g, yield 90%).1H NMR(400MHz,CDCl3)δ:7.41(dd,J=5.8,4.0Hz,1H),6.70(dd,J=5.8,1.6Hz,1H).13C NMR(101MHz,CDCl3)δ:162.15,159.57,130.29,117.43,117.16,77.41,77.09,76.77,53.42,53.15,32.00,29.78,22.78,14.23.MALDI-TOF-MS,m/z:calcd for C4H2FIS[M]+:228.03;found 228.02。
Synthesis of intermediate 2
Intermediate 1(1.14g, 5mmol) was charged to a 100mL three-necked flask and dissolved thoroughly with 35mL anhydrous THF, then triethylchlorosilane (0.9g, 6mmol) was mixed with 10mL anhydrous THF and added to a constant pressure dropping funnel and the system was replaced with nitrogen by evacuation. Reacting the system for 20min at-78 ℃ under magnetic stirring, slowly dropwise adding n-butyllithium (1.6M, 3.4mL) through a syringe, and dropwise adding triethylchlorosilane in a constant-pressure dropping funnel after reacting for 2 h. After 1h, the system was allowed to move to room temperature for further reaction for 6h and quenched with 100mL of distilled water. The reaction solution was extracted with ethyl acetate and washed three times with saturated brine, the collected organic solution was dried over anhydrous magnesium sulfate, filtered and distilled under reduced pressure to remove the solvent, and the residue was purified by column chromatography (200-300 mesh) with petroleum ether as an eluent to give intermediate 2 as a white transparent liquid (0.91g, yield 84%).1H NMR(400MHz,CDCl3)δ:7.41(dd,J=4.9,2.7Hz,1H),6.87(dd,J=5.0,1.3Hz,1H),1.01(t,J=7.7Hz,9H),0.85(t,J=7.7Hz,6H).13C NMR(101MHz,CDCl3)δ:165.14,162.30,129.99,118.19,117.87,77.88,77.04,76.73,7.26,4.06.MALDI-TOF-MS,m/z:calcd for C10H17FSSi[M]+:216.39;found 216.29。
Synthesis of intermediate 3
Intermediate 2(1g, 4.63mmol) was dissolved in 40mL of anhydrous THF and charged to a 100mL three-necked flask, then tributyltin chloride (2.7g, 8.29mmol) was mixed with 10mL of anhydrous THF and charged to the constant pressure dropping funnel and the system was replaced with nitrogen by evacuation. Reacting the system for 20min at-78 ℃ under magnetic stirring, slowly dripping Lithium Diisopropylamide (LDA) (2M, 3.45mL) by using an injector, slowly dripping tributyltin chloride in a constant-pressure dropping funnel after 2h, stirring for 1h, transferring the system to room temperature, reacting for 6h, quenching by using 100mL of distilled water, extracting by using ethyl acetate, and washing by using saturated saline solution for three times. The collected organic solution was dried over anhydrous magnesium sulfate, filtered and the solvent was distilled off under reduced pressure to obtain intermediate 3 as a brown liquid (2.11g, yield 90%), which was used in the next reaction without purification.
Synthesis of intermediate 4
Intermediate 3(2.5g, 4.95mmol), BTz (0.6g, 1.41mmol) and tetrakis (triphenylphosphine) palladium (1.63mg, 0.05mmol) were added to a 100mL three-necked flask and dissolved in 30mL dry toluene. The reaction was then evacuated three times and replaced with nitrogen, slowly heated to 110 ℃, refluxed and stirred under nitrogen for 48 h. After cooling to room temperature, the reaction mixture was poured into 100mL of distilled water, extracted with ethyl acetate and washed with saturated brine, and the organic solution was collected and then anhydrous MgSO4Drying, filtration and removal of the solvent by distillation under reduced pressure, and purification of the residue by column chromatography (200-300 mesh) with petroleum ether as eluent gave intermediate 4 as a yellow fluorescent oily liquid (0.79g, 87% yield).1H NMR(400MHz,CDCl3)δ:8.11(s,2H),4.72(d,J=6.4Hz,2H),2.29-2.23(m,1H),1.26(d,J=3.5Hz,24H),1.04(d,J=7.5Hz,12H),0.90(dd,J=18.3,10.4Hz,24H).13CNMR(101MHz,CDCl3)δ:164.72,162.18,148.73,146.20,137.19,135.96,120.49,120.16,115.76,115.45,109.72,77.36,77.04,76.72,59.99,39.08,31.87,31.46,29.89,29.58,29.34,26.30,22.69,14.10,7.31,4.06.MALDI-TOF-MS,m/z:calcd for C42H65F4N3S2Si2[M]+:808.28;found 807.53。
Synthesis of intermediate 5
After addition of intermediate 4(1.9g, 2.35mmol) to a 50mL single neck flask and dissolution in 30mL of anhydrous THF, tetrabutylammonium fluoride (4.6mL, 1M) was added dropwise at room temperature and stirred magnetically, and the completion of the reaction was checked by TLC every 20 min. Pouring the reaction solution into 50mL of distilled water after no raw material exists, extracting with ethyl acetate, washing with saturated saline, collecting the organic solution, and passing through anhydrous MgSO4Drying, filtration and removal of the solvent by distillation under reduced pressure, and purification of the residue by column chromatography (200-300 mesh) with petroleum ether as eluent gave intermediate 5 as a yellow solid (1.01g, 74% yield).1H NMR(400MHz,CDCl3)δ:8.06–8.01(m,2H),6.88(s,2H),4.72-4.67(m,2H),2.29-2.22(m,1H),1.28(t,J=11.6Hz,24H),0.87(t,J=6.5Hz,6H).13C NMR(101MHz,CDCl3)δ:159.38,156.82,148.66,146.13,137.09,131.03,119.73,119.45,109.82,105.82,77.35,77.03,76.71,60.04,39.14,31.86,31.49,29.90,29.58,29.32,26.28,22.67,14.08.MALDI-TOF-MS,m/z:calcd for C30H37F4N3S2[M]+:579.76;found579.69。
Synthesis of intermediate 6
After adding intermediate 5(750mg, 1.29mmol) and NBS (0.63g, 3.54mmol) to a 50mL single-neck flask, the mixture was dissolved in 25mL THF sufficiently, and glacial acetic acid (AcOH) was slowly added dropwise thereto under magnetic stirring in an amount of 10mL, and the reaction was stopped after detecting the substantial absence of the starting material by TLC at room temperature for 2 hours. Pouring the reaction solution into 25mL of distilled water, extracting with ethyl acetate, washing with saturated brine, collecting the organic solution, and collecting the organic solution through anhydrous MgSO4Drying, filtration and spin-evaporation to remove the solvent, the residue was purified by column chromatography (200-300 mesh) with petroleum ether as eluent to give intermediate 6 as a yellow solid (764mg, 80% yield). It is composed ofThe results of the analysis are shown in figures 1-3,1H NMR(400MHz,CDCl3)δ:7.93-7.85(m,2H),4.70(d,J=6.2Hz,2H),2.26-2.20(m,1H),1.28(dd,J=15.5,10.5Hz,24H),0.86(dd,J=7.9,5.0Hz,6H).13C NMR(101MHz,CDCl3)δ:157.32,154.74,136.67,130.64,119.29,109.32,95.31,95.11,77.36,77.04,76.73,60.01,39.20,31.90,31.47,29.95,29.64,29.37,26.29,22.71,14.14.MALDI-TOF-MS,m/z:calcd for C30H35Br2F4N3S2[M]+:737.55;found 737.37。
synthesis of D-A type Polymer Donor materials
A25 mL two-necked flask was charged with intermediate 6(81mg, 0.1mmol), intermediate BDT75(99mg, 0.1mmol), and Pd (PPh)3)4(25mg, 0.02mmol), dissolved in 5mL of chlorobenzene and the reaction evacuated three times, slowly heated to 110 deg.C, refluxed and stirred under nitrogen for 48 h. The reaction solution was transferred to 25mL of anhydrous methanol and precipitated, the supernatant was removed, and then precipitated with n-hexane 3 times, followed by filtration and drying, and then purified by silica gel column chromatography (petroleum ether: dichloromethane ═ 4:1 as an eluent) to obtain polymer J52FH as a magenta solid (80mg, yield 70%). Mn=30.2kDa,TdThe analysis results are shown in figure 4 at 203 c,1H NMR(400MHz,CDCl3)δ:8.5-6.0(br),5.7-4.0(br),3.5-2.5(br),2.4-0.3(br)。
example 2
This example differs from example 1 in that:
synthesis of D-A type Polymer Donor materials
Referring to the synthesis of polymer J52FH, starting from intermediate 6(91mg, 0.123mmol) and intermediate BDT77(120mg, 0.123mmol), the reaction yielded polymer J52FCl as a purple-red solid (120mg, 85% yield). Mn=38.4kDa,TdThe analysis results are shown in figure 5 at 213 c,1H NMR(400MHz,CDCl3)δ:8.4-6.0(br),5.6-3.8(br),3.7-2.5(br),2.4-0.3(br)。
example 3
This example differs from example 1 in that:
synthesis of D-A type Polymer Donor materials
Referring to the synthesis of polymer J52FH, starting from intermediate 6(110mg, 0.15mmol) and intermediate BDT76(145mg, 0.15mmol), the reaction yielded polymer J52FF as a purple solid (140mg, 78% yield). Mn=60.5kDa,Td272 c. the results of the analysis are shown in figure 6,1H NMR(400MHz,CDCl3)δ:8.3-6.3(br),5.7-3.5(br),3.2-2.5(br),2.4-0.3(br)。
example 4 Performance testing
And respectively testing the nuclear magnetic spectrum and the mass spectrum of the intermediate 6, respectively testing the nuclear magnetic hydrogen spectrum of the target molecule, as shown in figures 1-6, and performing performance test on the target molecule.
1. Thermal stability of the target Polymer
The results in Table 1 show the thermal decomposition temperatures (T) at 5% thermal weight loss for the three target polymersd) The thermogravimetric curves are shown in FIG. 7 at 203 deg.C, 213 deg.C and 272 deg.C, respectively. The results show that the three polymers have better thermal stability and meet the processing and preparation conditions of the photovoltaic device. The molecular weights of the polymers, number average molecular weights (M) of polymers J52FH, J52FCl, J52FF, were characterized by Gel Permeation Chromatography (GPC)n) 30.2kDa, 38.4kDa and 60.6kDa, respectively, corresponding to a polydispersity index (PDI) of 1.91, 1.73 and 2.13, respectively
TABLE 1 GPC data and 5% weight loss thermal decomposition temperatures for three target polymers
Polymers
Mn(kDa)
Mw(kDa)
Mz(kDa)
PDI
Td(℃)
J52FH
30.2
57.9
98.5
1.91
203
J52FCl
38.4
66.3
11.9
1.73
213
J52FF
60.6
13.0
24.5
2.13
272
2. Optical Properties of the target Polymer
From the results of FIGS. 8-9 and Table 2, it is shown that they show similar spectral absorption ranges in both solution and solid films, both around 300-650nm, which are capable of forming complementary optical absorptions with the corresponding acceptor materials. Wherein the short-band absorption of 300-380nm is mainly attributed to pi-electron transition of conjugated main chain, and the long-band absorption of 400-650nm is attributed to Intramolecular Charge Transfer (ICT) between BDT and BTz. The maximum absorption peak of J52FH in the solution state is 551nm, and both J52FCl and J52FF are 549 nm. Edges of J52FH, J52FCl and J52FFAbsorption peaks at 690, 681 and 675nm, respectively, corresponding to optical band gaps (E)g opt) At 1.80, 1.82 and 1.84 eV. The film absorption wavelength of all three polymers is red-shifted by 7nm compared to the absorption peak in chloroform solution, with a distinct shoulder, mainly due to the more ordered aggregation of molecules and the shortened intermolecular spacing in the solid film resulting in enhanced pi-pi stacking. Notably, the molar extinction coefficient of J52FH in solution is lower than that of J52FCl and J52FF, indicating that the introduction of halogen atoms in the side chains helps to enhance the light absorption intensity of the photovoltaic material, thereby facilitating the increase of the short-circuit current of the polymer organic solar cell.
TABLE 2 Spectroscopy and electrochemical data for target polymers
a is chloroform solution, b is solid film, wherein Eg opt=1240/λonset
3. Electrochemical Properties of the target Polymer
Table 2 the results show that the HOMO and LUMO energy levels of the three target polymers are-5.51, -5.53, -5.58eV and-3.68, -3.74, -3.70eV, respectively, and the detailed data are shown in Table 2. And (3) comparison finding: the LUMO energy level differences between the three target polymers and the corresponding acceptors are each greater than 0.3eV, which ensures that there is sufficient driving force to promote exciton dissociation to maximize charge transport. Although the HOMO levels of the three polymers differ slightly from the corresponding acceptors, efficient transport of excitons between them is seen from fluorescence quenching tests. Notably, the HOMO levels of the three polymers were significantly reduced when compared to the reported donor materials J52 or PFBZ, which indicates that the introduction of fluorine atoms on the thiophene pi-bridge helps to lower the HOMO levels of the materials, thereby increasing the open circuit voltage of the organic solar cell.
4. Accumulation and surface topography of active layers
It can be seen from fig. 10 that the root mean square Roughness (RMS) of the films after blending polymers J52FH, J52FCl, and J52FF with the receptor was 0.74, 0.95, and 0.81, respectively. The difference in the steric hindrance of the halogen atoms introduced by the side chains of the BDT can be the reason for the difference between the halogen atoms, but the planarity of the molecules as a whole is not greatly affected. A larger RMS indicates that there is excessive aggregation and larger phase separation between molecules, which is detrimental to exciton dissociation. In contrast, the RMS of the three polymers is at a lower level, and it can also be seen from the figure that the surface of the blended film has an interpenetrating network structure, indicating that there is good compatibility between the polymer donor and the acceptor. Better phase separation and ordered molecular accumulation can provide a smooth channel for the transmission of charges, and are favorable for improving the short-circuit current and the influence factor of the photovoltaic device.
5. Photovoltaic performance of target polymers
The results from FIGS. 11-12 and Table 3 show that the electron mobility of the three polymers is 2.0277X 10 respectively-4、2.6413×10-4And 2.2989 × 10-4cm2 V-1s-1Hole mobility of 1.4625X 10-4、2.2519×10-4And 4.8987 × 10-4cm2 V-1s-1. The data show that the electron mobility of the three polymers is not very different, but the hole mobility of J52FF is higher than that of J52FCl and J52FH, which is mainly due to the introduction of fluorine atoms on BDT to have a lower HOMO level. The higher hole mobility is beneficial to the transmission of charges, and exciton recombination is reduced, so that the short-circuit current and the influence factor of the photovoltaic device are improved, and the photoelectric conversion efficiency is improved.
The test result shows that the energy conversion efficiency of the organic polymer solar cell based on J52FH reaches 9.96 percent, and the V of the organic polymer solar cellocIs 0.94V, JscIs 19.62mA cm-2FF is 54.4%; the photovoltaic device PCE based on J52FCl is 10.52, Voc、JscAnd FF of 0.95V and 19.73mA cm-2And 56.5%; the PCE of the organic polymer solar cell based on J52FF reaches 13.93 percent, which is the highest level that all the conjugated polymers with BDT as an electron donating unit and BTz as an electron accepting unit can reach at present, and the V of the PCE is Voc、JscAnd FF is 0.89V and 22.27m respectivelyA cm-2And 70.3%. The results show V for three polymersocThe higher level is reached, which is mainly due to the introduction of fluorine atoms in the thiophene pi-bridge greatly reduces the HOMO level of the material. Higher J of the threescThey are related to their large extinction coefficient and the ability to form complementary light absorptions with the receptor material.
TABLE 3 photovoltaic Performance parameters of three target polymers
The above-described embodiments are preferred implementations of the present invention, and the present invention may be implemented in other ways without departing from the spirit of the present invention.
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