Carbon dioxide-controlled assembly based on conjugated polymer and boron nitride

Carbon dioxide-controlled assembly based on conjugated polymer and boron nitride

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Bo Wang^a, Chengfen Xing^a^,^*, Dong Gao^a, Hongbo Yuan^a, Liang Qiu^a, Xue Yang^b, Yang Huang^b^,^*, Yong Zhan^a

Chinese Chemical Letters | 2020, 31(1) : 261 - 264

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Chinese Chemical Letters | 2020, 31(1): 261-264

• Communications •

Carbon dioxide-controlled assembly based on conjugated polymer and boron nitride

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Bo Wang^a, Chengfen Xing^a^,^*, Dong Gao^a, Hongbo Yuan^a, Liang Qiu^a, Xue Yang^b, Yang Huang^b^,^*, Yong Zhan^a

Affiliations

^a Institute of Biophysics, Hebei University of Technology, Tianjin 300401, China

^b Hebei Key Laboratory of Boron Nitride Micro and Nano Materials, Hebei University of Technology, Tianjin 300130, China

Published: 2020-01-15 doi: 10.1016/j.cclet.2019.03.037

Outline

Abstract

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CO₂-controlled assembly of conjugated polymer and boron nitride (BN) was fabricated via electrostatic and hydrophobic interactions between the BN fiber and conjugated polymer of PFBT containing fluorene units and 2, 1, 3-benzothiadiazole units. CO₂, an effective and green stimulus for regulating the assembly of PFBT and BN fibers, leads to an obvious fluorescence variation. Moreover, PFBT enables the assembly with the signal amplification and light-harvesting properties. This work provides a new triggering method to construct intelligent conjugated polymer-based platform, and offers fluorescence monitoring strategy for carbon dioxide capture.

Key words

Conjugated polymers / Energy transfer / Boron nitride / Electrostatic interactions / Hydrophobic interactions / CO₂

Cite this Article

Bo Wang, Chengfen Xing, Dong Gao, Hongbo Yuan, Liang Qiu, Xue Yang, Yang Huang, Yong Zhan. Carbon dioxide-controlled assembly based on conjugated polymer and boron nitride[J]. Chinese Chemical Letters, 2020 , 31 (1) : 261 -264 . DOI: 10.1016/j.cclet.2019.03.037

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Currently, the assemblies of nano-materials have attracted great attention due to their wide potential application in drug delivery [1], biosensing [2] and bioimaging [3, 4]. Many stimuli, such as temperature, pH and light, could exert influence on the assemblies of nano-materials. Carbon dioxide (CO₂), a natural and green stimulus [5-7], has great potential in regulating the assemblies of nano-materials, including polymeric nano-materials [8-10], inorganic nano-materials [11, 12] and other assembly systems [13-16]. Moreover, CO₂-controlled conjugated polymers based materials have been developed as well, recently [17, 18]. However, CO₂ responsive materials still face some challenges. Generally, CO₂-responsive is attributed to pH responsive behaviour, since the pH of aqueous solutions is controlled by the concentration of CO₂ [19, 20]. The effectiveness of CO₂responsive materials might be limited by pH range, usually from 4.0 to around 7.6. Moreover, CO₂-responsive polymers can only exhibit their response at high CO₂concentrations in aqueous solution, limiting their biological applications. Therefore, developing a new triggering approach to construct pH-independent CO₂-responsive materials is highly desirable.

Due to the excellent fluorescence signal amplification, super light capturing ability and high fluorescence quantum yield, the assembly based on water-solubleconjugated polymers (WCPs) have been attracting enormous attentions in the field of biosensing [21, 22], cell imaging [23], protein detection [24] and disease treatment [25, 26]. CO₂-responsive conjugated polymers are based on the reaction of CO₂ with functional groups in the side chains. For example, Yoon and coworkers have constructed a CO₂-responsive polydiacetylene-based polymer [27]. Kang et al. introduced a fluorophore to PDMAEMA to prepare a CO₂-responsive polymer that exhibits a reversible color change by protonation or deprotonation of the aminemoiety in PDMAEMA through adding or removing CO₂, switching the fluorescence emission intensity [28]. However, the gas capture ability of WCPs still cannot be competitive with that of multiple dimension materials, such as boron nitride (BN) [29], which exhibits excellent thermal stability [30], high oxidation stability [31] and super chemical inertness [32]. Moreover, the structure of multi-interspace existed on the surface of BNs shows excellent ability in absorbing small molecules including CO₂, suggesting the BN to be potential platforms for CO₂ capture [33]. Meanwhile, the excellent mechanical strength of BN can be used as a backbone of composites. M. Pulickel's group developed a stable porous boron nitride foam structure, which exhibited good mechanical properties, large surface area, and high porosity to improve the ability to adsorb CO₂ [34]. Inspired by the above consideration, we construct here a CO₂-controlled assembly of 2, 1, 3-benzothia-diazole units modified polyfluorene (PFBT) and BN fiber. The PFBT contains a side chain with two amino and four carboxylic acid groups in each repeat unit. There is no interaction between PFBT and BN fiber in aqueous solution. Upon bubbling CO₂to the mixture of PFBT and BN fiber, the PFBT was adsorbed on the surface of BN fiber, showing an obvious variation of morphology. Moreover, the intramolecular energy transfer between fluorene structure and 2, 1, 3-benzothiadiazole occurs while bubbling CO₂ to the assemblies. Therefore, our assemblies give an opportunity to investigate the variation process of nano-assemblies.

As illustrated in Scheme 1, the PFBT exhibits negative charges in aqueous solution due to the deprotonation of carboxylic acid functionalized side chain. The strong electrostatic repulsion prevents the aggregation of the polymer backbones, leading to random dispersion state and blue fluorescence under UV light. As the dispersion of BN in aqueous solution exhibits negative electricity as well, owing to the B-O-H and N-O-H generated on BN in water [35, 36], the powerful electrostatic repulsion between PFBT and BN keeps them separated. With the introduction of CO₂, the protonation of carboxylate and amino groups in polymer PFBT decreases the electrostatic repulsion and enhances hydrophobic interactions between PFBT and BN, which promotes the interactions between the backbones of PFBT and BN, thus inducing shape-ordered aggregation. In addition, the intramolecular energy transfer from the polyfluorene to the 2, 1, 3-benzothiadiazole (BT) sites is also enhanced, causing color changing from blue to green. Therefore, the assembly of polymer PFBT with BN is controlled by carbon dioxide.

Materials and Instruments: All organic solvents and chemicals were purchased from Tianjin Komiou Chemical Reagent Co., Ltd. and Shanghai Macklin BiochemicalCo., respectively, and used according to the specifications. CO₂ (99.99% purity) was got from Tianjin Boliming Technology Co., Ltd. All solutions were prepared using Milli-Q water. The fluorescence spectra were assumed a Hitachi F-4600 fluorimeter furnished with a Xenon lamp excitation source. Dynamic light scattering (DLS) experiments and ζ potentials were accomplished with Nano-S90 (Malvern Instruments, UK). SEM images were measured by an EVO18 (ZEIZZ, GER) field-emission scanning electron microscope. AFM images were measured by a 5500 atomic force microscope (Agilent, USA) in a tapping mode. CO₂-adsorption isotherms were obtained by Autosorb iQ-C-TCD (Quantachrome, USA). The BN aqueous solution was dealt by ultrasonic cleaning (SB-5200DT).

Acquisition of CO₂ saturated ddH₂O: To 50.0 mL of pre-cooling ddH₂O was bubbled CO₂ (99.99% purity) at a constant flow rate of 1.0 mL/min for more than 60 min, carried out this step and stockpiled the solution in ice for use. The concentration of CO₂ enclosed in the CO₂ saturated ddH₂O is 76.05 mmol/L at 0 ℃, through referring to the Lange's Handbook of Chemistry.

Preparation of BN and PFBT aqueous solution: To 10 mg of the powder of BN was dispersed in 10 mL ultrapure water, and dealt by ultrasonic cleaning with a power of 20 W for about 5 min. PFBT was synthesized with reference to previous literature [37]. ¹H NMR (400 MHz, D₂O/Na₂CO₃): δ 7.70–7.28 (br, 8H), 3.51 (br, 2H), 3.0–2.8 (br, 13H), 2.3–2.6 (br, 8H), 2.2–2.0 (br, 18H), 1.0 (br, 4H), 0.90 (br, 4H).

Study for the CO₂-controlled assembly of PFBT and BN: To a series of disparate concentrations of BN aqueous solutions and carbon dioxide saturated solutions were added PFBT, respectively. The total experimental volume was controlled at 500 μL and the final concentration of PFBT was always maintained at 10 μg/mL. The fluorescence spectra were obtained using 500 μL glass cuvettes at 4 ℃. The scan speed was 2400 nm/min. The purpose of controlling the temperature of the Hitachi F-4600 fluorometer could be achieved by using the Recirculating Chiller F-305 (BÜCHI).

Materials characterization: The N₂ physisorption isotherms experiments measured by Autosorb iQ-C-TCD at -77 ℃. The pore size distribution was calculated by quenched solid density functional theory (QSDFT) [38, 39]. This method takes into account the effects of surface inhomogeneities and roughness on the geometric and chemically disordered micro and mesoporous structures, which apply to the current disordered PFBT/BN. BN and PFBT/BN aqueous solutions were prepared. PFBT/BN aqueous solution was bubbled with carbon dioxide gas near 30 min in a ice-bath and oscillated to dislodge redundant bubbles. Each of 2 μL BN, PFBT/BN and PFBT/BN with CO₂ were taken out and orderly placed on the clean silicon wafers (for SEM) and the mica wafer (for AFM), and transferrd to the refrigerator for about 20 min and freeze-dried for about 2 h by lyophilizer.

The conjugated polymer of PFBT and nanofiber of BN was synthesized according to previous literature [37]. The backbone of PFBT containing polyfluorene (PF) units as a donor and 2, 1, 3-benzothiadiazole (BT) units as receptor shows an obvious variation in fluorescence emission peak intensity under different concentration of CO₂ as shown in Fig. S2 (Supporting information). In order to investigate the influence of BN nanofiber materials on the fluorescence spectrum of PFBT, we measured the fluorescence spectrum of PFBT and PFBT-BN mixture upon CO₂bubbling, as shown in Fig. 1a.

The fluorescence spectrum suggests that PFBT displays an absorption peak at 380 nm and two distinct emission peaks, corresponding to the polyfluorene (PF) units and the 2, 1, 3-benzothiadiazole (BT) units at 418 nm and 531 nm, respectively [37]. When adding BN nanofibre to PFBT aqueous solution, no obvious variation of emission spectrum for PFBT aqueous solution can be observed. However, adding the saturated aqueous solution of carbon dioxide to the PFBT aqueous solution causes decrease of emission peak intensity at 418 nm and increase of emission peak intensity at 531 nm [40]. Moreover, after bubbling CO₂ to the PFBT and BN mixture, the emission spectra of the mixture show a similar variation trend compared with that of PFBT upon CO₂ bubbling, while the emission peak intensity was stronger than that of PFBT upon CO₂ bubbling. In order to investigate the influence of BN nanofibre on the fluorescence of PFBT, fluorescence spectra of BN nanofibre aqueous solution with a series of concentrations were measured. As indicated in Fig. 1a, in the presence of CO₂, the fluorescence of PFBT with BN was restored comparing to the control without BN. By adding BN, the left emission peak (418 nm) of the polymer PFBT gradually increased. The plot of the fluorescence intensityratio (I_{531 nm}/I_{418 nm}) of PFBT under a constant CO₂ concentration of 1.5 mmol/L was constantly reduced as a function of the BN concentration, indicating that the energy transfer from the fluorene to the BT moieties was decreased, which can be attributed to the capture of CO₂ by BN. (Fig. 1b) The fluorescence of polymer PFBT does not change as a function of the BN concentration, as illustrated in Fig. S1 (Supporting information). When adding different concentrations of CO₂ with BN concentration of 10.0 μg/mL, the left emission peak (418 nm) of the polymer PFBT was decreased by degrees and the right emission peak (531 nm) was improved (Fig. 1c).

Therefore, the fluorescence intensity ratio (I_{531 nm}/I_{418 nm}) of PFBT in the presence of increased CO₂ concentrations was constantly improved and reached the platform period when the CO₂ concentration reached 10 mmol/L. Fig. 1d, in the presence of CO₂ with BN or without BN, compared the curve of fluorescence resonance energy transfer (FRET) ratio, indicating that BN could capture CO₂, which prevents the formation of PFBT aggregates.

Many factors could influence the fluorescence intensity. As shown in the Fig. S3 (Supporting information), the different adding order of PFBT, BN and CO₂ can result in different formation of aggregates, causing fluorescence quenching of polymer PFBT. When BN was added at last, the fluorescence intensity slightly increases (Fig. S3a) and no significant fluorescence difference can be observed between the systems with different adding order of CO₂ and PFBT (Fig. S3b). However, the fluorescence of the assemblies significantly increases by adding samples with the order of BN/PFBT/CO₂, which can be attributed to the preference of BN to capture CO₂. Moreover, the other combination order shows little effect on the assembly, as well as little deference between the fluorescence intensity. (Fig. S3c)

Furthermore, we performed dynamic light scattering (DLS) and the ζ potentialsexperiment in aqueous solution to verify the controlled carbon dioxide capture by the assembly of PFBT and BN. As shown in Fig. 2, the average hydrodynamic radiusand ζ potential of PFBT, BN and PFBT/BN is approximately 200 nm and -30 mV. The PFBT and BN were dispersed in aqueous solution due to the strong electrostatic repulsion between side chains of PFBT and BN. (Figs. 2a and c) However, after bubbling CO₂, the ζ potential increased as the electrostatic repulsion between side chains of PFBT and BN was reduced, resulting to a larger average diameter. Notably, the significant increase in the average diameter of PFBT/BN suggests that CO₂ is capable for effective control of the PFBT and BN assembly. (Figs. 2b and c) Scanning electron microscopy (SEM) was performed to obtain more evidence of the controlled assembly of PFBT and BN by CO₂. As shown in Fig. 3, PFBT and BN were dispersed in the solution before bubbling CO₂. However, the polymer of PFBT accumulated on the surface of BN upon CO₂-bubbling, which is consistent with the DLS analysis, indicating the assemblies of PFBT and BN to be controlled by CO₂. In addition, Atomic force microscopic (AFM) also showed similar results. As shown in Fig. 4, PFBT and BN were well-dispersed with the topographic height of approximately 15 nm. After bubbling CO₂, the topographic height of the PFBT and BN assemblies were significantly enhanced to about 100 nm, demonstrating that PFBT and BN formed extraordinary aggregation at the existence of CO₂. This result is consistent with the DLS analysis and morphological representation of SEM, indicating that CO₂ is effective in controlling the assembly of PFBT and BN.

N₂ isothermal adsorption method was used to study the characteristics of the pore structure of PFBT/BN assembly without or with CO₂ [41]. As shown in Fig. 5, two samples showed typical IV isotherms, and no obvious hysteresis loops can be observed, indicating the existence of the microporous, mesoporous, and macroporous structure. There is a clear inflection point in the low relative pressure zone, which proves the existence of microporous structure. The porous structure of PFBT/BN is mainly attributed to BN nanofibers. The first inflection point of the N₂adsorption-desorption isotherms of PFBT/BN with CO₂ exhibits significant reduction than that without CO₂, suggesting that the number of micropores in the assembly decreased by bubbling CO₂. The curve of the relative high pressure zone shows a sharp rise, indicating the existence of macroporous structures. (Fig. 5a) The pore size distribution was calculated by quenched solid density functional theory (QSDFT) [38, 39], revealing a significant reduction of pore volume of PFBT/BN upon bubbling CO₂. In addition, the assemblies exist mainly in the form of mesoporous rather than the microporous structure upon CO₂-bubbling, demonstrating that PFBT and BN were clearly assembled under the existence of CO₂.

In conclusion, carbon dioxide-controlled PFBT/BN assembly was demonstrated by taking advantage of CO₂-responsive feature of the conjugated polymer of PFBT and the ability of capturing CO₂ of BN. CO₂ decreases the electrostatic repulsion between the functional group of PFBT and BN and increases hydrophobic interaction between PFBT and BN fiber, resulting in visible changes in fluorescence. Therefore, CO₂ can be used as effective trigger for the assembly of PFBT and BN fibers. Moreover, PFBT enables the assembly with the signal amplification and light-harvesting properties. Furthermore, the polymers can simply assemble into supermolecular aggregates by non-covalent interactions without complicated synthesis procedures. Therefore, it is expected that carbon dioxide can be used as a new trigger to construct intelligent conjugated polymer-based materials, offering fluorescence monitoring strategy for carbon dioxide capture.

Acknowledgments

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This work was supported by the National Natural Science Foundation of China (Nos. 21574037, 21773054 and 51803046), the "100 Talents" Program of Hebei Province, China (No. E2014100004), the Natural Science Foundation of Hebei Province (No B2017202051), the Program for Top 100 Innovative Talents in Colleges and Universities of Hebei Province (No. SLRC2017028).

Appendix A. Supplementary data

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Supplementary material related to this article can befound, in the online version, at doi:https://doi.org/10.1016/j.cclet.2019.03.037

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Year 2020 volume 31 Issue 1

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doi: 10.1016/j.cclet.2019.03.037

Receive Date：2019-02-25
Online Date：2026-01-28
Published：2020-01-15

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Received：2019-02-25
Revised：2019-03-19
Accepted：2019-03-21

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^a Institute of Biophysics, Hebei University of Technology, Tianjin 300401, China

^b Hebei Key Laboratory of Boron Nitride Micro and Nano Materials, Hebei University of Technology, Tianjin 300130, China

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表12种不同金属材料的力学参数

科 Family	属数 Number of genus	种数 Number of species	占总种数比例 Percentage of total species (%)	属 Genus	种数 Number of species	占总种数比例 Percentage of total species (%)
鹅膏菌科Amanitaceae	2	11	5.26	鹅膏菌属 Amanita	10	4.78
小菇科 Mycenaceae	2	12	5.74	丝盖伞属 Inocybe	5	2.39
多孔菌科 Polyporaceae	8	14	6.70	蜡蘑属 Laccaria	5	2.39
红菇科 Russulaceae	3	23	11.00	小皮伞属 Marasmius	6	2.87
				小菇属 Mycena	11	5.26
				光柄菇属 Pluteus	5	2.39
				红菇属 Russula	17	8.13
				栓菌属 Trametes	5	2.39

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Scheme 1 (a) Charge changes of PFBT upon bubbling with CO₂ and (b) Schematic representation of PFBT and BN were assembled under the control of carbon dioxide.

Fig. 1 Fluorescence emission spectra of PFBT in the presence of (a) CO₂ without and with BN. [CO₂] =1.5 mmol/L; (b) different concentrations of BN in aqueous solution with CO₂. [CO₂] =1.5 mmol/L. Inset: Plot of the fluorescence intensity ratio (I_{531 nm}/I_{418 nm}) of PFBT in the presence of different concentrations of BN in aqueous solution with CO₂. [CO₂] =1.5 mmol/L; (c) Different concentrations of CO₂ with BN. [BN] =10.0 μg/mL. (d) Plot of the fluorescence intensity ratio (I_{531 nm}/I_{418 nm}) of PFBT in the presence of different concentrations of CO₂ in aqueous solution without and with BN. [BN] =10.0 μg/mL, [PFBT] =10.0 μg/mL, the experimental temperature was 4 ℃. The excitation wavelength is 380 nm.

Fig. 2 Size and ζ potentials analysis of assemblies. Size of PFBT, BN and PFBT/BN in aqueous solution without (a) and with (b) CO₂. (c) ζ Potentials of PFBT, BN and PFBT/BN in aqueous solution without and with CO₂. [PFBT] =10.0 μg/mL, [BN] =10.0 μg/mL, the experimental temperature was 4 ℃.

Fig. 3 SEM images of (a) BN, (b) PFBT/BN and (c) PFBT/BN with CO₂ in aqueous solution at room temperature. [PFBT] = 5.0 μg/mL, [BN] = 5.0 μg/mL. Bubbling CO₂ at a constant flow rate of 1.0 mL/min for 30 min.

Fig. 4 Atomic force microscopic (AFM) images of (a) BN, (b) PFBT/BN and (c) PFBT/BN with CO₂. The line profiles of the aggregates are shown in the right. [PFBT] = 5.0 μg/mL, [BN] = 5.0 μg/mL. Bubbling CO₂ at a constant flow rate of 1.0 mL/min for 30 min.

Fig. 5 (a) Nitrogen adsorption-desorption isotherms of PFBT/BN without and with CO₂measured at -77 ℃, and (b) the pore size distribution plot of PFBT/BN without and with CO₂using the quenched solid density functional theory.

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