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Rational Design and Modification of High-k Bis(double-stranded) Block Copolymer for High Electrical Energy Storage Capability Jie Chen, Yuxin Wang, Hongfei Li, Huijing Han, Xiaojuan Liao, Ruyi Sun, Xingyi Huang, and Meiran Xie Chem. Mater., Just Accepted Manuscript • DOI: 10.1021/acs.chemmater.7b05042 • Publication Date (Web): 19 Jan 2018 Downloaded from http://pubs.acs.org on January 19, 2018
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Chemistry of Materials
Rational Design and Modification of High-k Bis(double-stranded) Block Copolymer for High Electrical Energy Storage Capability Jie Chen,† Yuxin Wang,‡ Hongfei Li,† Huijing Han,† Xiaojuan Liao,† Ruyi Sun,† Xingyi Huang,*,‡ and Meiran Xie*,† †
School of Chemistry and Molecular Engineering, East China Normal University, Shanghai 200241,
China ‡
Shanghai Key Laboratory of Electrical Insulation and Thermal Ageing, Shanghai Jiao Tong
University, Shanghai 200240, China
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ABSTRACT: High dielectric constant (high-k) polymers have important application in advanced electronic devices such as energy storage, wearable electronics, artificial muscles, and electrocaloric cooling, because of their excellent flexibility and ease of processing. However, most of the commercially available polymers have low k values and the designed strategies for enhancing k are usually at the cost of the increase of dielectric loss. In this work, novel high-k and low loss bis(double-stranded) block copolymers, containing the ionic-conjugated hybrid conductive segments (HCS) with narrow bandgap and the insulating segments with wide bandgap, were synthesized by tandem metathesis polymerizations. The novel copolymers exhibited enhanced dielectric constant of 33-28 accompanied with low dielectric loss of 0.055-0.02 at 102-106 Hz, and thus greatly increased stored energy density of 9.95 J cm-3 was achieved at relatively low electric field of 370 MV m-1, which is significantly higher than that of the commercially BOPP (about 1.6 J cm-3 at 400 MV m-1). In addition, by doping with I2, the k values of the HCS-contained block copolymer can further reach to 36.5-29 with low dielectric loss of 0.058-0.026, and the stored energy density maintained at high level of 8.99 J cm-3 at 300 MV m-1 with suitable I2 content. The excellent dielectric and energy storage capability were attributed to the unique macromolecular structure and well-defined nano-morphology, which not only enhanced the dipolar, electronic, and interfacial polarizations but also significantly suppressed the leakage current and increased the breakdown strength by wrapping the narrow bandgap segments in the wide bandgap segments.
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Chemistry of Materials
INTRODUCTION Polymers with high dielectric properties and good processability are of great interest because of their various applications in energy-storage devices1-5 and organic thin film transistors.6-11 However, for most of commercially polymers, the low dielectric constant (k < 10) and capacity density raise problem for practical applications because they are difficult to meet the requirement of high energy density or miniaturization of the energy storage devices.12,13 A simple method to increase the k value is to embed high-k nonconducting (barium titanate, strontium titanate, calcium titanate, etc.)14-17 or conductive (graphene, carbon black, metal, and so on)8,18-21 nanoparticle fillers to polymers. Composites incorporating the nonconducting nanoparticles typically require high filler loading to achieve significant increase in k value,14,22,23 while the nonconducting fillers easily reduce the polymers’ breakdown field strength due to the large k mismatch between the high-k filler and low-k polymer matrix,15 although this kind of composites is mostly considered in energy-storage devices. Alternatively, by use of the conducting fillers, the composites display high k value at low filler loading in comparison to those containing nonconducting fillers, because the electron conduction within the dispersed fillers leads to free charge buildup and interfacial polarization.8,19,24,25 The dielectric loss and leakage current can also be effectively inhibited by designing the gradient and layered nanostructures when the content of conducting filler is at a low level.26,27 Nonetheless, the highly conductive fillers usually incurs a serious leakage current when their loading close to the percolation threshold, resulting in the unacceptable high dielectric loss and extremely low breakdown voltage, which is not suitable for use in energy storage device. To resolve these issues such as high dielectric loss, low breakdown strength, sub-optimal stored energy density and efficiency of inorganic filler-contained polymer composites, some kinds of “all-polymer” approaches have been explored.28-32 Most attention has been focused on the use of various polar groups such as -F,33 -CN,34 and sulfone-containing moiety,7,9 which can significantly improve the dipole polarization of the non-ferroelectric polymers and increase k value. Especially, when the polar groups can be aligned coherently in one orientation, the dipole moments avoid to counteracted,35,36 which is beneficial to prepare high-k polymers. Importantly, the enhancement in k value is attained without any compromise in increasing dielectric loss and lowering breakdown strength. In addition to this, ionizing groups of polymer is also an effective way to increase the k value because organic ions have large dipole moments.4,37-40 Ionic polymers usually have the high k, but the high dielectric loss (> 0.5) mainly from the transport of ions over a long distance is not desirable for film capacitor applications.12 So, inhibiting ionic conduction is a basic premise to improve dielectric performance of ionic polymers. For example, a family of ionomers poly(4-methyl-1-pentene) containing -NH3Cl-1, -(NH3)2SO42- , or -(NH3)3PO43- side group, which ACS Paragon Plus Environment
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could connect with another positive charge carrier located on the inter- or intra-polymer chain to build a strong network structure and form a good segment stability, showed a high energy density (> 7 J cm-3 at 600 MV m-1), low dielectric loss (< 0.015), and high charge-discharge energy efficiency (> 93%).40 Recently, a class of “molecular composites” has been developed, in which the conductive π-conjugated segments are directly covalent-bonded to polymer chains,29,41-44 and the charge displacement within the conductive segments can produce interfacial polarization in electric field, ultimately resulting in large dielectric responses. For instance, 0-10 wt% of the oligoaniline octamer moiety was attached to the end of ferroelectric poly(vinylidene fluoride) for preparing a “dumbbell-shaped” copolymer to significantly increase the k value from 12 to 85 at 103 Hz,44 when the addition of oligoaniline octamer exceeded 10 wt%, the dielectric loss increased rapidly because of the electron conduction across the film probably; an all-polymeric nanodielectrics of polymethacrylate carrying terthiophene oligomers as side chains were reported by Tang, and these polymers displayed the k of 11, dielectric loss of 0.01-0.03, and energy density of 1.56 J cm-3 at 200 MV m-1,30 in which the side chains could self-assemble into conjugated, nanoscale, and electrically conductive domains dispersed in an insulating polymer matrix, leading to strong electronic and interfacial polarizations in the electric field. As a result, the dielectric properties, especially the dielectric loss and breakdown strength of all-polymeric “molecular composites” are better than the traditional composites containing inorganic filler, whereas the limited improvements are yet unsatisfactory. For the polymeric dielectrics, their dielectric properties can be predicted by using density functional theory in a high-throughput manner.45 Remarkably, Ramprasad has reported the relationship between the bandgap and the electronic and ionic k. With the decrease of bandgap, the electronic part of k value increased obviously, while the ionic part of k value is immune to the above trend, and the total k value is improved.46-49 The electronic part of k is suitable for applications in the sudden charge-discharge device due to the short timescales of this response, however, the too narrow bandgap usually leads to poor insulators in the high electric field, and the device is not safe. Therefore, it is a main task to find an optimal tradeoff between the total k value and the bandgap, and the ideal bandgap is about 3 eV.45,49 Polyacetylene (PA) is a kind of unique conducting polymers with a narrow bandgap of about 2 eV, and its electrical conductivity can be systematically and continuously tuned over a range of eleven orders of magnitude when doped with controlled amount of the halogens chlorine, bromine, or iodine (I2), and arsenic pentafluoride,50-54 which may have great application potential in all-polymeric “molecular composites” when it is wrapped in the wide bandgap insulating segments. Double-stranded polynorbornene (PNBE)55,56 and double-stranded PA57 with rigid multilayer planar oligoaryl linker have been synthesized, which have greater ACS Paragon Plus Environment
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resistance to irradiation and thermal and chemical degradation in comparison to their single-stranded counterparts, while they are usually known as low-k materials. When the dipolar and ionic groups were incorperated into the double-stranded PNBE or double-stranded PA, the k of block copolymers increased obviously, and the dielectric loss was also down to a low level as the block copolymers self-assembled into a well-defined nanostructure, whereas their energy density is still low (less than 3.0 J cm-3 at 245 MV m-1).58,59 Therefore, it is still a challenging task to develop the all-polymeric “molecular composites” for matching the requirement of polymeric dielectrics with high performance and reliability. Herein, we demonstrated a new type of all-polymeric “molecular composites” with an unprecedented bis(double-stranded) polymeric structure possessing the combined dipolar, electronic, and interfacial polarizations with the well-defined nano-morphology, in which the ionic-conjugated conductive segments with narrow bandgap were effectively wrapped by the insulating segments with wide bandgap to avoid the breakdown strength reducing for the narrow bandgap, thereby exhibiting excellent dielectric (k > 33 and dielectric loss < 0.03 at 102 Hz) and electrical energy storage capability (~ 9.95 J cm-3 at 370 MV m-1). It affords a general strategy for “structure design—morphology control—property tune” toward the high performance all-polymeric “molecular composites” dielectrics. RESULTS AND DISCUSSION Synthesis and Characterization of Bis(double-stranded) Block Copolymers. In order to further enhance the k and energy density, we designed the novel bis(double-stranded) block copolymer containing two different double-stranded ionic PNBE and conjugated PA segments, and successfully prepared
the
conductive
conductive-insulating
diblock
tetrablock
copolymer
PBNPF30-b-PBHPF30,
copolymers
and
the
derived
PBNPF30-b-PBHPF30-(b-PTNP100)2
and
56
PBNPF30-b-PBHPF30-(b-PTNP200)2, via the third-generation Grubbs catalyst -initiated tandem ring-opening metathesis polymerization (ROMP) of N-3,5-bis(trifluoromethyl)biphenyl-norbornene pyrrolidine (TNP)36 and bis[(norbornene pyrrolidinium hexafluorophosphate) phenyl] perylene 2,3,6,7-tetra[bis(trifluoromethyl) cyclopolymerization
(MCP)
phenyl] of
bisimide
(BNPF),58
as
well
bis(4-methoxyl-1,6-heptadiyne)
as
metathesis perylene
2,3,6,7-tetra[bis(trifluoromethyl) phenyl] bisimide (BHPF)59 by precisely tuning the structure of each monomer and optimizing the polymerization conditions (Scheme 1). The synthetic procedures and structure characterization of block copolymers were fully presented in the Supporting Information (SI), Table S1, and Figures S1-S4. The results indicated that monomers were completely converted into the anticipated bis(double-stranded) polymer structures. More importantly, 13C NMR analysis showed that the signals of acetylenic carbons on 1,6-heptadiyne of BHPF disappeared
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wholly after MCP. If the second double-stranded PBHPF skeleton was not formed effectively by MCP, the inevitably signals of acetylenic carbons should be appeared in NMR spectra, while the corresponding signals of acetylenic carbons were not found in Figures S3c and S3d, meaning that there was no triblock polymer structure formed as depicted in Scheme S1. In this new type of all-polymeric “molecular composites”, the ionic PBNPF, conjugated PBHPF, and insulating PTNP segments were covalent-bonded in one polymeric backbone, and the conjugated PBHPF can be further modified by doping with I2. Therefore, the block copolymers possessing strong dipolar, electronic, and interfacial polarizations are envisioned to achieve high k, low dielectric loss, high breakdown strength and energy density, and good charge-discharge efficiency. Scheme 1. Synthetic Protacol (a) and the Cartoon Representations for Conductive-Insulating Structure (b) of Bis(double-stranded) Block Copolymers
Nanostructure and Morphology of Block Copolymer Assembly. The block copolymer films made from the solution in different solvents possess various morphology of nanostructures, and the regular morphology may endow the block copolymer films with better dielectric and energy storage properties than the irregular morphology of block copolymer.58-62 The block copolymer containing conductive-insulating segments with regular morphology would have the potential to produce substantially higher breakdown strength and better insulation properties, because the formed regular
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conductive nano-domain can possess larger interacting areas with the insulating matrix than micro-sized domain,28-30 offering greater possibilities to tailor and optimize the properties of all-polymeric “molecular composites”. Therefore, the morphology of the block copolymer films formed by the solvent evaporation in air was investigated by TEM analysis, and used to evaluate the dielectric and energy storage properties of copolymer. TEM image showed that the copolymers PBNPF30-b-PBHPF30 and PBNPF30-b-PBHPF30-(b-PTNP100)2 mostly gathered to form the morphology of irregular nanoshape with the diameters of 100-300 nm and 60-150 nm in CHCl3 (Figures 1a, 1c, S5a, and S5c), respectively. In constant, by changing the solvent to THF, PBNPF30-b-PBHPF30 formed the regular solid nanosphere morphology with an average diameter of 95 nm (Figures 1b and S5b), and PBNPF30-b-PBHPF30-(b-PTNP100)2 formed a regular hollow nanosphere morphology with an average diameter of 40 nm (Figures 1d and S5d), which was attributed to the self-assembly of block copolymers driven by both the solubility discrepancy of different segments (Table S2) and the π-π stacking interaction between the bis(double-stranded) PBNPF-b-PBHPF blocks with large aromatic PBI linkers closed to each other. As a result, the partially soluble hybrid conductive segments (HCS) of ionic PBNPF and conjugated PBHPF with narrow bandgap (2.08-1.92 eV) were away from solvent due to the poor solubility in THF and self-assembled into the unique “hybrid conductive domain (HCD)” as the core, meanwhile, the good soluble insulating PTNP segments with wide bandgap (3.26 eV) self-assembled as the shell, and finally the hollow nanosphere morphology was generated to lower the surface energy, where the HCD core was wrapped by the insulating shell, as shown in Scheme S2. Importantly, comparing the irregular
nanoshape
in
CHCl3
with
the
regular
hollow
nanosphere
in
THF
for
PBNPF-b-PBHPF-(b-PTNP)2, the latter should provide a beneficial effect that the HCD was isolated between the insulated segment assembly, which effectively decreased the leakage current and dielectric loss. It is worthy to note that some block copolymers performing the induced self-assembly process in selective solvents don’t need any post-treatments, and various nanostructures can be pre-designed to acquire optimal dielectric properties by changing the solvent or composition of chain segments, which is much convenient method for preparing the required nanodielectric polymers in comparison to that preparation of conventional nanocomposites by the in situ polymerization of monomers on initiator-functionalized inorganic nanoparticle surfaces.15
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Figure 1. TEM images of PBNPF30-b-PBHPF30 (a,b) and PBNPF30-b-PBHPF30-(b-PTNP100)2 (c,d) in CHCl3 (a,c) and THF (b,d) at 0.01 mg mL-1. Further insight into the nanostructures of self-assembled copolymer formed in solution was conducted by dynamic light scattering (DLS) technique, and verified the aggregates existed in solution with different number-average hydrodynamic diameter (Dh). All the size values of copolymers with the self-assembled nanostructures were listed in Table S3. The self-assembly behavior and the self-assembled nanostructure size distribution of PBNPF30-b-PBHPF30, PBNPF30-b-PBHPF30-(b-PTNP100)2, and PBNPF30-b-PBHPF30-(b-PTNP200)2 in different solvents at varied concentrations (0.005-0.02 mg mL-1) were revealed details in the SI, and the results showed that the copolymers displayed an enhanced self-assembly ability and homogeneous size of nanostructures in THF with the dominating Dh of 42-102 nm comparing with those in CHCl3 with the Dh of 67-265 nm, as shown in Figure S6, which were basically larger than those of the self-assembled nanostructure size of copolymers in dried state tested by TEM analysis. The self-assembly capability of selected PBNPF30-b-PBHPF30-(b-PTNP200)2 in CHCl3 and THF at the concentration of 150 mg mL-1 was also investigated by DLS, as shown in Figure S7, there was a distinct peak with a dominating Dh of 170 nm for the assembly by π-π stacking in CHCl3, and a little number of single-molecule chains with a Dh of 17 nm were still existed. For comparison, there have two peaks with the Dhs of 100 nm for single assembly and 300 nm for combined several assemblies driven by the π-π stacking and solubility discrepancy between the constituent blocks in THF at high concentration of 150 mg mL-1, as shown in Scheme S2. The number and size of combined several
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assemblies were significantly higher than those of the assemblies at low concentration, because the distance between the assemblies decreased and the π-π stacking interaction kept them closely. To prove the morphology of copolymer film was composed of the self-assembled nanostructures in the dried state, the copolymer PBNPF30-b-PBHPF30-(b-PTNP200)2 was selected as a representative to reveal the self-assembled nanostructures at so high concentration of 150 mg mL-1 as the film preparation for dielectric measurement. The scanning electron microscope (SEM) was used to observe the fractured surface to elucidate the morphology of polymer film. The fractured surfaces of the PBNPF30-b-PBHPF30-(b-PTNP200)2 films were obtained by using an external force to break polymer film and their morphologies were showed in Figure S8. For the copolymer film made from CHCl3 solution, the irregular nanoshapes with the diameters of 70-120 nm were found on the fractured surface (Figures S8a-c), which was basically consistent with the self-assembled nanostructures by TEM (Figure 1c). For the copolymer film made from THF solution at high concentration, the relatively regular nanosparticles with the size of 60-80 nm were observed, and the size was slightly larger than that of the hollow nanosphere by TEM (Figure 1d) at low concentration, which was in agreement with that the size of the single nanosparticle in solution by DLS (Dh = 100 nm) was somewhat larger than that in dried state tested by SEM. Differently, there have some bright nanoparticles and dark or sunken nanoparticles, and all the nanoparticles were closely aligned on the fractured surface (Figures S8d-f), in which the bright nanoparticles are indicative of hardness and strongness for these tightly aggaregated regular nanostructures, similar with that of inorganic fiber embedded in the polymer matrix. Whereas, the large self-assembled nanostructures with the Dh of 300 nm in THF by DLS were not observed by SEM, this was because that the detected large nanostructures by DLS were the combined several hollow nanospheres, which were loosely aggaregated by the π-π stacking interaction, as shown in Scheme S2. Therefore, it could be concluded that the self-assembled nanostructures were indeed existed in polymer film and clearly observed by SEM, which is very important and relevant for the dielectric properties of polymer films. Dielectric Properties of Block Copolymer Films. High k and low loss are important indicators of high performance dielectric materials. All the k and dielectric loss of block copolymers with different nanostructured morphologies were listed in Table S4. Bis(double-stranded) diblock copolymer PBNPF30-b-PBHPF30 displayed enhanced k of 36-30 in CHCl3 (Figure 2a) or 35.0-31.5 in THF (Figure 2c) compared to the corresponding solely ionic PBNPF (33-26)58 or conjugated PBHPF (17.5) homopolymer,59 but accompanied with high dielectric loss of 0.25-0.15 in CHCl3 (Figure 2b) or 0.27-0.13 in THF (Figure 2d) as frequency varied from 102 Hz to 106 Hz, most likely as the serious conduction,17 which made the HCS PBNPF-b-PBHPF hard to meet the demand for fast ACS Paragon Plus Environment
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discharge film capacitor, so it should be improved using insulated segments to decrease the dielectric loss of ionic-conjugated copolymers by inhibiting the ion or electron conduction and mobility.37,38,53 Expectedly, when the insulated PTNP segments bonded to the HCS PBNPF-b-PBHPF forming the derived
tetrablock
copolymers
PBNPF30-b-PBHPF30-(b-PTNP100)2
and
PBNPF30-b-PBHPF30-(b-PTNP200)2, they still exhibited high k values of 32-27.5 and 31-27 in CHCl3 with irregular nanostructure (Figure 2a), as well as 32.5-28.0 and 31.0-27.5 in THF with a regular nanostructure (Figure 2c), respectively; while the dielectric losses decreased obviously to 0.09-0.05 and 0.04-0.03 in CHCl3 (Figure 2b) as well as 0.055-0.05 and 0.035-0.02 in THF (Figure 2d), respectively, due to the contribution from the strong dipolar, electronic, and positive interfacial polarizations28-30 combined with a regular nanostructure morphology by inhibiting the ion and electron conductions, which should be benefit for practical applications. More importantly, all the HCS-contained block copolymers exhibited higher k than that of any homopolymer,36,58,59 meaning that using the nanoscale HCS composed of both ionic PBNPF and conjugated PBHPF segments with narrow bandgap was an effective strategy to increase the k of polymers. The results implied that the block copolymers with the HCD-contained regular nanostructure morphology could improve the dielectric properties, because the regular hollow nanosphere morphology provided a beneficial effect that the HCD with narrow bandgap was isolated between the insulating shell with wide bandgap to decrease the leakage current, and bringing two nanoscale interface polarizations in the electric field, as shown in Figure 3 and Scheme S3, which effectively improved the dielectric performance. 40
0.30
(a)
PBNPF30-b-PBHPF30
30
Dielectric loss
PBNPF30-b-PBHPF30-(b-PTNP200)2
35
(b)
PBNPF30-b-PBHPF30
0.25
PBNPF3--b-PBHPF30-(b-PTNP100)2
Dielectric constant
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
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PBNPF30-b-PBHPF30-(b-PTNP100)2 PBNPF30-b-PBHPF30-(b-PTNP200)2
0.20 0.15 0.10 0.05
25 2
10
3
10
4
10
5
10
10
6
0.00
10
2
3
10
Frequency / Hz
10
4
Frequency / Hz
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10
6
10
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40
0.30
(c) PBNPF30-b-PBHPF30
(d) PBNPF30-b-PBHPF30
0.25
PBNPF30-b-PBHPF30-(b-PTNP100)2
PBNPF30-b-PBHPF30-(b-PTNP100)2
35
PBNPF30-b-PBHPF30-(b-PTNP200)2
Dielectric loss
Dielectric constant
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
Chemistry of Materials
30
0.20
PBNPF30-b-PBHPF30-(b-PTNP200)2
0.15 0.10 0.05
25
10
0.00 2
3
10
10
4
10
5
6
2
10
10
3
10
10
4
10
5
10
6
Frequency / Hz
Frequency / Hz
Figure 2. Dielectric constant (a,c) and dielectric loss (b,d) of polymer films from CHCl3 (a,b) and THF (c,d) solution.
PBNPF PBHPF PTNP
~ Figure 3. Schematic illustrations of the PBNPF-b-PBHPF-(b-PTNP)2 capacitor device.
Cu polymer film SiO2
all-polymeric
“molecular
composites”
The dielectric properties of “molecular composites” are affected by the conductivity of nanometer domains.29,41-43 The electrical conductivity of PA could be tuned over a range of eleven orders of magnitude by doping.51-53 In order to further improve the dielectric properties of nanoscale HCD-contained “molecular composites”, PBNPF30-b-PBHPF30-(b-PTNP200)2 was selected as a representative for doping with various amount of I2 (Scheme S4) to form the conductive PA nanometer domain, which can enhance the electronic and nano-interface polarizations. Figure 4 presented the k and dielectric loss of copolymer PBNPF30-b-PBHPF30-(b-PTNP200)2 films with different I2 content. Figures 4a and 4c clearly showed the increase in k with the raised content of I2. When the copolymer contained various I2 content from 2.5 to 100 mol%, the k value increased in sequence from 33.5 to 43.0 at 102 Hz, as well as from 27.9 to 33.6 at 106 Hz (Table S5), which were higher than the common commercial polymer dielectric materials. The great enhancement in k for the copolymer is attributed to their fraction of I2 doping. The k increased fast below 10 mol% of I2 and then slow above 20 mol% of I2 (Figure 4c), indicating the I2-doped PA as the HCD content was ACS Paragon Plus Environment
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closed to the threshold.1 50
(a)
0.10 0 mol% 10 mol% 60 mol%
2.5 mol% 20 mol% 80 mol%
5 mol% 40 mol% 100 mol%
40 35
0 mol% 10 mol% 60 mol%
2.5 mol% 20 mol% 80 mol%
5 mol% 40 mol% 100 mol%
0.06 0.04 0.02
30 25 2 10
50
(b)
0.08
Dielectric loss
Dielectric constant
45
10
(c)
3
4
10 Frequency / Hz
10
5
10
6
0.00 2 10
0.08
100 Hz 1 MHz
45
10
3
4
10 Frequency / Hz
10
(d)
5
6
10
100 Hz 1 MHz
0.06 Dielectric loss
Dielectric constant
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
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40 35 30 25 0
20
40 60 I2 content (mol%)
80
100
0.04
0.02
0.00 0
20
40 60 I2 content (mol%)
Figure 4. Dielectric constant (a,c), and dielectric loss (b,d) of PBNPF30-b-PBHPF30-(b-PTNP200)2 films with different I2 content from THF solution.
80
100
copolymer
All the I2-doped copolymer films exhibited higher k than that of corresponding undoped copolymer PBNPF30-b-PBHPF30-(b-PTNP200)2 (Table S5 vs Table S4), because the electronic and interfacial polarizations had a great enhancement when the high conductive PA nanometer domain was constructed after I2 doping. The interfacial polarization displayed mostly the outstanding contribution to increase k. For PBNPF30-b-PBHPF30-(b-PTNP200)2 with different I2 content, the main polarizations are dipolar, electronic, and interfacial polarizations. When the frequency was at a low range of 102-105 Hz, the dipolar, electronic, and interfacial polarizations could respond to the electric field in time and function together; while the frequency was over 105 Hz, the interfacial polarization could not catch up, and the curves of k showed a slump. The dielectric loss values of all copolymer films were staying at a reasonable low level of 0.058-0.026 in a wide frequency range of 102-106 Hz. As the I2 content increasing, the dielectric loss value slightly increased from 0.04 to 0.058 at 102 Hz, as well as from 0.026 to 0.03 at 106 Hz (Figures 4b and 4d). Besides, when the I2 content was less than 60 mol%, the dielectric loss of copolymer films remained a gentle increase
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with the increase in I2 content at the frequency range; when the I2 content was over 60 mol%, the loss at 3×102-105 Hz increased obviously (Figure 4b), which should be attributed to the serious dark current of excess I3- ions. According to the literature,64 the molecular I2 dissociate in PA matrix to form I+ and I3- as shown in Scheme S5. The formation of a complex of this I+ with the conjugated double bond stabilized the cations, and the corresponding generated I3- was dispersed around the cations. Because the ions around PA segment was isolated between the insulating shells, the increase value of dielectric loss was not obvious when the anion content held a low level. As the increase of I2 content, more and more I3- were generated. When the I3- ions exceeded the critical value, the shielding effect of current became weaker and the leakage current became larger, resulting in an increased dielectric loss. Leakage Current Density of Block Copolymers. The insulating behavior is an important character of dielectric materials, and the leakage current density is a great factor to affect the dielectric properties of polymer.15 The PBNPF30-b-PBHPF30 film made from CHCl3 solution was easy to be penetrated at the applied electric field of above 40 MV m-1, and its maximum leakage current density exceeded 1.4×10-6 A cm-2 at 40 MV m-1 (Figure 5a). As expected, the maximum leakage current densities of the PBNPF-b-PBHPF-(b-PTNP)2 films with mostly irregular shape in CHCl3 decreased to 1.3×10-6 and 3.8×10-7 A cm-2 at 100 MV m-1 with the elongated insulating PTNP block length due to the lowered mass concentration of HCD. For comparison, the PBNPF30-b-PBHPF30 film with the self-assembled solid sphere nanostructure in THF was penetrated at the electric field of above 50 MV m-1 because the ionic blocks were isolated, and the maximum leakage current density was about 1.6×10-6 A cm-2 at 50 MV m-1 (Figure 5b); the corresponding PBNPF-b-PBHPF-(b-PTNP)2 films with the self-assembled regular hollow sphere nanostructure in THF displayed the lowered leakage current densities of 1.8-1.2×10-7 A cm-2 at 100 MV m-1, implying that the well-defined hollow nanosphere could reduce the leakage current and improve the dielectric properties of block copolymers, which did have an obvious influence on the dielectric loss and energy efficiency. The leakage current densities of copolymers followed a reasonable increasing trend with the raise of applied electric field. The resistivity calculated from the I-V characteristics is of 1010-1013 Ω·cm, which was consistent with the conductivities of the films under increased frequency (Figure S7). Namely, they had an excellent insulating property and qualified for the practical
applications.
Intuitively,
the
maximum
leakage
current
densities
of
the
PBNPF30-b-PBHPF30-(b-PTNP200)2 films containing 2.5 and 5 mol% doped I2 was 1.7×10-7 and 2.6×10-7 A cm-2 at 100 MV m-1 (Figure 5c), respectively, which was not significantly higher than that of undoped copolymer. With the I2 content increasing, the maximum leakage current densities of
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copolymer films containing 10, 20, 40, 60, 80, and 100 mol% I2 were up to 5.8×10-7, 8.2×10-7, 1.4×10-6, 2.9×10-6, 5.8×10-6, and 9.2×10-6 A cm-2 at 100 MV m-1 in sequence, and they were 5-75 times higher than that of undoped copolymer, which did have an obvious influence on the maximum breakdown filed and energy density. So, the investigation of the electrical energy storage properties was focused on the block copolymer films containing the optimal doped I2 content (≤ 5 mol%).
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-5
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2.5 mol% 10 mol% 40 mol% 80 mol%
-6
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Figure 5. Leakage current density of the films made from block copolymers in CHCl3 (a), THF (b), and the PBNPF30-b-PBHPF30-(b-PTNP200)2 film with different I2 content in THF (c) at varied applied electric fields. Electrical Energy Storage Properties of Block Copolymers. The linear polarization behavior and low hysteresis observed for polymers were indicative of the low level of energy dissipation, which was in agreement with the low dielectric loss in the impendence test.1,13,65 Predictably, the hysteresis loop with dipole saturation of HCS PBNPF30-b-PBHPF30 was wide at high electric fields due to the serious leakage current, the ion and electron migrations were responsible for the hysteresis, which was a disadvantage in thin film capacitors, and the maximum polarization of HCS PBNPF30-b-PBHPF30 with a regular solid sphere nanostructure in THF was lowered to 0.45 µC cm-2 at 50 MV m-1. The hysteresis loops of conductive copolymers could be effectively narrowed by lengthening the insulating PTNP blocks, because the ion and electron migrations were restrained. As expectation, insulating segments-bonded HCS of PBNPF30-b-PBHPF30-(b-PTNP100)2 and PBNPF30-b-PBHPF30-(b-PTNP200)2 with well-defined hollow nanosphere in THF displayed narrower hysteresis loops, and thus their maximum polarizations were reached up to 4.25 µC cm-2 at 350 MV m-1 and 4.59 µC cm-2 at 370 MV m-1 (Figures S12d-f), respectively. These maximum polarizations had a strengthened change compared to those (0.22 µC cm-2 at 30 MV m-1, 2.95 µC cm-2 at 250 MV m-1, and 4.08 µC cm-2 at 330 MV m-1, respectively) of the corresponding copolymers with irregular nanostructure in CHCl3 (Figures S12a-c), indicating that the well-defined nanostructure affected the maximum polarization and narrowed the hysteresis loops of conductive-insulating
copolymers
in
a
certain
extent,
because
the
hybrid
conductive
PBNPF-b-PBHPF segments were effectively wrapped by the insulating PTNP segments, and thus
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Chemistry of Materials
decreased the leakage current densities and improved the interfacial polarization, which was in good agreement with low dielectric loss. Figures
S13a,b
and
S14a
showed
the
D-E
loops
of
the
selected
copolymer
PBNPF30-b-PBHPF30-(b-PTNP200)2 films with the optimal doped I2 content measured at 102 Hz under varying electric fields at room temperature. High electric displacement was observed for the copolymer films resulting from their high k, which should be favorable for high energy density (Table S5). After doping with different amount of I2, the maximum polarizations for the copolymer films increased, while their breakdown field was descended, because of their raised conductivity (Figure S9c) and leakage current density (Figure 5c). By doping with 2.5 and 5 mol% of I2, the maximum polarizations of copolymer films were up to 5.09 µC cm-2 at 320 MV m-1 and 5.39 µC cm-2 at 300 MV m-1, respectively, which were higher than the undoped copolymer film (4.59 µC cm-2 at 370 MV m-1) even if the breakdown field fell (Figure S14b). Obviously, when considering the electric field remained at 300 MV m-1, their polarizations were still ascended as the doped I2 content increased; in other words, the copolymer films with higher I2 content should have higher stored energy density under the same given electric filed. Low remnant polarization and high energy storage efficiency can be expected because of narrower hysteresis loops.7 For energy storage dielectric materials, high energy density is the basic requirement for polymer dielectrics with high electrical energy storage performance, which came from three aspects: high breakdown field, high electric displacement, and last but not least, high energy efficiency.14,15,65,66 The energy density (Ue) of a capacitor was given by the equation: Ue = ʃE(dD),12 where E and D were the applied electric field and electric displacement, respectively. According to this equation, the stored energy density (Us) or released energy density (Ur) of polymers as a function of the maximum electric field strength could be obtained by integrating the charge or discharge curve of the D-E loop. The charge-discharge efficiency (η) was given by the equation: η = (Ur/Us)×100%. The dissipative energy during the charge-discharge cycle was a disadvantage in applications, and thus needs to be avoided. For the nanoscale HCD-contained block copolymer films with irregular nanostructure in CHCl3, the Us/Ur and η were of 0.05/0.02 J cm-3 and 40.0% for PBNPF30-b-PBHPF30 at 30 MV m-1 (Table S4), which were even lower than those (0.29/0.20 J cm-3 and 68.9% at 79 MV m-1) of ionic PBNPF,58 owing to the severe current leakage of HCD. The Us/Ur and η increased obviously to 4.67/2.97 J cm-3 and 63.6% for PBNPF30-b-PBHPF30-(b-PTNP100)2 at 250 MV m-1, as well as 6.83/5.60 J cm-3 and 81.9% for PBNPF30-b-PBHPF30-(b-PTNP200)2 at 330 MV m-1 (Figures 6a-c and S15).
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0.12 0.08 0.04 0.00
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0
50
100
150 200 250 300 Electric field (MV/m)
350
400
0
50
100
150 200 250 300 Electric field (MV/m)
Figure 6. Energy density versus applied electric field for polymer films from PBNPF30-b-PBHPF30 (a,d), PBNPF30-b-PBHPF30-(b-PTNP100)2 (b,e), and PBNPF30-b-PBHPF30-(b-PTNP200)2 (c,f) in CHCl3 (a-c) and in THF (d-f). For block copolymer films with the well-defined nanostructures in THF, the Us and Ur were low as 0.17 and 0.07 J cm-3 for PBNPF30-b-PBHPF30 at 50 MV m-1 (Table S4). Surprisingly, the Us and Ur were up to 9.49 and 6.18 J cm-3 for PBNPF30-b-PBHPF30-(b-PTNP100)2 at 350 MV m-1, even further to 9.95 and 8.33 J cm-3 for PBNPF30-b-PBHPF30-(b-PTNP200)2 at 370 MV m-1 (Figure 6d-f), which were of high-level in the dielectric polymer family and much higher than those of similar polymers (Us < 3.0 J cm-3 at 245 MV m-1);58,59 their η values were 44.6, 65.1, and 83.7% separately (Figure S15). These data were better than those of corresponding copolymer films with irregular nanostructure in CHCl3, because the narrow bandgap segments were isolated by the wide bandgap segments in the well-defined nanostructure, resulting in a higher breakdown strength, which displayed a positive contribution to improve Ur and η. Besides, as the insulating PTNP block length increasing, the corresponding η was improved, which was in agreement with the lowered dielectric loss of copolymers. For the I2-doped copolymer films, they exhibited the decreased Us/Ur and breakdown field of 8.79/7.52 J cm-3 and 320 MV m-1 with 2.5 mol% I2, as well as 8.99/7.70 J cm-3 and 300 MV m-1 with 5 mol% I2 (Figures 7a and S16a,b), respectively, compared to the undoped copolymer film (9.95/8.33 J cm-3 and 370 MV m-1) (Table S5). Although the maximum Us/Ur and the breakdown field were declined basically as the increase in I2 content, the representative Us/Ur values of I2-doped copolymer films at a certain electric field were still higher than those of undoped copolymer film, for example,
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they were 7.72/6.63 J cm-3 with 2.5 mol% I2 or 8.99/7.70 J cm-3 with 5 mol% I2 at 300 MV m-1, higher than 5.80/4.89 J cm-3 with 0 mol% I2 at 300 MV m-1 (Figure 7b, or S16i), which were of high-level in the polymeric dielectric substance and greatly exceeded the best commercially available BOPP dielectrics (1.6 J cm-3 at 400 MV m-1).7,30,62 (b)
8 6 4
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Chemistry of Materials
0.0
2.5 I2 content (mol%)
5.0
Figure 7. Stored energy density versus applied electric field (a) and energy density versus I2 content (b) for I2-doped PBNPF30-b-PBHPF30-(b-PTNP200)2 films from THF solution. Importantly, compared to those previously reported “molecular composites” containing dodecylbenzenesulfonic acid, camphorsulfonic acid, or HCl-doped oligoaniline,29,41,42 the I2 dopant has its distinctive merit for doped copolymer films. Usually, the protonic acid could drastically reduce the breakdown field and η despite of a low doping content due to the harmful ionic polarization, which limited frequency response of the capacitors. While I2 as a non-proton dopant had little effect on the breakdown field and η at low doping content, which were mainly affected by the leakage current. Therefore, the main aim could be focused on reducing the leakage current of polymers. The covalent-linkage between the conductive and insulating moieties and constructing a unique nanostructure could be of benefit to reduce the leakage current. The conductive I2-doped PA and ions (nanoscale HCD) were wrapped in the core of hollow nanosphere, and their η values were relatively high, which were 85.6 and 85.7% with the I2 content of 2.5 and 5 mol% (Table S5), respectively. Finally, comparing with some previous all-polymeric dielectrics,9,32,33,49,67-75 the energy densities
versus
efficiencies
of
the
nanoscale
HCD-contained
copolymer
PBNPF30-b-PBHPF30-(b-PTNP200)2 films without or with 2.5 and 5 mol% of I2 showed a combination of high energy density and efficiency level (Figure 8), which seems to be better candidates for dielectric materials in comparison to the reported most polymer dielectrics.
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100 90
Commercial BOPP
ArPTU [75]
PTTEAM [30]
P(DMTSub) [69] PMP-(NH ) PO 3- [40] 3 2 4 PMMA [9]
Efficiency (%)
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
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80
PET/PMMA/P(VDF-HFP) multilayer [67] PDMTGlu [66]
This work
P(VDF-TrFE-CTFE)-g-PEMA [74]
70
PC/PVDF multilayer [73] P(VDF-TrFE-CTFE)-g-PS [71] P(VDF-HFP)-g-PDMA [31]
60
DNA-CTMA [70]
50
Stretched P(VDF-HFP) [72]
40 0
2
4 6 3 Energy density (J/cm )
8
10
Figure 8. Energy density versus efficiency of PBNPF30-b-PBHPF30-(b-PTNP200)2 at 370 MV m-1, PBNPF30-b-PBHPF30-(b-PTNP200)2 with 2.5 mol% I2 at 320 MV m-1, PBNPF30-b-PBHPF30-(b-PTNP200)2 with 5 mol% I2 at 300 MV m-1, and some other polymer dielectrics at 400 MV m-1 in previous literatures. CONCLUSIONS By
rational
design,
a
novel
all-polymeric
“molecular
composites”
of
HCS-contained
bis(double-stranded) conductive-insulating block copolymer PBNPF-b-PBHPF-(b-PTNP)2 was synthesized, and self-assembled into HCD-contained regular nanostructure with the strong dipolar, electronic, and interfacial polarizations, as well as the good film-forming property (Figure S19). The block copolymer with the regular hollow nanosphere morphology exhibited high k value of about 30, low dielectric loss of 0.02, and excellent stored/released energy density of 9.95/8.33 J cm-3 with good charge-discharge efficiency of 83.7%, which were superior to those of the same copolymers with irregular nanostructure, and also better than those of any ionic or conjugated polymers. After doping with suitable amount of I2, the k value of block copolymer films can further reach up to 34 with low dielectric loss of 0.03, and the stored/released energy density maintained at 8.99/7.70 J cm-3 with better charge-discharge efficiency of 85.7%. Therefore, the proposed HCS polymer structure, multiple polarizations, and well-defined nano-morphology can drastically enhance the dielectric properties and improve the application potential of polymer films in energy storage devices. ASSOCIATED CONTENT Supporting Information The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acs.chemmater. xxxxxxx. Full experimental procedures, characterization, and related discussion; Tables; Schemes; GPC traces; UV-vis, IR, and NMR spectra; DLS diagrams, TEM and SEM images; D-E loops;
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conductivity, dielectric constant and loss at different temperatures, energy density, and charge-discharge efficiency curves; TGA and DSC curves; stress-strain curves; photographs. AUTHOR INFORMATION Corresponding Authors *E-mail:
[email protected] (M.X.). *E-mail:
[email protected] (X.H.). Funding This research was financially supported by the National Natural Science Foundation of China (No. 21574041, 21704025, and 21374030) and the Large Instruments Open Foundation of East China Normal University (No. 20162042). Notes The authors declare no competing financial interest. REFERENCES (1) Prateek; Thakur, V. K.; Gupta, R. K. Recent Progress on Ferroelectric Polymer-Based Nanocomposites for High Energy Density Capacitors: Synthesis, Dielectric Properties, and Future Aspects. Chem. Rev. 2016, 116, 4260-317. (2) Yang, K.; Huang, X.; He, J.; Jiang, P. Strawberry-like Core–Shell Ag@Polydopamine@BaTiO3 Hybrid Nanoparticles for High-k Polymer Nanocomposites with High Energy Density and Low Dielectric Loss. Adv. Mater. Interfaces 2015, 2, 1500361-1500371. (3) Wang, Y.; Cui, J.; Yuan, Q.; Niu, Y.; Bai, Y.; Wang, H. Significantly Enhanced Breakdown Strength and Energy Density in Sandwich-Structured Barium Titanate/Poly(vinylidene fluoride) Nanocomposites. Adv. Mater. 2015, 27, 6658-6663. (4) Zhu, L. Exploring Strategies for High Dielectric Constant and Low Loss Polymer Dielectrics. J. Phys. Chem. Lett. 2014, 5, 3677-3687. (5) Zhu, L.; Wang, Q. Novel Ferroelectric Polymers for High Energy Density and Low Loss Dielectrics. Macromolecules 2012, 45, 2937-2954. (6) Li, Q.; Chen, L.; Gadinski, M. R.; Zhang, S.; Zhang, G.; Li, H.; Haque, A.; Chen, L.-Q.; Jackson, T.; Wang, Q. Flexible high-temperature dielectric materials from polymer nanocomposites. Nature 2015, 523, 576-579. (7) Wang, Y.; Huang, X.; Li, T.; Wang, Z.; Li, L.; Guo, X.; Jiang, P. Novel crosslinkable high-k copolymer dielectrics for high-energydensity capacitors and organic field-effect transistors ACS Paragon Plus Environment
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applications. J. Mater. Chem. A 2017, 5, 20737-20746. (8) Toor, A.; So, H.; Pisano, A. P. Improved Dielectric Properties of Polyvinylidene Fluoride Nanocomposite Embedded with Poly(vinylpyrrolidone)-Coated Gold Nanoparticles. ACS Appl. Mater. Interfaces 2017, 9, 6369-6375. (9) Wei, J.; Zhang, Z.; Tseng, J. K.; Treufeld, I.; Liu, X.; Litt, M. H.; Zhu, L. Achieving High Dielectric Constant and Low Loss Property in a Dipolar Glass Polymer Containing Strongly Dipolar and Small-Sized Sulfone Groups. ACS Appl. Mater. Interfaces 2015, 7, 5248-5257. (10) Ponce Ortiz, R.; Facchetti, A.; Marks, T. J. High-k Organic, Inorganic, and Hybrid Dielectrics for Low-Voltage Organic Field-Effect Transistors. Chem. Rev. 2010, 110, 205-239. (11) Baeg, K. J.; Khim, D.; Jung, S. W.; Kang, M.; You, I. K.; Kim, D. Y.; Facchetti, A.; Noh, Y. Y. Remarkable Enhancement of Hole Transport in TopGated N-Type Polymer Field-Effect Transistors by a High-k Dielectric for Ambipolar Electronic Circuits. Adv. Mater. 2012, 24, 5433-5439. (12) Dang, Z.M.; Yuan, J.K.; Zha, J.W.; Zhou, T.; Li, S.-T.; Hu, G.H. Fundamentals, Processes and Applications of High-permittivity Polymer-matrix Composites. Prog. Mater. Sci. 2012, 57, 660-723. (13) Baer, E.; Zhu, L. 50th Anniversary Perspective: Dielectric Phenomena in Polymers and Multilayered Dielectric Films. Macromolecules 2017, 50, 2239-2256. (14) Wang, G.; Huang, X.; Jiang, P. Tailoring Dielectric Properties and Energy Density of Ferroelectric Polymer Nanocomposites by High‑k Nanowires. ACS Appl. Mater. Interfaces 2015, 7, 18017-18027. (15) Huang, X.; Jiang, P. Core–Shell Structured High-k Polymer Nanocomposites for Energy Storage and Dielectric Applications. Adv. Mater. 2015, 27, 546-554. (16) Molberg, M.; Crespy, D.; Rupper, P.; Nüesch, F.; Månson, J.-A. E.; Löwe, C.; Opris, D. M. High Breakdown Field Dielectric Elastomer Actuators Using Encapsulated Polyaniline as High Dielectric Constant Filler. Adv. Funct. Mater. 2010, 20, 3280-3291. (17) Luo, S.; Yu, S.; Sun, R.; Wong, C. P. Nano Ag-Deposited BaTiO3 Hybrid Particles as Fillers for Polymeric Dielectric Composites: Toward High Dielectric Constant and Suppressed Loss. ACS Appl. Mater. Interfaces 2014, 6, 176-182. (18) Wen, F.; Xu, Z.; Tan, S.; Xia, W.; Wei, X.; Zhang, Z. Chemical Bonding-Induced Low Dielectric Loss and Low Conductivity in High‑k Poly(vinylidenefluoride-trifluorethylene)/Graphene Nanosheets Nanocomposites. ACS Appl. Mater. Interfaces 2013, 5, 9411-9420. (19) Yang, L.; Ho, J.; Allahyarov, E.; Mu, R.; Zhu, L. Semicrystalline Structure−Dielectric Property Relationship and Electrical Conduction in a Biaxially Oriented Poly(vinylidene fluoride) Film under High Electric Fields and High Temperatures. ACS Appl. Mater. Interfaces 2015, 7, 19894-19905.
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(20) Yang, K.; Huang, X.; Huang, Y.; Xie, L.; Jiang, P. Fluoro-Polymer@BaTiO3 Hybrid Nanoparticles Prepared via RAFT Polymerization: Toward Ferroelectric Polymer Nanocomposites with High Dielectric Constant and Low Dielectric Loss for Energy Storage Application. Chem. Mater. 2013, 25, 2327-2338. (21) Chon, J.; Ye, S.; Cha, K. J.; Lee, S. C.; Koo, Y. S.; Jung, J. H.; Kwon, Y. K. High-k Dielectric Sol-Gel Hybrid Materials Containing Barium Titanate Nanoparticles. Chem. Mater. 2010, 22, 5445-5452. (22) Tang, H.; Lin, Y.; Sodano, H. A. Enhanced Energy Storage in Nanocomposite Capacitors through Aligned PZT Nanowires by Uniaxial Strain Assembly. Adv. Energy. Mater. 2012, 2, 469-476. (23) Liu, H.; Luo, S.; Yu, S.; Ding, S.; Shen, Y.; Sun, R.; Wong, C.P. Flexible BaTiO3nf-Ag/PVDF Nanocomposite Films with High Dielectric Constant and Energy Density. IEEE Transactions on Dielectrics and Electrical Insulation 2017, 24, 757-763. (24) Zhu, J.; Shen, J.; Guo, S.; Sue, H.J. Confined Distribution of Conductive Particles in Polyvinylidene Fluoride-Based Multilayered Dielectrics: Toward High Permittivity and Breakdown Strength. Carbon 2015, 84, 355-364. (25) Yuan, J.K.; Yao, S.H.; Dang, Z.M.; Sylvestre, A.; Genestoux, M.; Bai, J. Giant Dielectric Permittivity Nanocomposites: Realizing True Potential of Pristine Carbon Nanotubes in Polyvinylidene Fluoride Matrix through an Enhanced Interfacial Interaction. J. Phys. Chem. C 2011, 115, 5515-5521. (26) Wang, B.; Liang, G.; Jiao, Y.; Gu, A.; Liu, L.; Yuan, L.; Zhang, W. Two-layer materials of polyethylene and a carbon nanotube/cyanate ester composite with high dielectric constant and extremely low dielectric loss. Carbon 2013, 54, 224-233. (27) Wang, B.; Liu, L.; Liang, G.; Yuan, L.; Gu, A. Boost up dielectric constant and push down dielectric loss of carbon nanotube/cyanate ester composites via gradient and layered structure design J. Mater. Chem. A 2015, 3, 23162-23169. (28) Islam, M. S.; Qiao, Y.; Tang, C.; Ploehn, H. J. Terthiophene-Containing Copolymers and Homopolymer Blends as High Performance Dielectric Materials. ACS Appl. Mater. Interfaces 2015, 7, 1967-1977. (29) Hardy, C. G.; Islam, M. S.; Gonzalez-Delozier, D.; Morgan, J. E.; Cash, B.; Benicewicz, B. C.; Ploehn, H. J.; Tang, C. Converting an Electrical Insulator into a Dielectric Capacitor: EndCapping Polystyrene with Oligoaniline. Chem. Mater. 2013, 25, 799-807. (30) Qiao, Y.; Islam, M. S.; Han, K.; Leonhardt, E.; Zhang, J.; Wang, Q.; Ploehn, H. J.; Tang, C. Polymers Containing Highly Polarizable Conjugated Side Chains as High-Performance All-Organic Nanodielectric Materials. Adv. Funct. Mater. 2013, 23, 5638-5646. ACS Paragon Plus Environment
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Page 22 of 26
(31) Liu, Y.; Zhang, Y.; Lan, Q.; Liu, S.; Qin, Z.; Chen, L.; Zhao, C.; Chi, Z.; Xu, J.; Economy, J. High-Performance
Functional
Polyimides
Containing
Rigid
Nonplanar
Conjugated
Triphenylethylene Moieties. Chem. Mater. 2012, 24, 1212-1222. (32) Li, J.; Khanchaitit, P.; Han, K.; Wang, Q. New Route Toward High-Energy-Density Nanocomposites Based on Chain-End Functionalized Ferroelectric Polymers. Chem. Mater. 2010, 22, 5350-5357. (33) Rahimabady, M.; Qun Xu, L.; Arabnejad, S.; Yao, K.; Lu, L.; Shim, V. P. W.; Gee Neoh, K.; Kang, E.T. Poly(vinylidene fluoride-co-hexafluoropropylene)-graft-Poly(dopamine methacrylamide) Copolymers: A Nonlinear Dielectric Material for High Energy Density Storage. Appl. Phys. Let. 2013, 103, 262904-262908. (34) Chisca, S.; Musteata, V. E.; Sava, I.; Bruma, M. Dielectric Behavior of Some Aromatic Polyimide Films. Eur. Polym. J. 2011, 47, 1186-1197. (35) You, Z.; Song, W.; Zhang, S.; Jin, O.; Xie, M. Polymeric Microstructures and Dielectric Properties of Polynorbornenes with 3,5-Bis(trifluoromethyl)biphenyl Side Groups by Ring-Opening Metathesis Polymerization. J. Polym. Sci. Part A: Polym. Chem. 2013, 51, 4786-4798. (36) You, Z.; Gao, D.; Jin, O.; He, X.; Xie, M. High Dielectric Performance of Tactic Polynorbornene Derivatives Synthesized by Ring-Opening Metathesis Polymerization. J. Polym. Sci. Part A: Polym. Chem. 2013, 51, 1292-1301. (37) Choi, U. H.; Mittal, A.; Price, T. L.; Gibson, H. W.; Runt, J.; Colby, R. H. Polymerized Ionic Liquids with Enhanced Static Dielectric Constants. Macromolecules 2013, 46, 1175-1186. (38) Choi, U. H.; Liang, S.; Chen, Q.; Runt, J.; Colby, R. H. Segmental Dynamics and Dielectric Constant of Polysiloxane Polar Copolymers as Plasticizers for Polymer Electrolytes. ACS Appl. Mater. Interfaces 2016, 8, 3215-3225. (39) Smith, T. W.; Zhao, M.; Yang, F.; Smith, D.; Cebe, P. Imidazole Polymers Derived from Ionic Liquid 4-Vinylimidazolium Monomers: Their Synthesis and Thermal and Dielectric Properties. Macromolecules 2013, 46, 1133-1143. (40) Zhang, M.; Zhang, L.; Zhu, M.; Wang, Y.; Li, N.; Zhang, Z.; Chen, Q.; An, L.; Lin, Y.; Nan, C. Controlled Functionalization of Poly(4-methyl-1-pentene) Films for High Energy Storage Applications. J. Mater. Chem. A 2016, 4, 4797-4807. (41) He, L.; Chao, D.; Jia, X.; Liu, H.; Yao, L.; Liu, X.; Wang, C. Electroactive polymer with oligoanilines in the main chain and azo chromophores in the side chain: synthesis, characterization and dielectric properties. J. Mater. Chem. 2011, 21, 1852-1858. (42) Chao, D.; Jia, X.; Liu, H.; He, L.; Cui, L.; Wang, C.; Berda, E. B. Novel Electroactive Poly(arylene ether sulfone) Copolymers Containing Pendant Oligoaniline Groups: Synthesis and ACS Paragon Plus Environment
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Chemistry of Materials
Properties. J. Polym. Sci. Part A: Polym. Chem. 2011, 49, 1605-1614. (43) Stoyanov, H.; Kollosche, M.; McCarthy, D. N.; Kofod, G. Molecular composites with enhanced energy density for electroactive Polymers. J. Mater. Chem. 2010, 20, 7558-7565. (44) Liang, S.; Claude, J.; Xu, K.; Wang, Q. Synthesis of Dumbbell-Shaped Triblock Structures Containing
Ferroelectric
Polymers
and
Oligoanilines
with
High
Dielectric
Constants.
Macromolecules 2008, 41, 6265-6268. (45) Mannodi-Kanakkithodi, A.; Treich, G. M.; Huan, T. D.; Ma, R.; Tefferi, M.; Cao, Y.; Sotzing, G. A.; Ramprasad, R. Rational Co-Design of Polymer Dielectrics for Energy Storage. Adv. Mater. 2016, 28, 6277-6291. (46) Mannodi-Kanakkithodi, A.; Huan, T. D.; Ramprasad, R. Mining Materials Design Rules from Data: The Example of Polymer Dielectrics. Chem. Mater. 2017, 29, 9001-9010. (47) Kim, C.; Pilania, G.; Ramprasad, R. From Organized High-Throughput Data to Phenomenological Theory using Machine Learning: The Example of Dielectric Breakdown. Chem. Mater. 2016, 28, 1304-1311. (48) Sharma, V.; Wang, C.; Lorenzini, R. G.; Ma, R.; Zhu, Q.; Sinkovits, D. W.; Pilania, G.; Oganov, A. R.; Kumar, S.; Sotzing, G. A.; Boggs, S. A.; Ramprasad, R. Rational design of all organic polymer dielectrics. Nat. Commun. 2014, 5, 4845-4853. (49) Pilania, G.; Wang, C. C.; Wu, K.; Sukumar, N.; Breneman, C.; Sotzing, G.; Ramprasad, R. New Group IV chemical motifs for improved dielectric permittivity of polyethylene. J. Chem. Inf. Model. 2013, 53, 879-886. (50) Epstein, A. J.; Rommelmann, H.; Abkowitz, M.; Gibson, H. W. Frequency Dependent Conductivity of Polyacetylene. Mol. Cryst. Liq. Cryst. 2006, 77, 81-96. (51) Shirakawa, H.; Louis, E. J.; MacDiarmid, A. G.; Chiang, C. K.; Heeger, A. J. Synthesis of electrically conducting organic polymers: halogen derivatives of polyacetylene, (CH)x. Chem. Commun. 1977, 16, 578-581. (52) Chiang, C. K.; Fincher, C. R.; Park, Y. W.; Heeger, A. J.; Shirakawa, H.; Louis, E. J.; Gau, S. C.; MacDiarmid, A. G. Electrical Conductivity in Doped Polyacetylene Phys. Rev. Let. 1977, 39, 1098-1101. (53) Ito, T.; Shirakawa, H.; Ikeda, S. Thermal cis-trans isomerization and decomposition of polyacetylene. J. Polym. Sci. Part A: Polym. Chem. 1975, 13, 1943-1950. (54) Ito, T.; Shirakawa, H.; Ikeda, S. Simultaneous polymerization and formation of polyacetylene film on the surface of concentrated soluble Ziegler-type catalyst solution. J. Polym. Sci. Part A: Polym. Chem. 1974, 12, 11-20. (55)Chou, C. M.; Lee, S. L.; Chen, C. H.; Biju, A. T.; Wang, H. W.; Wu, Y. L.; Zhang, G. F.; Yang, K. ACS Paragon Plus Environment
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W.; Lim, T. S.; Huang, M. J.; Tsai, P. Y.; Lin, K. C.; Huang, S. L.; Chen, C. H.; Luh, T. Y. Polymeric Ladderphanes. J. Am. Chem. Soc. 2009, 131, 12579-85. (56) Yang, H. C.; Lin, S. Y.; Yang, H. C.; Lin, C. L.; Tsai, L.; Huang, S. L.; Chen, I. W.; Chen, C. H.; Jin, B. Y.; Luh, T. Y. Molecular Architecture towards Helical DoubleStranded Polymers. Angew. Chem. Int. Ed. 2006, 45, 726-30. (57) Song, W.; Han, H.; Wu, J.; Xie, M. Ladder-like polyacetylene with excellent optoelectronic properties and regular architecture. Chem. Commun. 2014, 50, 12899-12902. (58) Chen, J.; Long, C.; Li, H.; Han, H.; Sun, R.; Xie, M. Double-stranded block copolymer with dual-polarized linker for improving dielectric and electrical energy storage performance. Polymer 2017, 127, 259-268. (59) Chen, J.; Li, H.; Han, H.; Sun, R.; Xie, M. Multiple polarizations and nanostructure of double-stranded conjugated block copolymer for enhancing dielectric performance. Mater. Lett. 2017, 208, 95-97. (60) Love, J. A.; Morgan, J. P.; Trnka, T. M.; Grubbs, R. H. A Practical and Highly Active Ruthenium-Based Catalyst that Effects the Cross Metathesis of Acrylonitrile. Angew. Chem. Int. Ed. 2002, 41, 4035-4037. (61) Liu, W.; Chen, J.; Zhou, D.; Liao, X.; Xie, M.; Sun, R. A high-performance dielectric block copolymer with a self-assembled superhelical nanotube morphology. Polym. Chem. 2017, 8, 725-734. (62) Liu, W.; Liao, X.; Li, Y.; Zhao, Q.; Xie, M.; Sun, R. Nanostructured high-performance dielectric block copolymers. Chem. Commun. 2015, 51, 15320-15323. (63) Choi, U. H.; Mittal, A.; Price, T. L.; Colby, R. H.; Gibson, H. W. Imidazolium-Based Ionic Liquids as Initiators in Ring Opening Polymerization: Ionic Conduction and Dielectric Response of End-Functional Polycaprolactones and Their Block Copolymers. Macromol. Chem. Phys. 2016, 217, 1270-1281. (64) Shang, Q. Y.; Pramanick, S.; Hudson, B. Chemical nature of conduction in iodine-doped trans-1,4-poly(buta-1,3-diene) and some of its derivatives: the presence of I3- and the effect of double-bond configuration. Macromolecules 1990, 23, 1886-1889. (65) Chu, B. A. Dielectric Polymer with High Electric Energy Density and Fast Discharge Speed. Science 2006, 313, 334-336. (66) Li, Q.; Han, K.; Gadinski, M. R.; Zhang, G.; Wang, Q. High energy and power density capacitors from solution-processed ternary ferroelectric polymer nanocomposites. Adv. Mater. 2014, 26, 6244-6629. (67) Baldwin, A. F.; Ma, R.; Mannodi-Kanakkithodi, A.; Huan, T. D.; Wang, C.; Tefferi, M.; ACS Paragon Plus Environment
Page 24 of 26
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Chemistry of Materials
Marszalek, J. E.; Cakmak, M.; Cao, Y.; Ramprasad, R.; Sotzing, G. A. Poly(dimethyltin glutarate) as a prospective material for high dielectric applications. Adv. Mater. 2015, 27, 346-351. (68) Yin, K.; Zhou, Z.; Schuele, D. E.; Wolak, M.; Zhu, L.; Baer, E. Effects of Interphase Modification
and
Biaxial
Orientation
on
Dielectric
Properties
of
Poly(ethylene
terephthalate)/Poly(vinylidene fluoride-co-hexafluoropropylene) Multilayer Films. ACS Appl. Mater. Interfaces 2016, 8, 13555-13566. (69) Treich, G. M.; Nasreen, S.; Mannodi Kanakkithodi, A.; Ma, R.; Tefferi, M.; Flynn, J.; Cao, Y.; Ramprasad, R.; Sotzing, G. A. Optimization of Organotin Polymers for Dielectric Applications. ACS Appl. Mater. Interfaces 2016, 8, 21270-21277. (70) Joyce, D. M.; Venkat, N.; Ouchen, F.; Singh, K. M.; Smith, S. R.; Grabowski, C. A.; Terry Murray, P.; Grote, J. G. Deoxyribonucleic acid-based hybrid thin films for potential application as high energy density capacitors. J. Appl. Phys. 2014, 115, 114108. (71) Guan, F.; Wang, J.; Yang, L.; Tseng, J. K.; Han, K.; Wang, Q.; Zhu, L. Confined Ferroelectric Properties
in
Poly(Vinylidene
Fluoride-co-Chlorotrifluoroethylene)-graft-Polystyrene
Graft
Copolymers for Electric Energy Storage Applications. Macromolecules 2011, 44, 2190-2199. (72) Guan, F.; Pan, J.; Wang, J.; Wang, Q.; Zhu, L. Crystal Orientation Effect on Electric Energy Storage in Poly(vinylidene fluoride-co-hexafluoropropylene) Copolymers. Macromolecules 2010, 43, 384-392. (73) Mackey, M.; Schuele, D. E.; Zhu, L.; Flandin, L.; Wolak, M. A.; Shirk, J. S.; Hiltner, A.; Baer, E. Reduction of Dielectric Hysteresis in Multilayered Films via Nanoconfinement. Macromolecules 2012, 45, 1954-1962. (74) Li, J.; Hu, X.; Gao, G.; Ding, S.; Li, H.; Yang, L.; Zhang, Z. Tuning phase transition and ferroelectric properties of poly(vinylidene fluoride-co-trifluoroethylene) via grafting with desired poly(methacrylic ester)s as side chains. J. Mater. Chem. C 2013, 1, 1111-1121. (75) Hougham, G. G.; Jean, Y. C. Relative Contributions of Polarizability and Free Volume in Reduction of Refractive Index and Dielectric Constant with Fluorine Substitution in Polyimides by Positron Annihilation Spectroscopy. Macromol. Chem. Phys. 2014, 215, 103-110.
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For Table of Contents use only
Rational Design and Modification of High-k Bis(double-stranded) Block Copolymer for High Electrical Energy Storage Capability Jie Chen, Yuxin Wang, Hongfei Li, Huijing Han, Xiaojuan Liao, Ruyi Sun, Xingyi Huang, and Meiran Xie
Electric field (MV/m)
200
300
400 12
5 mol% I2 2.5 mol% I2
0 mol% I2
8 6
35
4 30 2 25 2 10
10
3
10
4
Frequency / Hz
E
10 3
40
100
Energy density (J/cm )
0 45
Dielectric constant
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60
10
5
0
10
6
TOC
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