- Email: [email protected]
carbon nanotube composite with high efficient electromagnetic interference shielding and favourable mechanical properties
Accepted Manuscript Large-scale preparation of segregated PLA/carbon nanotube composite with high efficient electromagnetic interference shielding and favourable mechanical properties Fang Ren, Zhen Li, Ling Xu, Zhenfeng Sun, Penggang Ren, Dingxiang Yan, Zhongming Li PII:
S1359-8368(18)32711-2
DOI:
10.1016/j.compositesb.2018.09.030
Reference:
JCOMB 6000
To appear in:
Composites Part B
Received Date: 22 August 2018 Revised Date:
11 September 2018
Accepted Date: 14 September 2018
Please cite this article as: Ren F, Li Z, Xu L, Sun Z, Ren P, Yan D, Li Z, Large-scale preparation of segregated PLA/carbon nanotube composite with high efficient electromagnetic interference shielding and favourable mechanical properties, Composites Part B (2018), doi: https://doi.org/10.1016/ j.compositesb.2018.09.030. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT Graphical Abstract
RI PT
Large-scale preparation of segregated PLA/carbon nanotube composite with high efficient electromagnetic interference shielding and favourable mechanical properties
M AN U
SC
Fang Rena, Zhen Lia, Ling Xub, Zhenfeng Suna, Penggang Ren a*, Dingxiang Yan b, Zhongming Lib
Segregated structure poly (lactic acid) (PLA) conductive composites with efficient electromagnetic interference (EMI) shielding performance and favourable mechanical properties were easily fabricated by injection molding from poly (L-lactid acid) (PLLA), poly (lactic acid) stereocomplex crystallite (PLASC) and multi-wall carbon nanotube (MWCNT). Due to the selective dispersion of conductive MWCNT filler in the continuous PLA phase,
AC C
EP
TE D
good conductivity and high EMI shielding effectiveness (EMI SE) were achieved under low MWCNT content.
ACCEPTED MANUSCRIPT
Large-scale preparation of segregated PLA/carbon nanotube composite with high efficient electromagnetic interference shielding and favourable
RI PT
mechanical properties Fang Rena, Zhen Lia, Ling Xu b, Zhenfeng Suna, Penggang Ren a*, Dingxiang Yanb*, Zhongming Lib
Shaanxi 710048, People’s Republic of China
SC
a. The Faculty of Printing and Packaging Engineering, Xi’an University of Technology, Xi’an
b. College of Polymer Science and Engineering, State Key Laboratory of Polymer Materials
M AN U
Engineering, Sichuan University, Chengdu 610065, People’s Republic of China *
Corresponding Author. [email protected]; [email protected]
Abstract: Environment friendly conductive polymer composites (CPCs) with high electromagnetic interference (EMI) shielding performance and favourable mechanical properties
TE D
were successfully produced on large scale from poly (L-lactid acid) (PLLA), poly (lactic acid) stereocomplex crystallite (PLASC) and multi-wall carbon nanotube (MWCNT). The morphology
EP
results indicated that the perfect segregated structure was easily manipulated by controlling the injection temperature. The prepared composite exhibits good conductivity and high EMI shielding
AC C
effectiveness (EMI SE) under low MWCNT content due to the selective dispersion of the conductive MWCNT in the continuous PLLA phase. With the addition of only 3 wt% MWCNT, the composite exhibits high electrical conductivity of 6.42 S/m and outstanding EMI shielding performance of 31.02 dB at 8.2 GHz. Moreover, similar molecular structure between PLLA and PLAsc endowed excellent interfacial adhesion, thus results in favourable mechanical properties of composites. The work provides a novel idea for manufacting high EMI shielding materials with both toughness and degradation.
ACCEPTED MANUSCRIPT Keywords: Conductive polymer composites; Segregated structure; Poly (lactic acid); Electromagnetic interference shielding 1. Introduction
RI PT
With the miniaturization and increasing power of electronic instruments and telecommunication devices, the human health and the inherent performance of the nearby-devices are under serious threat for the severe electromagnetic radiation [1-4]. To mitigate the undesirable impact, one
SC
common approach is to shield the electromagnetic interference (EMI) with electric and/or
M AN U
magnetic materials, such as metal materials, magnetic coating, and conductive polymer composites (CPCs) [5-10]. The CPCs have been viewed as advanced candidates for EMI shielding due to their design flexibility, processing advantages, resistance to corrosion, low density and especially for the high electromagnetic absorption as compared to traditional metallic shielding
TE D
materials [11-15]. The electrical conductivity of CPCs is generally required to reach at least 1 S m-1 to satisfy commercially application in EMI shielding [13, 16]. Such conductivity can be only obtained under the high filler concentration, which seriously affects the cost, flowability,
EP
processing characteristics and toughness of composites [17, 18]. Although the utilization of
AC C
nanofiller (especially for carbon nanotube or graphene) effectively reduced the electrical percolation threshold of the CPCs due to the easy formation of conductive networks, the filler loading of CPCs with electromagnetic interference shielding effectiveness (EMI SE) at least 20 dB is still high (10-20 wt%) [19, 20]. For example, about 15wt% graphene loading should be required for CPCs to obtain the EMI SE =21 dB [21] , and when EMI SE improved to 29.3 dB, the graphene loading need to reach 30 wt% [22]. Thus, preparing CPCs with superior EMI SE at low nanofiller loading remain a mission of shouldering heavy responsibilities.
ACCEPTED MANUSCRIPT The construction of segregated structure in CPCs can effectively reduce the electrical percolation threshold and improve electrical conductivity [23-29]. For instance, the segregated structure in a cross-linked carbon nanotube (CNT)/poly(ethylene-co-octene) (POE) composite resulted in a low
RI PT
threshold percolation of 1.5 vol % compared to 9.0 vol % in a conventional CNT/ POE composite [30]. Such segregated architectures also exhibited superior EMI SE to conventional CPCs due to the selective distribution of fillers in the polymer matrices. The thermally reduced
SC
graphene/ultrahigh molecular weight polyethylene (RGO/UHMWPE) composite with segregated
M AN U
structure realized a satisfactory EMI SE of 28.3-32.4 dB at only 0.66vol% filler loading, significantly lower than that of the uniform CPCs [22]. Up to now, the segregated CPCs are mainly prepared by high melt viscosity to prevent the diffusion of electrical filler into their interior, thus mainly limited to UHMWPE [31-33] , crosslinked polymer [11, 34], or amorphous polymers
TE D
under low temperature condition [35, 36]. It is difficult to obtain complete segregated structure in crystalline or semi-crystalline polymers with low-melt-viscosity, such as PP, PA, PET and PLA. Furthermore, the common preparation methods of segregated CPCs, such as mold compressing or
EP
compression molding plus salt-leaching method [22, 37], are not suitable for industrial application
AC C
due to the low productivity. To our knowledge, constructing the segregated structure in low-melt-viscosity crystalline polymer on large scale remains a daunting challenge. On the other hand, excessive consumption and discarding after their service life of fossil-based polymer will lead to serious environment pollution and energy crisis in the near future [38]. Thus, the use of eco-friendly polymer propagates aggressively for the growing need to minimize the carbon footprint in the environment. Compared with other biodegradable polymers (such as poly butylene succinate (PBS), poly-e-caprolactone (PCL) and poly glycolic acid (PGA)), poly(lactic
ACCEPTED MANUSCRIPT acid) (PLA) is considered as the most promising material to substitute for petroleum-based polymer because of its excellent mechanical properties, manipulative degradability and good processibility [39, 40]. However, PLA is a typical semi-crystalline polymer with
RI PT
low-melt-viscosity. It is an enormous challenge to create segregated structure with perfect conductive networks in PLA matrix because the electrical filler may migrate into the polymer interior when temperature exceeds its melting temperature, especially under the external forces.
SC
Fortunately, the PLA stereocomplex crystallite (PLASC) with high melting temperature (Tm) of
M AN U
220℃ is easily formed in the poly L-lactic acid (PLLA) and poly D-lactic acid (PDLA) blends because the multicenter hydrogen bonding interactions between L -lactyl and D -lactyl unit sequences could maintain the two helical chains with the opposite configuration together. While, the Tm of PLA homocrystallites (PLAHC) (about 160-180oC) is relative lower than PLASC.
TE D
Significant difference between Tm of SC and HC makes it possible to establish segregated conductive networks in PLA matrix by controlling the processing temperature. Herein, the PLASC was firstly fabricated from PLLA/PDLA melt blend and then coated with PLLA particles and
EP
multi-wall carbon nanotube (MWCNT) (abbreviate as PLASC@PLLA-MWCNT). Finally, a
AC C
segregated structure PLA composite with perfect conductive networks was successfully prepared by injection-molding technique under various temperatures. Such segregated structure endowed the PLA composite with a much high conductivity of 6.42 Sm-1 and EMI SE value of 27.4 dB at the 3.0 wt% MWCNT loading. More exhilaratingly, the as-prepared composite exhibits steadily increased strength and elongation at break with the MWCNT filler increasing. Furthermore, the effects of injection temperature on morphology, electrical conductivity and the EMI shielding performance of PLASC@PLLA-CNT composite were also investigated.
ACCEPTED MANUSCRIPT 2. Experimental section
2.1 Materials
RI PT
PLLA 4032D and PDLA were purchased from Nature works Co. Ltd. (USA). The weight-average molecular weight (Mw), polydispersity index (PDI) and melting temperature (Tm) of PLLA are 2.23×105 g/mol, 2.10, and 167.4oC, respectively. The corresponding values of PDLA are 8.5×104
SC
g/mol, 1.82, and 176.0oC, respectively. MWCNT was supplied by Nanocyl S.A., Belgium (Nanocyl NC 7000), with average diameter of 9.5nm and average length of 1.5µm. Alcohol and
Reagent Factory (Chengdu, China).
M AN U
dichloromethane (DCM) with analytical grade were purchased from Chengdu Kelong Chemical
2.2 Preparation of PLASC@PLLA-MWCNT segregated composites
TE D
The schematic diagram of the fabrication of PLASC@PLLA-MWCNT segregated composites is shown in Fig.1. Firstly, PLLA and PDLA particles (with weight ratio 1:1) were blended with
EP
Haake torque rheometer (Rheomix 600) at 180oC for 10min, the PLAsc particles with high melting temperature were obtained. 12g PLLA particles were dissolved in 150ml DCM with
AC C
vigorous stirring at room temperature. After completely dissolved, 150ml alcohol was dripped slowly into the PLLA/DCM solution mixture to adjust the solubility parameter. Then 8g PLAsc particles were added and mixed for 10min. Subsequently, another 150ml alcohol was added into the mixture and large amounts of white precipitate appeared immediately. After filter and dry at 50oC for 48h, the PLASC coated with PLLA hybrid particles (PLASC@PLLA) were obtained. Finally, the PLASC@PLLA particles and appropriate amount of MWCNT (weight fraction 0.5, 1.0, 2.0 and 3.0%) were mixed with high-speed mixer and then injected into PLASC@PLLA-MWCNT
ACCEPTED MANUSCRIPT segregated composite specimens. The injection temperature in our experiment fluctuated from 210 to
230oC
to
explore
the
optimal
processing
parameter
for
the
preparation
of
SC
RI PT
PLASC@PLLA-MWCNT segregated composite.
molding method.
2.3 Characterization
TE D
Scanning electron microscopy (SEM)
M AN U
Fig.1 Schematic of the fabrication of the PLASC@PLLA-MWCNT segregated composites using injection
The surface morphologies of the PLAsc and PLASC@PLLA-MWCNT particles were observed by using a field emission scanning electron microscope (Inspect-F, FEI, USA), at an accelerating
EP
voltage of 5.0 kV. The particles were coated with a thin layer of gold beforehand. Cross-sections
AC C
for the SEM observations were obtained by cryo-fracturing the specimens with liquid nitrogen for 30 min.
Differential scanning calorimetry (DSC) Crystallization behavior of PLAsc and PLAsc@PLLA particles was investigated by differential scanning calorimetry on a TA Q2000 instrument. The samples (5-6 mg) were heated from 40 °C to 250 °C at a heating rate of 10 °C/min under nitrogen atmosphere. Crystallinitie (χ) of PLAsc was
ACCEPTED MANUSCRIPT calculated by normalizing their enthalpy to the equilibrium enthalpy of completely crystals, taken as142 J/g for completely crystals PLAsc. The crystallinity (χ) of PLAsc can be calculated as follows:
Where ∆H
and ∆H
∆ ∆
(1)
× 100%
RI PT
χ=
are the enthalpy of 100% PLAsc crystal and the melting enthalpy
measured in experiment, respectively.
SC
For convenience of comparison, the Crystallinitie (χ) of PLAsc in PLAsc@PLLA blend was
M AN U
converted to relative crystallinity (χr) of PLAsc in the pure PLAsc matrix as follows: = Where
is the weight content.
Polarizing Optical Microscopy (POM)
×
(2)
TE D
The segregated structure of composite film was observed by an Olympus BX51 polarizing optical microscopy (Olympus Co., Tokyo, Japan). The film samples were prepared with a thickness of 8 µm by a Leica EMUC6/FC6 microtome.
EP
Measurement of electrical conductivity
AC C
The electrical conductivity of the composite samples was measured using a Keithley electrometer Model 4200-SCS (USA) according to a two-point method. Before the test, both ends of the rectangular specimens were coated with silver paste to reduce the contact resistance between specimens and electrodes.
EMI shielding characteristics EMI shielding measurements were performed with a coaxial test cell (APC-7 connector) in conjunction with an Agilent N5247A vector network analyzer, according to ASTM ES7-83 and
ACCEPTED MANUSCRIPT ASTM D4935-99. The intermediate frequency bandwidth was set as 1 kHz during the measurement and 201 points were collected for each specimen. Samples with a 10 mm diameter and 2 mm thickness were placed in the specimen holder. The scattering parameters (S11 and S21) in
RI PT
the frequency range of 8.2–12.4 GHz were recorded to calculate the reflected power (R), transmitted power (T), absorbed power (A), EMI SE ( SET ), microwave reflection ( SER ) and microwave absorption ( SE A ), using the following equations: 2
2
SC
R = S11 , T = S21 A = 1− R −T
(3)
(4) (5)
SET (dB ) = SER + SE A + SEM
(6)
M AN U
SER (dB ) = −10 log(1 − R ), SE A (dB ) = −10 log(T / (1 − R ))
Where SEM is the microwave multiple internal reflections, which can be negligible when SET
TE D
is higher than10 dB [41]. Mechanical properties testing
The mechanical performance measurements were conducted on a test instrument (Model 5576,
EP
Instron Instruments, USA). For tensile test, the specimens with dimension of 45×5 ×2mm3 were
AC C
conducted with a speed of 20 mm/min. The tensile strength and elongation at break were averaged from 5 samples.
3. Results and discussions
3.1 Morphology and structure of PLASC@PLLA-MWCNT particle
Fig.2 shows the surface SEM morphologies of the PLASC and PLASC@PLLA-MWCNT particles. The as-prepared PLASC particle has irregular and rough geometrical morphology due to the
ACCEPTED MANUSCRIPT melting mixing (Fig.2a and 2b). This particular structure is beneficial to the subsequent coating by PLLA and MWCNT particles. Compared with PLASC particle, PLASC@PLLA-MWCNT particle exhibits larger dimension and roughness (Fig.2c), suggesting the successful coating of the PLLA
RI PT
and MWCNT particles on PLAsc. Abundant and uniformly dispersed MWCNT can be observed from the magnified SEM morphology of PLASC@PLLA-MWCNT particle (Fig.2d). It ensures the
EP
TE D
M AN U
SC
formation of conductive networks in as-prepared PLASC@PLLA-MWCNT segregated composite.
AC C
Fig.2 SEM morphologies of PLAsc ((a) and (b)) and PLAsc@PLLA-MWCNT ((c) and (d)).
To further demonstrates the successful coating of the PLLA particles, melting behavior of the PLAsc and PLAsc@PLLA particles was investigated and their DSC curves are listed in Fig.3.
A
strong melting peak at about 220.0oC and two small peaks at 166.5oC and 174.6oC appeared in the PLAsc curve are corresponded to melting endothermic of PLAsc, PLLA and PDLA crystallite, respectively. It indicates that the overwhelming stereocomplex crystallite with high melting temperature is successfully constructed in the PLLA/PDLA melting blend system, in spite of the
ACCEPTED MANUSCRIPT existence of a small quantity of PLLA and PDLA homocrystallites. On the contrary, the strong peak at 167.4oC and relatively weak peak at 220.0oC can be observed from the PLAsc@PLLA curve. The crystallinity of PLAsc calculated from PLAsc and PLAsc@PLLA curves are 34.48%
RI PT
and 12.31%, respectively. Combining the weight ratio of PLLA/PLAsc (3:2), the relative crystallinity of PLAsc in the PLAsc@PLLA blend was transformed to 30.78%, which is closed to that of PLAsc in pure matrix. Unchanged crystallinity of PLAsc suggested that the PLAsc is not
SC
dissolved in DCM solution during the coating process, which ensures the formation of segregated
AC C
EP
TE D
molding condition (215oC).
M AN U
structure in samples because PLAsc particles (Tm=220oC) are not melted under normal injection
Fig.3 DSC curves of PLASC and PLASC @PLLA particles.
3.2 Effect of injecting temperature on the performances of composites
Melting behavior of PLA is mainly depended on the injecting temperature. The preferable injecting temperature should be ranged from the Tm of PLLA to the Tm of PLAsc. In this case, only the PLLA particles exhibit melt fluidity, while the PLAsc particles still maintain solid state.
ACCEPTED MANUSCRIPT Thus the "sea-island" can be formed naturally in the composites and the MWCNT dispersed only in the continuous PLLA phase, rather than the island PLAsc phase, resulting in the significant improvement of electrical conductivity due to volume exclusion effect. Polarizing microscope
RI PT
images of PLAsc@PLLA-MWCNT composites at different temperature are shown in Fig.4. Perfect segregated structure was established in the composites prepared at relative low temperature (<220oC). The scattered PLAsc phase is bright, while the continuous phase (PLLA)
SC
looks more black and opaque. It indicates the MWCNT fillers selectively dispersed into the
M AN U
continuous phase, rather than uniformly dispersed into all polymer matrices. No apparent difference of segregated structure existed between composites prepared at 210oC and 215oC (Fig.4a and 4b). However, when temperature rises to 220oC (about Tm of PLAsc), the size and total area of the dispersed phase are decreased obviously (Fig.4c). It means that the PLAsc crystal
TE D
begins to melt, which consistent with the DSC analysis. As the temperature rises further to 230oC, "sea-island" structure completely disappeared, and MWCNT fillers uniformly dispersed in whole polymer matrix (Fig.4d). Thus, it concluded that the perfect segregated structure can be obtained
EP
only below the Tm of PLAsc (220oC). At this temperature, MWCNT fillers dispersed in the melted
AC C
PLLA phase, unable to penetrate into the solid PLAsc interior, thus formed perfect segregated structure with conductive networks.
M AN U
SC
RI PT
ACCEPTED MANUSCRIPT
Fig.4 POM images of PLAsc @PLLA-MWCNT (3wt%MWCNT) composites at different temperature.
The SEM images of composites at 215oC and 230oC are showed in Fig.5. Obvious two phase
TE D
sea-island structure exists in the composite injected at 215oC (Fig.5a). A closer inspection reveals that the island phase exhibits a relative rough surface as same as the PLAsc particles (Fig.2),
EP
suggesting the PLAsc particles are not melted in 215oC. Despite the existence of the obvious sea-island structure, the blurry interface between two phases in composite indicates the excellent
AC C
interfacial interaction and adhesion due to the similar molecular structure of PLAsc and PLLA. Homogeneous polymer matrix with relative smooth surface observed in composite prepared at 230oC (Fig.5b) was further proved the melting behavior of PLAsc crystal and the good compatibility between PLAsc and PLLA matrices.
RI PT
ACCEPTED MANUSCRIPT
Fig.5 SEM images of the fractured surface of injection molding composites at different temperature (a): 215oC, (b)
SC
230oC
Fig.6 shows the effect of injection temperature on the electrical conductivity of
M AN U
PLAsc@PLLA-MWCNT composites. The conductivity of the composites firstly increases and then decreases with the injection temperature increasing, and achieves the maximum value of 6.42 S/m at the 215oC. In addition, the fluctuation of conductivity below 215oC is relatively smaller than that above 215oC. The conductivity of composites only increased by 32% (from 4.84 to 6.42
TE D
S/m) when temperature rise from 210 to 215oC. Below the Tm of PLASC (Tm=220℃), MWCNT selectively dispersed in the continuous PLLA phase. With the increase of temperature, the fluidity
EP
of PLLA phase is further enhanced, making MWCNT more evenly dispersed in PLLA, which facilitates to form conductive channels. Thus, conductivity of composites increased. However,
AC C
almost 2.7 times decrease in conductivity was observed when temperature rise from 215 to 220oC. It can be explained by construction and destruction of the segregated structure with conductive networks in composites. When injection temperature below 220oC, segregated structure with good conductive networks was formed due to the infusibility of PLAsc particles, the difference at various injection temperatures is merely the perfection of segregated structure. Therefore, the conductivity fluctuation is relatively small. Whereas, the conductive MWCNT fillers will disperse into the PLAsc particles and the segregated structure gradually destructed at high injection
ACCEPTED MANUSCRIPT temperature (>220oC), results in sudden drop of conductivity. This is consistent with the
M AN U
SC
RI PT
observation from Fig.4 and Fig.5.
Fig.6 Electrical conductivity of PLAsc@PLLA-MWCNT at different injection temperature.
The EMI SE of PLAsc @PLLA-MWCNT composites injected at different temperature are shown in Fig.7. The variation of average EMI SE is essentially in accord with the conductivity of
TE D
composite. The average EMI SE of composite firstly increased from 25.07 dB (210oC) to 27.44 dB (215oC), then rapidly decreased to 17.44 dB (220oC) and 15.61 dB (230oC). This phenomenon
EP
is easily explained by the construction and deconstruction of segregated structure in composites at various temperatures. Interestingly, the EMI SE of composites with perfect segregated structure
AC C
(210oC and 215oC) exhibits a weak dependence on frequency, whereas the transitional (220oC) and homogeneous structure composites (230oC) show strong dependence on frequency. The resonance absorption peak shifts toward the higher frequency with the increase of temperature. This could be understood in terms of the factor that the employment of the electrical loss spacers would essentially vary the dielectric constant of the transport medium, which results in the changes in wave length and velocity. Such phenomena is in accordance with the some previous researches [42-44]. In addition, the comparison of SET (total EMI SE), SEA (microwave
ACCEPTED MANUSCRIPT absorption) and SER (microwave reflection) for various composites at the frequency of 8.2GHz (Fig.7b) indicates that the contribution of absorption to the total EMI SE is much larger than that from reflection in all prepared composites. To give a comprehensive understanding of the
RI PT
microwave attenuation mechanism, the power coefficient of reflectivity (R), transmissivity (T), and absorptivity (A) are obtained from the measured scattering parameters (S11, S21) as shown in Figure 7c. With increasing the injected temperature, T value increases noticeably, R value
SC
significantly decreases in initial and then slightly increases, and A value exhibits small changes.
M AN U
This is mainly attributed to the destruction of the segregated structure in composites at high injection temperature (>220oC). Whatever, the composite prepared at 215oC exhibits high EMI SE, broad shielding frequency range and excellent absorption characteristics. Therefore, the optimal
EP
TE D
injection temperature was fixed at 215oC.
AC C
Fig. 7 EMI SE properties of PLAsc@PLLA-MWCNT composites (3wt%MWCNT) injected at different
temperature. (a) EMI SE as a function of frequency; (b) Comparison of SET, SEA and SER at the frequency of 8.2 GHz; (c) Coefficients of reflection (R), absorption (A), and transmittance (T) at 8.2 GHz.
3.3 The effects of MWCNT contents on the performances of composites
The POM images of PLAsc@PLLA-MWCNT composites with various MWCNT contents injected at 215oC are shown in Fig.8. As a dispersed phase, the infusible PLAsc particles are
ACCEPTED MANUSCRIPT surrounded by the opaque PLLA+MWCNT phase. Because the MWCNT filler are merely dispersed in the continuous PLLA phase, the conductive network is easily constructed in PLLA phase due to the excluded volume effect. Therefore, segregated structure can be observed in all
RI PT
composite samples and the conductive paths are constantly improved with the MWCNT filler increasing. Nevertheless, the perfect conductive networks are still not constructed in Fig.8a because of the low filler contents. The conductivities of composites with various MWCNT
SC
contents are shown in Fig.9. Rapid increase of the conductivity of composite at relative low
M AN U
MWCNT loading implies the establishment of the conductive paths. The conductivity of PLA increases from 10-15 S/m to 2.84×10-9 S/m at 0.5 wt% and 0.09 S/m at 1.0 wt% MWCNT loading, respectively, almost 6 and 13 orders of magnitude increasement. Thereafter, the conductivity of composites increases slowly with the MWCNT filler increasing. It suggests that the prepared
TE D
composites exhibit a typical percolation behavior and is usually evaluated with power-law equation, i.e. σ = σ 0 (φ − φc ) . Where t
σ , σ 0 , φ and φc is the electrical conductivity of
composite, constant conductivity associated with the intrinsic characteristic of MWCNT, volume
EP
content of the MWCNT filled in composites, and the percolation threshold (the minimum contents
AC C
of filler to construct the electrical path in composite), respectively. t represents a critical exponent related to dimensionality. The fitted curve of Logσ vs Log (φ − φc ) is listed in the inset of Fig.9. 0.44 vol% percolation threshold obtained from the fitted curve indicates the conductive networks are cost-effectively established in segregated composites with high efficiency. Thus, it means that the perfect electrical networks exist in composites when the filler loading exceed 0.44 vol% (about 0.8 wt%). This is consistent with the observation from Fig.8. Once formed the conductive network, the improvement of composite conductivity is indistinctive with the filler
ACCEPTED MANUSCRIPT increasing. Even so, the conductivity of prepared PLA segregated composite with 3 wt% MWCNT
M AN U
SC
RI PT
reaches 6.42 S/m, completely meet the practical application in EMI shielding.
TE D
Fig.8 POM images of PLAsc@ PLLA-MWCNT composites with different MWCNT contents. (a) 0.5 wt%; (b)1.0
AC C
EP
wt%; (c) 2.0 wt%; (d) 3.0 wt%.
Fig.9 Electrical conductivity of the PLAsc@ PLLA-MWCNT composites as a function of MWCNT contents.
ACCEPTED MANUSCRIPT Fig.10 shows the EMI SE properties of segregated composites with different filler loading. The EMI SE continues to increase with the MWCNT filler increasing, especially for the composites with relative high filler loading. With the addition of 3 wt% MWCNT, the maximum and the
RI PT
average EMI SE of composites reach up to 31.02 and 27.44dB. More importantly, the EMI SE beyond 25 dB in frequency range of 8 to 12GHz suggested that the prepared composite can meet the requirements of traditional electromagnetic shielding materials [13]. To further understand the
SC
mechanism of electromagnetic shielding, SET, SEA and SER of composites with various filler
M AN U
loading at the frequency of 8.2 GHz are calculated and were listed in Fig.10b. The SET and the SEA are obviously enhanced with increasing MWCNT filler content. However, the SER exhibits a strong independence on MWCNT filler contents. With the 3wt% MWCNT loading, the value of SEA reaches 28.11dB, almost 90.62% of SET, indicating the absorption dominant shielding
TE D
mechanism rather than reflection in the prepared composites. According to the power balance of T, R, and A versus incident power (as shown in Figure 10c), T value decrease significantly, R value increases noticeably, and A value first slightly increased and then decreased as the filler content
EP
increasing. It is attributed to the unique segregated structure. At the low filler contents, the perfect
AC C
conductive networks are not constructed, which allows more electromagnetic waves penetrating through the composite and therefore results in a high T value. Thereafter, segregated structure can be constructed and the conductive paths are constantly improved with the filler increasing. Thus, T value decreases sharply and the composites exhibits excellent shielding characteristics. The PLAsc particles without MWCNT filler can be considered as a “skin” of shielding materials, and PLLA-MWCNT phase with high conductivity act as inner absorption and reflecting layer. The electromagnetic microwaves are easily propagated into the “skin” due to the impedance matching
ACCEPTED MANUSCRIPT of non-conductive PLAsc particles. Subsequently, the incident electromagnetic microwaves will be attenuated in the PLLA-MWCNT phase by reflecting, adsorption and scattering many times. Electromagnetic microwaves are “trapped” in the closed conductive network and is difficult to
RI PT
penetrate this reflecting layer. This shielding mechanism has been reported in our previous
M AN U
SC
researches [22, 25, 26, 37].
Fig.10 EMI SE properties of PLAsc@PLLA-MWCNT composites molded at different melt temperature. (a) EMI
SE as a function of frequency; (b) Comparison of SET, SEA and SER at the frequency of 8.2 GHz. (c) Coefficients of R, A and T at 8.2 GHz.
TE D
The mechanical property is a major parameter for evaluating the application of CPCs shielding materials. Generally, the mechanical properties of composite, including tensile strength and
EP
elongation at break, significantly deteriorated in the presence of the segregated structure due to the weak interfaces. Therefore, the tensile performance of the prepared segregated composites with
AC C
various MWCNT loading was measured and the results are plotted in Fig.11. Pure PLAsc matrix exhibits a typical brittle fracture behavior, without obvious yielding phenomenon, which is attributed to the special crystal texture of PLAsc [45]. The tensile strength and elongation at break of PLAsc matrix are only 39.14MPa and 1.78%, respectively. While an apparent two yielding existed in the strain-stress curve of PLLA matrix. The tensile strength and elongation at break can reach 70.78MPa and 5.13%, respectively. Interestingly, the strength and elongation at break of the PLLA@PLAsc-MWCNT composites increased with the MWCNT filler content increasing. With
ACCEPTED MANUSCRIPT the addition of 3wt% MWCNT, increments of 32.70% and 67.17% were obtained for the tensile strength and elongation at break; increased from 43.73MPa (PLAsc@PLLA) to 58.03MPa and from 1.98% (PLAsc@PLLA) to 3.31%, respectively. The improvement of strength and elongation
RI PT
of composites may be ascribed to the excellent mechanical performance of MWCNT, toughening modification of PLAsc particles and excellent interfacial adhesion between PLLA and PLAsc (as shown in Fig5a). As continuous phase, PLLA matrix bears most of the external load and therefore
SC
some microcracks initiated and propagated in PLLA matrix when the applied load exceeds its
M AN U
breaking strength. Once the propagated microcrack encountered the stiff PLAsc particles, the crack propagation path may be changed. Particle reinforcement, crack deflection and particle pullout are the main toughening mechanisms. Due to the excellent interfacial adhesion between PLLA and PLAsc, the PLAsc@PLLA composite exhibits superior strength and toughness to
TE D
PLAsc. Furthermore, with the increase of MWCNT concentration, the strength and deformability of the PLLA-MWCNT phase was gradually increased. The breaking point of the PLAsc @PLLA-MWCNT composites lied on the strain-stress curves of PLLA matrix and the special two
EP
yielding appeared in the composites containing high MWCNT loading. This indicates that the
AC C
tensile strength and elongation at break is mainly determined by PLLA–MWCNT phase. In other words, the brittle rupture is not occurred in PLAsc@PLLA-MWCNT composite because the stress concentration on crack tip eliminated by dispersed PLAsc particles. The schematic diagram of the toughening and reinforcing mechanism is shown in Fig.12. Regardless, this large-scale produced composite exhibits not only the good electromagnetic shielding effectiveness, but also excellent mechanical properties with low MWCNT loading. Together with the PLA degradation performance, this approach provides a novel idea for manufacting new high EMI shielding
ACCEPTED MANUSCRIPT
SC
RI PT
materials with both toughness and degradation.
Fig.11 Strain-stress curves of PLLA, PLAsc and PLAsc@ PLLA-MWCNT composites with various MWCNT
AC C
EP
TE D
M AN U
content.
Fig.12 The schematic diagram of the toughening and reinforcing mechanism.
4. Conclusion
Segregated structure PLA conductive composites with efficient EMI shielding performance and favourable mechanical properties were easily fabricated by injection molding from PLAsc, PLLA and MWCNT particles. Due to the selective dispersion of conductive MWCNT filler in the
ACCEPTED MANUSCRIPT continuous PLLA phase, good conductivity and high EMI SE were achieved under low MWCNT content. Moreover, enhanced tensile strength and toughness was simultaneously obtained because of the excellent interfacial adhesion between PLLA and PLAsc. With the additional of 3 wt%
RI PT
MWCNT, the EMI SE reached 31.02 dB at the frequency of 8.2 GHz, the tensile strength increased from 43.73 to 58.03 MPa and elongation at break increased from 1.98 to 3.31%. Our work reveals a major breakthrough in creating a segregated conductive network structure in
M AN U
friendly, and highly efficient EMI shielding composites.
SC
low-melt-viscosity polymers on large scale, further developing economical, environmentally
Acknowledgements
This work was supported by National Natural Science Foundation of China (Grant No. 21706208, 51773167, 21704070), the Natural Science Foundation of Shaanxi Province, China (Grant No.
TE D
2017JQ5065), the Opening Project of State Key Laboratory of Polymer Materials Engineering (Sichuan University) (Grant No. sklpme2017-4-13).
References
EP
[1] Shahzad F, Alhabeb M, Hatter CB, Anasori B, Man Hong S et al. Electromagnetic interference
AC C
shielding with 2D transition metal carbides (MXenes). Science 2016; 353:1137-40. [2] Jia LC, Yan DX, Liu XF, Ma RJ, Wu HY, Li ZM. Highly efficient and reliable transparent electromagnetic interference shielding film. Acs Appl Mater Inter 2018; 10(14):11941-49.
[3] Song WL, Wang J, Fan LZ, Li Y, Wang CY, Cao MS. Interfacial engineering of carbon nanofiber-graphene-carbon nanofiber heterojunctions in flexible lightweight electromagnetic shielding networks. Acs Appl Mater Inter 2014; 6(13):10516-23. [4] Liu J, Zhang HB, Sun RH, Liu YF, Liu ZS, Zhou AG, et al. Hydrophobic, flexible, and
ACCEPTED MANUSCRIPT lightweight MXene foams for high‐performance electromagnetic‐interference shielding. Adv Mater 2017; 29(38):1702367. [5] Jia LC, Li MZ, Yan DX, Cui CH, Wu HY, Li ZM. A strong and tough polymer-carbon
RI PT
nanotube film for flexible and efficient electromagnetic interference shielding. J Mater Chem C 2017; 5(35):8944-51.
[6] Wang H, Zheng K, Zhang X, Ding X, Zhang ZX, Bao C, et al. 3D network porous polymeric
SC
composites with outstanding electromagnetic interference shielding. Compos Sci Technol
M AN U
2016; 125:22-9.
[7] Chen Y, Zhang HB, Huang YQ, Jiang Y, Zheng WG, Yu ZZ. Magnetic and electrically conductive epoxy/graphene/carbonyl iron nanocomposites for efficient electromagnetic interference shielding. Compos Sci Technol 2015; 118:178-85.
TE D
[8] Hsiao ST, Ma CM, Tien HW, Liao WH, Wang YY, Li SM. Effect of covalent modification of graphene nanosheets on the electrical property and electromagnetic interference shielding performance of a water-borne polyurethane composite. Acs Appl Mater Inter 2015;
EP
7(4):2817-26.
AC C
[9] Jing QF, Law JY, Tan LP, Silberschmidt VV, Li L, Dong ZL. Preparation, characterization and properties of polycaprolactone diol-functionalized multi-walled carbon nanotube/ thermoplastic polyurethane composite. Compos Part A 2015; 70:8-15.
[10] Qing YC, Min DD, Zhou YH, Luo F, Zhou WC. Graphene nanosheet- and flake carbonyl iron particle-filled epoxy–silicone composites as thin–thickness and wide-bandwidth microwave absorber. Carbon 2015; 86:98-107. [11] Jia LC, Yan DX, Cui CH, Jiang X, Ji X, Li ZM. Electrically conductive and electromagnetic
ACCEPTED MANUSCRIPT interference shielding of polyethylene composites with devisable carbon nanotube networks. J Mater Chem C 2015; 3(36):9369-78. [12] Ren F, Song DP, Li Z, Jia LC, Zhao YC, Yan DX, et al. Synergistic effect of graphene
RI PT
nanosheets and carbonyl iron nickel alloy hybrid filler on electromagnetic interference shielding and thermal conductivity of cyanate ester composites. J Mater Chem C 2018; 6(6):1476-86.
SC
[13] Thomassin J, Jérôme C, Pardoen T, Bailly C, Huynen I, Detrembleur C. Polymer/carbon
M AN U
based composites as electromagnetic interference (EMI) shielding materials. Mater Sci Eng R. 2013; 74(7):211-32.
[14] Zeng ZH, Jin H, Chen MJ, Li WW, Zhou LC, Zhang Z. Lightweight and anisotropic porous MWCNT/WPU composites for ultrahigh performance electromagnetic interference shielding.
TE D
Adv Funct Mater 2016; 26(2):303-10.
[15] Zhang HM, Zhang GC, Li JT, Fan X, Jing ZX, Li JW, et al. Lightweight, multifunctional microcellular
PMMA/
Fe3O4
@MWCNTs
nanocomposite
foams
with
efficient
EP
electromagnetic interference shielding. Compos Part A–Appl S 2017; 100:128-38.
AC C
[16] Sun XM, Sun H, Li HP, Peng HS. Developing polymer composite materials: carbon nanotubes or graphene? Adv Mater 2013; 25(37):5153-76.
[17] Chen ZP, Ren WC, Gao LB, Liu BX, Pei SF, Cheng HM. Three-dimensional flexible and conductive interconnected graphene networks grown by chemical vapour deposition. Nat Mater 2011; 10(6):424-8. [18] Gui XC, Li HB, Zhang LH, Jia Y, Liu L, Li Z, et al. A Facile Route to Isotropic Conductive Nanocomposites by Direct Polymer Infiltration of Carbon Nanotube Sponges. Acs Nano
ACCEPTED MANUSCRIPT 2011; 5(6):4276-83. [19] Ling JQ, Zhai WT, Feng WW, Shen B, Zhang JF, Zheng WG. Facile preparation of lightweight microcellular polyetherimide/graphene composite foams for electromagnetic
RI PT
interference shielding. Acs Appl Mater Inter 2013; 5(7):2677-84. [20] Arjmand M, Apperley T, Okoniewski M, Sundararaj U. Comparative study of electromagnetic interference shielding properties of injection molded versus compression multi-walled
carbon
nanotube/polystyrene
composites.
SC
molded
M AN U
50(14):5126-34.
Carbon
2012;
[21] Liang JJ, Wang Y, Huang Y, Ma YF, Liu ZF, Cai JW, et al. Electromagnetic interference shielding of graphene/epoxy composites. Carbon 2009; 47(3):922-5. [22] Yan DX, Ren PG, Pang H, Fu Q, Yang MB, Li ZM. Efficient electromagnetic interference of
22(36):18772-4.
lightweight graphene/polystyrene
composite.
J
Mater Chem 2012;
TE D
shielding
[23] Pang H, Xu L, Yan DX, Li ZM. Conductive polymer composites with segregated structures.
EP
Prog Polym Sci 2014; 39(11):1908-33.
AC C
[24] Sharif F, Arjmand M, Moud AA, Sundararaj U, Roberts EP. Segregated hybrid poly(Methyl Methacrylate)/graphene/magnetite nanocomposites for electromagnetic interference shielding. Acs Appl Mater Inter 2017; 9(16):14171-9.
[25] Yan DX, Pang H, Li B, Vajtai R, Xu L, Ren PG, et al. Structured reduced graphene oxide/polymer composites for ultra‐efficient electromagnetic interference shielding. Adv Funct Mater 2015; 25(4):559-66. [26] Wu HY, Jia LC, Yan DX, Gao JF, Zhang XP, Ren PG, et al. Simultaneously improved
ACCEPTED MANUSCRIPT electromagnetic interference shielding andmechanical performance of segregated carbon nanotube/polypropylene composite via solid phase molding. Compos Sci Technol 2018; 156:87-94.
RI PT
[27] Wang H, Zheng K, Zhang X, Du TX, Xiao C, Ding X, et al. Segregated poly(vinylidene fluoride)/MWCNTs composites for high-performance electromagnetic interference shielding. Compos Part A–Appl S 2016; 90:606-13.
SC
[28] Zhai W, Zhao SG, Wang Y, Zheng GQ, Dai K, Liu CT, Shen CY. Segregated conductive
A–Appl S, 2018, 105: 68-77.
M AN U
polymer composite with synergistically electrical and mechanical properties. Compos Part
[29] Zhao SG, Lou DD, Zhan PF, Li GJ, Dai K, Guo J, Zheng GQ, Liu CT, Shen CY, Guo ZH. Heating-induced negative temperature coefficient effect in conductive graphene/polymer
TE D
ternary nanocomposites with a segregated and double-percolated structure. Journal of Materials Chemistry C, 2017, 5: 8233-8242. [30] Li T, Ma LF, Bao RY, Qi GQ, Yang W, Xie BH, et al. A new approach to construct
EP
segregated structures in thermoplastic polyolefin elastomers towards improved conductive
AC C
and mechanical properties. J Mater Chem A 2015; 3(10):5482-90. [31] Hu HL, Zhang G, Xiao LG, Wang HJ, Zhang QS, Zhao ZD. Preparation and electrical conductivity of graphene/ultrahigh molecular weight polyethylene composites with a segregated structure. Carbon 2012; 50(12):4596-9.
[32] Cui CH, Pang H, Yan DX, Jia LC, Jiang X, Lei J, et al. Percolation and resistivity-temperature behaviours of carbon nanotube-carbon black hybrid loaded ultrahigh molecular weight polyethylene composites with segregated structures. RSC Adv 2015;
ACCEPTED MANUSCRIPT 5(75):61318-23. [33] Pang H, Yan DX, Bao Y, Chen JB, Chen C, Li ZM. Super-tough conducting carbon nanotube/ultrahigh-molecular-weight
polyethylene
composites
with
segregated
and
RI PT
double-percolated structure. J Mater Chem 2012; 22(44):23568-75. [34] Zhan YH, Lavorgna M, Buonocore GG, Xia HS. Enhancing electrical conductivity of rubber
mixing. J Mater Chem 2012; 22(21):10464-8.
SC
composites by constructing interconnected network of self-assembled graphene with latex
M AN U
[35] Yoonessi M, Gaier JR. Highly conductive multifunctional graphene polycarbonate nanocomposites. Acs Nano 2010; 4(12):7211-20.
[36] Jin Y, Gerhardt RA. Percolation and electrical conductivity modeling of novel microstructured insulator-conductor nanocomposites fabricated from PMMA and ATO. Mrs
TE D
Proce 2014; 1692(4):22264-71.
[37] Xu L, Jia LC, Yan DX, Ren PG, Xu JZ, Li ZM. Efficient electromagnetic interference shielding of lightweight carbon nanotube/polyethylene composites via compression molding
EP
plus salt-leaching. Rsc Adv 2018; 8(16):8849-55.
AC C
[38] Huang HD, Liu CY, Li D, Chen YH, Zhong GJ, Li ZM. Ultra-low gas permeability and efficient reinforcement of cellulose nanocomposite films by well-aligned graphene oxide nanosheets. J Mater Chem A 2014; 2(38):15853-63.
[39] Maharana T, Pattanaik S, Routaray A, Nath N, Sutar AK. Synthesis and characterization of poly(lactic acid) based graft copolymers. React Funct Polym 2015; 93:47-67. [40] Tan BH, Muiruri JK, Li ZB, He CB. Recent progress in using stereocomplexation for enhancement of thermal and mechanical property of polylactide. Acs Sustain Chem Eng
ACCEPTED MANUSCRIPT 2016; 4(10):5370-91. [41] Gupta TK, Singh BP, Dhakate SR, Singh VN, Mathur RB. Improved nanoindentation and microwave shielding properties of modified MWCNT reinforced polyurethane composites. J
RI PT
Mater Chem A 2013; 1(32):9138-49. [42] Yan DX, Pang H, Xu L, Bao Y, Ren PG, Lei J, et al. Electromagnetic interference shielding
graphene oxide. Nanotechnology 2014; 25(14):145705.
SC
of segregated polymer composite with an ultralow loading of in situ thermally reduced
M AN U
[43] Yu WC, Xu JZ, Wang ZG, et al. Constructing highly oriented segregated structure towards high-strength carbon nanotube/ultrahigh-molecular-weight polyethylene composites for electromagnetic interference shielding. Compos Part A–Appl S 2018; 110: 237-45. [44] Song WL, Zhou Z, Wang LC, et al. Constructing Repairable Meta-Structures of
TE D
Ultra-Broad-Band Electromagnetic Absorption from Three-Dimensional Printed Patterned Shells. Acs Appl Mater Inter 2017; 9(49): 43179-87. [45] Tsuji H. Poly (lactic acid) stereocomplexes: A decade of progress. Adv Drug Deliver Rev
AC C
EP
2016; 107:97-135.
ACCEPTED MANUSCRIPT Highlights: 1. Segregated structure PLA conductive composites were easily fabricated by injection molding from PLASC, PLLA and MWCNT particles.
RI PT
2. The prepared composite exhibited good conductivity and high EMI SE under low MWCNT content due to the selective dispersion of the conductive MWCNT in the continuous PLLA
SC
phase.
3. Similar molecular structure between PLLA and PLASC endowed excellent interfacial
AC C
EP
TE D
M AN U
adhesion, thus results in favourable mechanical properties of composites.
S1359-8368(18)32711-2
DOI:
10.1016/j.compositesb.2018.09.030
Reference:
JCOMB 6000
To appear in:
Composites Part B
Received Date: 22 August 2018 Revised Date:
11 September 2018
Accepted Date: 14 September 2018
Please cite this article as: Ren F, Li Z, Xu L, Sun Z, Ren P, Yan D, Li Z, Large-scale preparation of segregated PLA/carbon nanotube composite with high efficient electromagnetic interference shielding and favourable mechanical properties, Composites Part B (2018), doi: https://doi.org/10.1016/ j.compositesb.2018.09.030. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT Graphical Abstract
RI PT
Large-scale preparation of segregated PLA/carbon nanotube composite with high efficient electromagnetic interference shielding and favourable mechanical properties
M AN U
SC
Fang Rena, Zhen Lia, Ling Xub, Zhenfeng Suna, Penggang Ren a*, Dingxiang Yan b, Zhongming Lib
Segregated structure poly (lactic acid) (PLA) conductive composites with efficient electromagnetic interference (EMI) shielding performance and favourable mechanical properties were easily fabricated by injection molding from poly (L-lactid acid) (PLLA), poly (lactic acid) stereocomplex crystallite (PLASC) and multi-wall carbon nanotube (MWCNT). Due to the selective dispersion of conductive MWCNT filler in the continuous PLA phase,
AC C
EP
TE D
good conductivity and high EMI shielding effectiveness (EMI SE) were achieved under low MWCNT content.
ACCEPTED MANUSCRIPT
Large-scale preparation of segregated PLA/carbon nanotube composite with high efficient electromagnetic interference shielding and favourable
RI PT
mechanical properties Fang Rena, Zhen Lia, Ling Xu b, Zhenfeng Suna, Penggang Ren a*, Dingxiang Yanb*, Zhongming Lib
Shaanxi 710048, People’s Republic of China
SC
a. The Faculty of Printing and Packaging Engineering, Xi’an University of Technology, Xi’an
b. College of Polymer Science and Engineering, State Key Laboratory of Polymer Materials
M AN U
Engineering, Sichuan University, Chengdu 610065, People’s Republic of China *
Corresponding Author. [email protected]; [email protected]
Abstract: Environment friendly conductive polymer composites (CPCs) with high electromagnetic interference (EMI) shielding performance and favourable mechanical properties
TE D
were successfully produced on large scale from poly (L-lactid acid) (PLLA), poly (lactic acid) stereocomplex crystallite (PLASC) and multi-wall carbon nanotube (MWCNT). The morphology
EP
results indicated that the perfect segregated structure was easily manipulated by controlling the injection temperature. The prepared composite exhibits good conductivity and high EMI shielding
AC C
effectiveness (EMI SE) under low MWCNT content due to the selective dispersion of the conductive MWCNT in the continuous PLLA phase. With the addition of only 3 wt% MWCNT, the composite exhibits high electrical conductivity of 6.42 S/m and outstanding EMI shielding performance of 31.02 dB at 8.2 GHz. Moreover, similar molecular structure between PLLA and PLAsc endowed excellent interfacial adhesion, thus results in favourable mechanical properties of composites. The work provides a novel idea for manufacting high EMI shielding materials with both toughness and degradation.
ACCEPTED MANUSCRIPT Keywords: Conductive polymer composites; Segregated structure; Poly (lactic acid); Electromagnetic interference shielding 1. Introduction
RI PT
With the miniaturization and increasing power of electronic instruments and telecommunication devices, the human health and the inherent performance of the nearby-devices are under serious threat for the severe electromagnetic radiation [1-4]. To mitigate the undesirable impact, one
SC
common approach is to shield the electromagnetic interference (EMI) with electric and/or
M AN U
magnetic materials, such as metal materials, magnetic coating, and conductive polymer composites (CPCs) [5-10]. The CPCs have been viewed as advanced candidates for EMI shielding due to their design flexibility, processing advantages, resistance to corrosion, low density and especially for the high electromagnetic absorption as compared to traditional metallic shielding
TE D
materials [11-15]. The electrical conductivity of CPCs is generally required to reach at least 1 S m-1 to satisfy commercially application in EMI shielding [13, 16]. Such conductivity can be only obtained under the high filler concentration, which seriously affects the cost, flowability,
EP
processing characteristics and toughness of composites [17, 18]. Although the utilization of
AC C
nanofiller (especially for carbon nanotube or graphene) effectively reduced the electrical percolation threshold of the CPCs due to the easy formation of conductive networks, the filler loading of CPCs with electromagnetic interference shielding effectiveness (EMI SE) at least 20 dB is still high (10-20 wt%) [19, 20]. For example, about 15wt% graphene loading should be required for CPCs to obtain the EMI SE =21 dB [21] , and when EMI SE improved to 29.3 dB, the graphene loading need to reach 30 wt% [22]. Thus, preparing CPCs with superior EMI SE at low nanofiller loading remain a mission of shouldering heavy responsibilities.
ACCEPTED MANUSCRIPT The construction of segregated structure in CPCs can effectively reduce the electrical percolation threshold and improve electrical conductivity [23-29]. For instance, the segregated structure in a cross-linked carbon nanotube (CNT)/poly(ethylene-co-octene) (POE) composite resulted in a low
RI PT
threshold percolation of 1.5 vol % compared to 9.0 vol % in a conventional CNT/ POE composite [30]. Such segregated architectures also exhibited superior EMI SE to conventional CPCs due to the selective distribution of fillers in the polymer matrices. The thermally reduced
SC
graphene/ultrahigh molecular weight polyethylene (RGO/UHMWPE) composite with segregated
M AN U
structure realized a satisfactory EMI SE of 28.3-32.4 dB at only 0.66vol% filler loading, significantly lower than that of the uniform CPCs [22]. Up to now, the segregated CPCs are mainly prepared by high melt viscosity to prevent the diffusion of electrical filler into their interior, thus mainly limited to UHMWPE [31-33] , crosslinked polymer [11, 34], or amorphous polymers
TE D
under low temperature condition [35, 36]. It is difficult to obtain complete segregated structure in crystalline or semi-crystalline polymers with low-melt-viscosity, such as PP, PA, PET and PLA. Furthermore, the common preparation methods of segregated CPCs, such as mold compressing or
EP
compression molding plus salt-leaching method [22, 37], are not suitable for industrial application
AC C
due to the low productivity. To our knowledge, constructing the segregated structure in low-melt-viscosity crystalline polymer on large scale remains a daunting challenge. On the other hand, excessive consumption and discarding after their service life of fossil-based polymer will lead to serious environment pollution and energy crisis in the near future [38]. Thus, the use of eco-friendly polymer propagates aggressively for the growing need to minimize the carbon footprint in the environment. Compared with other biodegradable polymers (such as poly butylene succinate (PBS), poly-e-caprolactone (PCL) and poly glycolic acid (PGA)), poly(lactic
ACCEPTED MANUSCRIPT acid) (PLA) is considered as the most promising material to substitute for petroleum-based polymer because of its excellent mechanical properties, manipulative degradability and good processibility [39, 40]. However, PLA is a typical semi-crystalline polymer with
RI PT
low-melt-viscosity. It is an enormous challenge to create segregated structure with perfect conductive networks in PLA matrix because the electrical filler may migrate into the polymer interior when temperature exceeds its melting temperature, especially under the external forces.
SC
Fortunately, the PLA stereocomplex crystallite (PLASC) with high melting temperature (Tm) of
M AN U
220℃ is easily formed in the poly L-lactic acid (PLLA) and poly D-lactic acid (PDLA) blends because the multicenter hydrogen bonding interactions between L -lactyl and D -lactyl unit sequences could maintain the two helical chains with the opposite configuration together. While, the Tm of PLA homocrystallites (PLAHC) (about 160-180oC) is relative lower than PLASC.
TE D
Significant difference between Tm of SC and HC makes it possible to establish segregated conductive networks in PLA matrix by controlling the processing temperature. Herein, the PLASC was firstly fabricated from PLLA/PDLA melt blend and then coated with PLLA particles and
EP
multi-wall carbon nanotube (MWCNT) (abbreviate as PLASC@PLLA-MWCNT). Finally, a
AC C
segregated structure PLA composite with perfect conductive networks was successfully prepared by injection-molding technique under various temperatures. Such segregated structure endowed the PLA composite with a much high conductivity of 6.42 Sm-1 and EMI SE value of 27.4 dB at the 3.0 wt% MWCNT loading. More exhilaratingly, the as-prepared composite exhibits steadily increased strength and elongation at break with the MWCNT filler increasing. Furthermore, the effects of injection temperature on morphology, electrical conductivity and the EMI shielding performance of PLASC@PLLA-CNT composite were also investigated.
ACCEPTED MANUSCRIPT 2. Experimental section
2.1 Materials
RI PT
PLLA 4032D and PDLA were purchased from Nature works Co. Ltd. (USA). The weight-average molecular weight (Mw), polydispersity index (PDI) and melting temperature (Tm) of PLLA are 2.23×105 g/mol, 2.10, and 167.4oC, respectively. The corresponding values of PDLA are 8.5×104
SC
g/mol, 1.82, and 176.0oC, respectively. MWCNT was supplied by Nanocyl S.A., Belgium (Nanocyl NC 7000), with average diameter of 9.5nm and average length of 1.5µm. Alcohol and
Reagent Factory (Chengdu, China).
M AN U
dichloromethane (DCM) with analytical grade were purchased from Chengdu Kelong Chemical
2.2 Preparation of PLASC@PLLA-MWCNT segregated composites
TE D
The schematic diagram of the fabrication of PLASC@PLLA-MWCNT segregated composites is shown in Fig.1. Firstly, PLLA and PDLA particles (with weight ratio 1:1) were blended with
EP
Haake torque rheometer (Rheomix 600) at 180oC for 10min, the PLAsc particles with high melting temperature were obtained. 12g PLLA particles were dissolved in 150ml DCM with
AC C
vigorous stirring at room temperature. After completely dissolved, 150ml alcohol was dripped slowly into the PLLA/DCM solution mixture to adjust the solubility parameter. Then 8g PLAsc particles were added and mixed for 10min. Subsequently, another 150ml alcohol was added into the mixture and large amounts of white precipitate appeared immediately. After filter and dry at 50oC for 48h, the PLASC coated with PLLA hybrid particles (PLASC@PLLA) were obtained. Finally, the PLASC@PLLA particles and appropriate amount of MWCNT (weight fraction 0.5, 1.0, 2.0 and 3.0%) were mixed with high-speed mixer and then injected into PLASC@PLLA-MWCNT
ACCEPTED MANUSCRIPT segregated composite specimens. The injection temperature in our experiment fluctuated from 210 to
230oC
to
explore
the
optimal
processing
parameter
for
the
preparation
of
SC
RI PT
PLASC@PLLA-MWCNT segregated composite.
molding method.
2.3 Characterization
TE D
Scanning electron microscopy (SEM)
M AN U
Fig.1 Schematic of the fabrication of the PLASC@PLLA-MWCNT segregated composites using injection
The surface morphologies of the PLAsc and PLASC@PLLA-MWCNT particles were observed by using a field emission scanning electron microscope (Inspect-F, FEI, USA), at an accelerating
EP
voltage of 5.0 kV. The particles were coated with a thin layer of gold beforehand. Cross-sections
AC C
for the SEM observations were obtained by cryo-fracturing the specimens with liquid nitrogen for 30 min.
Differential scanning calorimetry (DSC) Crystallization behavior of PLAsc and PLAsc@PLLA particles was investigated by differential scanning calorimetry on a TA Q2000 instrument. The samples (5-6 mg) were heated from 40 °C to 250 °C at a heating rate of 10 °C/min under nitrogen atmosphere. Crystallinitie (χ) of PLAsc was
ACCEPTED MANUSCRIPT calculated by normalizing their enthalpy to the equilibrium enthalpy of completely crystals, taken as142 J/g for completely crystals PLAsc. The crystallinity (χ) of PLAsc can be calculated as follows:
Where ∆H
and ∆H
∆ ∆
(1)
× 100%
RI PT
χ=
are the enthalpy of 100% PLAsc crystal and the melting enthalpy
measured in experiment, respectively.
SC
For convenience of comparison, the Crystallinitie (χ) of PLAsc in PLAsc@PLLA blend was
M AN U
converted to relative crystallinity (χr) of PLAsc in the pure PLAsc matrix as follows: = Where
is the weight content.
Polarizing Optical Microscopy (POM)
×
(2)
TE D
The segregated structure of composite film was observed by an Olympus BX51 polarizing optical microscopy (Olympus Co., Tokyo, Japan). The film samples were prepared with a thickness of 8 µm by a Leica EMUC6/FC6 microtome.
EP
Measurement of electrical conductivity
AC C
The electrical conductivity of the composite samples was measured using a Keithley electrometer Model 4200-SCS (USA) according to a two-point method. Before the test, both ends of the rectangular specimens were coated with silver paste to reduce the contact resistance between specimens and electrodes.
EMI shielding characteristics EMI shielding measurements were performed with a coaxial test cell (APC-7 connector) in conjunction with an Agilent N5247A vector network analyzer, according to ASTM ES7-83 and
ACCEPTED MANUSCRIPT ASTM D4935-99. The intermediate frequency bandwidth was set as 1 kHz during the measurement and 201 points were collected for each specimen. Samples with a 10 mm diameter and 2 mm thickness were placed in the specimen holder. The scattering parameters (S11 and S21) in
RI PT
the frequency range of 8.2–12.4 GHz were recorded to calculate the reflected power (R), transmitted power (T), absorbed power (A), EMI SE ( SET ), microwave reflection ( SER ) and microwave absorption ( SE A ), using the following equations: 2
2
SC
R = S11 , T = S21 A = 1− R −T
(3)
(4) (5)
SET (dB ) = SER + SE A + SEM
(6)
M AN U
SER (dB ) = −10 log(1 − R ), SE A (dB ) = −10 log(T / (1 − R ))
Where SEM is the microwave multiple internal reflections, which can be negligible when SET
TE D
is higher than10 dB [41]. Mechanical properties testing
The mechanical performance measurements were conducted on a test instrument (Model 5576,
EP
Instron Instruments, USA). For tensile test, the specimens with dimension of 45×5 ×2mm3 were
AC C
conducted with a speed of 20 mm/min. The tensile strength and elongation at break were averaged from 5 samples.
3. Results and discussions
3.1 Morphology and structure of PLASC@PLLA-MWCNT particle
Fig.2 shows the surface SEM morphologies of the PLASC and PLASC@PLLA-MWCNT particles. The as-prepared PLASC particle has irregular and rough geometrical morphology due to the
ACCEPTED MANUSCRIPT melting mixing (Fig.2a and 2b). This particular structure is beneficial to the subsequent coating by PLLA and MWCNT particles. Compared with PLASC particle, PLASC@PLLA-MWCNT particle exhibits larger dimension and roughness (Fig.2c), suggesting the successful coating of the PLLA
RI PT
and MWCNT particles on PLAsc. Abundant and uniformly dispersed MWCNT can be observed from the magnified SEM morphology of PLASC@PLLA-MWCNT particle (Fig.2d). It ensures the
EP
TE D
M AN U
SC
formation of conductive networks in as-prepared PLASC@PLLA-MWCNT segregated composite.
AC C
Fig.2 SEM morphologies of PLAsc ((a) and (b)) and PLAsc@PLLA-MWCNT ((c) and (d)).
To further demonstrates the successful coating of the PLLA particles, melting behavior of the PLAsc and PLAsc@PLLA particles was investigated and their DSC curves are listed in Fig.3.
A
strong melting peak at about 220.0oC and two small peaks at 166.5oC and 174.6oC appeared in the PLAsc curve are corresponded to melting endothermic of PLAsc, PLLA and PDLA crystallite, respectively. It indicates that the overwhelming stereocomplex crystallite with high melting temperature is successfully constructed in the PLLA/PDLA melting blend system, in spite of the
ACCEPTED MANUSCRIPT existence of a small quantity of PLLA and PDLA homocrystallites. On the contrary, the strong peak at 167.4oC and relatively weak peak at 220.0oC can be observed from the PLAsc@PLLA curve. The crystallinity of PLAsc calculated from PLAsc and PLAsc@PLLA curves are 34.48%
RI PT
and 12.31%, respectively. Combining the weight ratio of PLLA/PLAsc (3:2), the relative crystallinity of PLAsc in the PLAsc@PLLA blend was transformed to 30.78%, which is closed to that of PLAsc in pure matrix. Unchanged crystallinity of PLAsc suggested that the PLAsc is not
SC
dissolved in DCM solution during the coating process, which ensures the formation of segregated
AC C
EP
TE D
molding condition (215oC).
M AN U
structure in samples because PLAsc particles (Tm=220oC) are not melted under normal injection
Fig.3 DSC curves of PLASC and PLASC @PLLA particles.
3.2 Effect of injecting temperature on the performances of composites
Melting behavior of PLA is mainly depended on the injecting temperature. The preferable injecting temperature should be ranged from the Tm of PLLA to the Tm of PLAsc. In this case, only the PLLA particles exhibit melt fluidity, while the PLAsc particles still maintain solid state.
ACCEPTED MANUSCRIPT Thus the "sea-island" can be formed naturally in the composites and the MWCNT dispersed only in the continuous PLLA phase, rather than the island PLAsc phase, resulting in the significant improvement of electrical conductivity due to volume exclusion effect. Polarizing microscope
RI PT
images of PLAsc@PLLA-MWCNT composites at different temperature are shown in Fig.4. Perfect segregated structure was established in the composites prepared at relative low temperature (<220oC). The scattered PLAsc phase is bright, while the continuous phase (PLLA)
SC
looks more black and opaque. It indicates the MWCNT fillers selectively dispersed into the
M AN U
continuous phase, rather than uniformly dispersed into all polymer matrices. No apparent difference of segregated structure existed between composites prepared at 210oC and 215oC (Fig.4a and 4b). However, when temperature rises to 220oC (about Tm of PLAsc), the size and total area of the dispersed phase are decreased obviously (Fig.4c). It means that the PLAsc crystal
TE D
begins to melt, which consistent with the DSC analysis. As the temperature rises further to 230oC, "sea-island" structure completely disappeared, and MWCNT fillers uniformly dispersed in whole polymer matrix (Fig.4d). Thus, it concluded that the perfect segregated structure can be obtained
EP
only below the Tm of PLAsc (220oC). At this temperature, MWCNT fillers dispersed in the melted
AC C
PLLA phase, unable to penetrate into the solid PLAsc interior, thus formed perfect segregated structure with conductive networks.
M AN U
SC
RI PT
ACCEPTED MANUSCRIPT
Fig.4 POM images of PLAsc @PLLA-MWCNT (3wt%MWCNT) composites at different temperature.
The SEM images of composites at 215oC and 230oC are showed in Fig.5. Obvious two phase
TE D
sea-island structure exists in the composite injected at 215oC (Fig.5a). A closer inspection reveals that the island phase exhibits a relative rough surface as same as the PLAsc particles (Fig.2),
EP
suggesting the PLAsc particles are not melted in 215oC. Despite the existence of the obvious sea-island structure, the blurry interface between two phases in composite indicates the excellent
AC C
interfacial interaction and adhesion due to the similar molecular structure of PLAsc and PLLA. Homogeneous polymer matrix with relative smooth surface observed in composite prepared at 230oC (Fig.5b) was further proved the melting behavior of PLAsc crystal and the good compatibility between PLAsc and PLLA matrices.
RI PT
ACCEPTED MANUSCRIPT
Fig.5 SEM images of the fractured surface of injection molding composites at different temperature (a): 215oC, (b)
SC
230oC
Fig.6 shows the effect of injection temperature on the electrical conductivity of
M AN U
PLAsc@PLLA-MWCNT composites. The conductivity of the composites firstly increases and then decreases with the injection temperature increasing, and achieves the maximum value of 6.42 S/m at the 215oC. In addition, the fluctuation of conductivity below 215oC is relatively smaller than that above 215oC. The conductivity of composites only increased by 32% (from 4.84 to 6.42
TE D
S/m) when temperature rise from 210 to 215oC. Below the Tm of PLASC (Tm=220℃), MWCNT selectively dispersed in the continuous PLLA phase. With the increase of temperature, the fluidity
EP
of PLLA phase is further enhanced, making MWCNT more evenly dispersed in PLLA, which facilitates to form conductive channels. Thus, conductivity of composites increased. However,
AC C
almost 2.7 times decrease in conductivity was observed when temperature rise from 215 to 220oC. It can be explained by construction and destruction of the segregated structure with conductive networks in composites. When injection temperature below 220oC, segregated structure with good conductive networks was formed due to the infusibility of PLAsc particles, the difference at various injection temperatures is merely the perfection of segregated structure. Therefore, the conductivity fluctuation is relatively small. Whereas, the conductive MWCNT fillers will disperse into the PLAsc particles and the segregated structure gradually destructed at high injection
ACCEPTED MANUSCRIPT temperature (>220oC), results in sudden drop of conductivity. This is consistent with the
M AN U
SC
RI PT
observation from Fig.4 and Fig.5.
Fig.6 Electrical conductivity of PLAsc@PLLA-MWCNT at different injection temperature.
The EMI SE of PLAsc @PLLA-MWCNT composites injected at different temperature are shown in Fig.7. The variation of average EMI SE is essentially in accord with the conductivity of
TE D
composite. The average EMI SE of composite firstly increased from 25.07 dB (210oC) to 27.44 dB (215oC), then rapidly decreased to 17.44 dB (220oC) and 15.61 dB (230oC). This phenomenon
EP
is easily explained by the construction and deconstruction of segregated structure in composites at various temperatures. Interestingly, the EMI SE of composites with perfect segregated structure
AC C
(210oC and 215oC) exhibits a weak dependence on frequency, whereas the transitional (220oC) and homogeneous structure composites (230oC) show strong dependence on frequency. The resonance absorption peak shifts toward the higher frequency with the increase of temperature. This could be understood in terms of the factor that the employment of the electrical loss spacers would essentially vary the dielectric constant of the transport medium, which results in the changes in wave length and velocity. Such phenomena is in accordance with the some previous researches [42-44]. In addition, the comparison of SET (total EMI SE), SEA (microwave
ACCEPTED MANUSCRIPT absorption) and SER (microwave reflection) for various composites at the frequency of 8.2GHz (Fig.7b) indicates that the contribution of absorption to the total EMI SE is much larger than that from reflection in all prepared composites. To give a comprehensive understanding of the
RI PT
microwave attenuation mechanism, the power coefficient of reflectivity (R), transmissivity (T), and absorptivity (A) are obtained from the measured scattering parameters (S11, S21) as shown in Figure 7c. With increasing the injected temperature, T value increases noticeably, R value
SC
significantly decreases in initial and then slightly increases, and A value exhibits small changes.
M AN U
This is mainly attributed to the destruction of the segregated structure in composites at high injection temperature (>220oC). Whatever, the composite prepared at 215oC exhibits high EMI SE, broad shielding frequency range and excellent absorption characteristics. Therefore, the optimal
EP
TE D
injection temperature was fixed at 215oC.
AC C
Fig. 7 EMI SE properties of PLAsc@PLLA-MWCNT composites (3wt%MWCNT) injected at different
temperature. (a) EMI SE as a function of frequency; (b) Comparison of SET, SEA and SER at the frequency of 8.2 GHz; (c) Coefficients of reflection (R), absorption (A), and transmittance (T) at 8.2 GHz.
3.3 The effects of MWCNT contents on the performances of composites
The POM images of PLAsc@PLLA-MWCNT composites with various MWCNT contents injected at 215oC are shown in Fig.8. As a dispersed phase, the infusible PLAsc particles are
ACCEPTED MANUSCRIPT surrounded by the opaque PLLA+MWCNT phase. Because the MWCNT filler are merely dispersed in the continuous PLLA phase, the conductive network is easily constructed in PLLA phase due to the excluded volume effect. Therefore, segregated structure can be observed in all
RI PT
composite samples and the conductive paths are constantly improved with the MWCNT filler increasing. Nevertheless, the perfect conductive networks are still not constructed in Fig.8a because of the low filler contents. The conductivities of composites with various MWCNT
SC
contents are shown in Fig.9. Rapid increase of the conductivity of composite at relative low
M AN U
MWCNT loading implies the establishment of the conductive paths. The conductivity of PLA increases from 10-15 S/m to 2.84×10-9 S/m at 0.5 wt% and 0.09 S/m at 1.0 wt% MWCNT loading, respectively, almost 6 and 13 orders of magnitude increasement. Thereafter, the conductivity of composites increases slowly with the MWCNT filler increasing. It suggests that the prepared
TE D
composites exhibit a typical percolation behavior and is usually evaluated with power-law equation, i.e. σ = σ 0 (φ − φc ) . Where t
σ , σ 0 , φ and φc is the electrical conductivity of
composite, constant conductivity associated with the intrinsic characteristic of MWCNT, volume
EP
content of the MWCNT filled in composites, and the percolation threshold (the minimum contents
AC C
of filler to construct the electrical path in composite), respectively. t represents a critical exponent related to dimensionality. The fitted curve of Logσ vs Log (φ − φc ) is listed in the inset of Fig.9. 0.44 vol% percolation threshold obtained from the fitted curve indicates the conductive networks are cost-effectively established in segregated composites with high efficiency. Thus, it means that the perfect electrical networks exist in composites when the filler loading exceed 0.44 vol% (about 0.8 wt%). This is consistent with the observation from Fig.8. Once formed the conductive network, the improvement of composite conductivity is indistinctive with the filler
ACCEPTED MANUSCRIPT increasing. Even so, the conductivity of prepared PLA segregated composite with 3 wt% MWCNT
M AN U
SC
RI PT
reaches 6.42 S/m, completely meet the practical application in EMI shielding.
TE D
Fig.8 POM images of PLAsc@ PLLA-MWCNT composites with different MWCNT contents. (a) 0.5 wt%; (b)1.0
AC C
EP
wt%; (c) 2.0 wt%; (d) 3.0 wt%.
Fig.9 Electrical conductivity of the PLAsc@ PLLA-MWCNT composites as a function of MWCNT contents.
ACCEPTED MANUSCRIPT Fig.10 shows the EMI SE properties of segregated composites with different filler loading. The EMI SE continues to increase with the MWCNT filler increasing, especially for the composites with relative high filler loading. With the addition of 3 wt% MWCNT, the maximum and the
RI PT
average EMI SE of composites reach up to 31.02 and 27.44dB. More importantly, the EMI SE beyond 25 dB in frequency range of 8 to 12GHz suggested that the prepared composite can meet the requirements of traditional electromagnetic shielding materials [13]. To further understand the
SC
mechanism of electromagnetic shielding, SET, SEA and SER of composites with various filler
M AN U
loading at the frequency of 8.2 GHz are calculated and were listed in Fig.10b. The SET and the SEA are obviously enhanced with increasing MWCNT filler content. However, the SER exhibits a strong independence on MWCNT filler contents. With the 3wt% MWCNT loading, the value of SEA reaches 28.11dB, almost 90.62% of SET, indicating the absorption dominant shielding
TE D
mechanism rather than reflection in the prepared composites. According to the power balance of T, R, and A versus incident power (as shown in Figure 10c), T value decrease significantly, R value increases noticeably, and A value first slightly increased and then decreased as the filler content
EP
increasing. It is attributed to the unique segregated structure. At the low filler contents, the perfect
AC C
conductive networks are not constructed, which allows more electromagnetic waves penetrating through the composite and therefore results in a high T value. Thereafter, segregated structure can be constructed and the conductive paths are constantly improved with the filler increasing. Thus, T value decreases sharply and the composites exhibits excellent shielding characteristics. The PLAsc particles without MWCNT filler can be considered as a “skin” of shielding materials, and PLLA-MWCNT phase with high conductivity act as inner absorption and reflecting layer. The electromagnetic microwaves are easily propagated into the “skin” due to the impedance matching
ACCEPTED MANUSCRIPT of non-conductive PLAsc particles. Subsequently, the incident electromagnetic microwaves will be attenuated in the PLLA-MWCNT phase by reflecting, adsorption and scattering many times. Electromagnetic microwaves are “trapped” in the closed conductive network and is difficult to
RI PT
penetrate this reflecting layer. This shielding mechanism has been reported in our previous
M AN U
SC
researches [22, 25, 26, 37].
Fig.10 EMI SE properties of PLAsc@PLLA-MWCNT composites molded at different melt temperature. (a) EMI
SE as a function of frequency; (b) Comparison of SET, SEA and SER at the frequency of 8.2 GHz. (c) Coefficients of R, A and T at 8.2 GHz.
TE D
The mechanical property is a major parameter for evaluating the application of CPCs shielding materials. Generally, the mechanical properties of composite, including tensile strength and
EP
elongation at break, significantly deteriorated in the presence of the segregated structure due to the weak interfaces. Therefore, the tensile performance of the prepared segregated composites with
AC C
various MWCNT loading was measured and the results are plotted in Fig.11. Pure PLAsc matrix exhibits a typical brittle fracture behavior, without obvious yielding phenomenon, which is attributed to the special crystal texture of PLAsc [45]. The tensile strength and elongation at break of PLAsc matrix are only 39.14MPa and 1.78%, respectively. While an apparent two yielding existed in the strain-stress curve of PLLA matrix. The tensile strength and elongation at break can reach 70.78MPa and 5.13%, respectively. Interestingly, the strength and elongation at break of the PLLA@PLAsc-MWCNT composites increased with the MWCNT filler content increasing. With
ACCEPTED MANUSCRIPT the addition of 3wt% MWCNT, increments of 32.70% and 67.17% were obtained for the tensile strength and elongation at break; increased from 43.73MPa (PLAsc@PLLA) to 58.03MPa and from 1.98% (PLAsc@PLLA) to 3.31%, respectively. The improvement of strength and elongation
RI PT
of composites may be ascribed to the excellent mechanical performance of MWCNT, toughening modification of PLAsc particles and excellent interfacial adhesion between PLLA and PLAsc (as shown in Fig5a). As continuous phase, PLLA matrix bears most of the external load and therefore
SC
some microcracks initiated and propagated in PLLA matrix when the applied load exceeds its
M AN U
breaking strength. Once the propagated microcrack encountered the stiff PLAsc particles, the crack propagation path may be changed. Particle reinforcement, crack deflection and particle pullout are the main toughening mechanisms. Due to the excellent interfacial adhesion between PLLA and PLAsc, the PLAsc@PLLA composite exhibits superior strength and toughness to
TE D
PLAsc. Furthermore, with the increase of MWCNT concentration, the strength and deformability of the PLLA-MWCNT phase was gradually increased. The breaking point of the PLAsc @PLLA-MWCNT composites lied on the strain-stress curves of PLLA matrix and the special two
EP
yielding appeared in the composites containing high MWCNT loading. This indicates that the
AC C
tensile strength and elongation at break is mainly determined by PLLA–MWCNT phase. In other words, the brittle rupture is not occurred in PLAsc@PLLA-MWCNT composite because the stress concentration on crack tip eliminated by dispersed PLAsc particles. The schematic diagram of the toughening and reinforcing mechanism is shown in Fig.12. Regardless, this large-scale produced composite exhibits not only the good electromagnetic shielding effectiveness, but also excellent mechanical properties with low MWCNT loading. Together with the PLA degradation performance, this approach provides a novel idea for manufacting new high EMI shielding
ACCEPTED MANUSCRIPT
SC
RI PT
materials with both toughness and degradation.
Fig.11 Strain-stress curves of PLLA, PLAsc and PLAsc@ PLLA-MWCNT composites with various MWCNT
AC C
EP
TE D
M AN U
content.
Fig.12 The schematic diagram of the toughening and reinforcing mechanism.
4. Conclusion
Segregated structure PLA conductive composites with efficient EMI shielding performance and favourable mechanical properties were easily fabricated by injection molding from PLAsc, PLLA and MWCNT particles. Due to the selective dispersion of conductive MWCNT filler in the
ACCEPTED MANUSCRIPT continuous PLLA phase, good conductivity and high EMI SE were achieved under low MWCNT content. Moreover, enhanced tensile strength and toughness was simultaneously obtained because of the excellent interfacial adhesion between PLLA and PLAsc. With the additional of 3 wt%
RI PT
MWCNT, the EMI SE reached 31.02 dB at the frequency of 8.2 GHz, the tensile strength increased from 43.73 to 58.03 MPa and elongation at break increased from 1.98 to 3.31%. Our work reveals a major breakthrough in creating a segregated conductive network structure in
M AN U
friendly, and highly efficient EMI shielding composites.
SC
low-melt-viscosity polymers on large scale, further developing economical, environmentally
Acknowledgements
This work was supported by National Natural Science Foundation of China (Grant No. 21706208, 51773167, 21704070), the Natural Science Foundation of Shaanxi Province, China (Grant No.
TE D
2017JQ5065), the Opening Project of State Key Laboratory of Polymer Materials Engineering (Sichuan University) (Grant No. sklpme2017-4-13).
References
EP
[1] Shahzad F, Alhabeb M, Hatter CB, Anasori B, Man Hong S et al. Electromagnetic interference
AC C
shielding with 2D transition metal carbides (MXenes). Science 2016; 353:1137-40. [2] Jia LC, Yan DX, Liu XF, Ma RJ, Wu HY, Li ZM. Highly efficient and reliable transparent electromagnetic interference shielding film. Acs Appl Mater Inter 2018; 10(14):11941-49.
[3] Song WL, Wang J, Fan LZ, Li Y, Wang CY, Cao MS. Interfacial engineering of carbon nanofiber-graphene-carbon nanofiber heterojunctions in flexible lightweight electromagnetic shielding networks. Acs Appl Mater Inter 2014; 6(13):10516-23. [4] Liu J, Zhang HB, Sun RH, Liu YF, Liu ZS, Zhou AG, et al. Hydrophobic, flexible, and
ACCEPTED MANUSCRIPT lightweight MXene foams for high‐performance electromagnetic‐interference shielding. Adv Mater 2017; 29(38):1702367. [5] Jia LC, Li MZ, Yan DX, Cui CH, Wu HY, Li ZM. A strong and tough polymer-carbon
RI PT
nanotube film for flexible and efficient electromagnetic interference shielding. J Mater Chem C 2017; 5(35):8944-51.
[6] Wang H, Zheng K, Zhang X, Ding X, Zhang ZX, Bao C, et al. 3D network porous polymeric
SC
composites with outstanding electromagnetic interference shielding. Compos Sci Technol
M AN U
2016; 125:22-9.
[7] Chen Y, Zhang HB, Huang YQ, Jiang Y, Zheng WG, Yu ZZ. Magnetic and electrically conductive epoxy/graphene/carbonyl iron nanocomposites for efficient electromagnetic interference shielding. Compos Sci Technol 2015; 118:178-85.
TE D
[8] Hsiao ST, Ma CM, Tien HW, Liao WH, Wang YY, Li SM. Effect of covalent modification of graphene nanosheets on the electrical property and electromagnetic interference shielding performance of a water-borne polyurethane composite. Acs Appl Mater Inter 2015;
EP
7(4):2817-26.
AC C
[9] Jing QF, Law JY, Tan LP, Silberschmidt VV, Li L, Dong ZL. Preparation, characterization and properties of polycaprolactone diol-functionalized multi-walled carbon nanotube/ thermoplastic polyurethane composite. Compos Part A 2015; 70:8-15.
[10] Qing YC, Min DD, Zhou YH, Luo F, Zhou WC. Graphene nanosheet- and flake carbonyl iron particle-filled epoxy–silicone composites as thin–thickness and wide-bandwidth microwave absorber. Carbon 2015; 86:98-107. [11] Jia LC, Yan DX, Cui CH, Jiang X, Ji X, Li ZM. Electrically conductive and electromagnetic
ACCEPTED MANUSCRIPT interference shielding of polyethylene composites with devisable carbon nanotube networks. J Mater Chem C 2015; 3(36):9369-78. [12] Ren F, Song DP, Li Z, Jia LC, Zhao YC, Yan DX, et al. Synergistic effect of graphene
RI PT
nanosheets and carbonyl iron nickel alloy hybrid filler on electromagnetic interference shielding and thermal conductivity of cyanate ester composites. J Mater Chem C 2018; 6(6):1476-86.
SC
[13] Thomassin J, Jérôme C, Pardoen T, Bailly C, Huynen I, Detrembleur C. Polymer/carbon
M AN U
based composites as electromagnetic interference (EMI) shielding materials. Mater Sci Eng R. 2013; 74(7):211-32.
[14] Zeng ZH, Jin H, Chen MJ, Li WW, Zhou LC, Zhang Z. Lightweight and anisotropic porous MWCNT/WPU composites for ultrahigh performance electromagnetic interference shielding.
TE D
Adv Funct Mater 2016; 26(2):303-10.
[15] Zhang HM, Zhang GC, Li JT, Fan X, Jing ZX, Li JW, et al. Lightweight, multifunctional microcellular
PMMA/
Fe3O4
@MWCNTs
nanocomposite
foams
with
efficient
EP
electromagnetic interference shielding. Compos Part A–Appl S 2017; 100:128-38.
AC C
[16] Sun XM, Sun H, Li HP, Peng HS. Developing polymer composite materials: carbon nanotubes or graphene? Adv Mater 2013; 25(37):5153-76.
[17] Chen ZP, Ren WC, Gao LB, Liu BX, Pei SF, Cheng HM. Three-dimensional flexible and conductive interconnected graphene networks grown by chemical vapour deposition. Nat Mater 2011; 10(6):424-8. [18] Gui XC, Li HB, Zhang LH, Jia Y, Liu L, Li Z, et al. A Facile Route to Isotropic Conductive Nanocomposites by Direct Polymer Infiltration of Carbon Nanotube Sponges. Acs Nano
ACCEPTED MANUSCRIPT 2011; 5(6):4276-83. [19] Ling JQ, Zhai WT, Feng WW, Shen B, Zhang JF, Zheng WG. Facile preparation of lightweight microcellular polyetherimide/graphene composite foams for electromagnetic
RI PT
interference shielding. Acs Appl Mater Inter 2013; 5(7):2677-84. [20] Arjmand M, Apperley T, Okoniewski M, Sundararaj U. Comparative study of electromagnetic interference shielding properties of injection molded versus compression multi-walled
carbon
nanotube/polystyrene
composites.
SC
molded
M AN U
50(14):5126-34.
Carbon
2012;
[21] Liang JJ, Wang Y, Huang Y, Ma YF, Liu ZF, Cai JW, et al. Electromagnetic interference shielding of graphene/epoxy composites. Carbon 2009; 47(3):922-5. [22] Yan DX, Ren PG, Pang H, Fu Q, Yang MB, Li ZM. Efficient electromagnetic interference of
22(36):18772-4.
lightweight graphene/polystyrene
composite.
J
Mater Chem 2012;
TE D
shielding
[23] Pang H, Xu L, Yan DX, Li ZM. Conductive polymer composites with segregated structures.
EP
Prog Polym Sci 2014; 39(11):1908-33.
AC C
[24] Sharif F, Arjmand M, Moud AA, Sundararaj U, Roberts EP. Segregated hybrid poly(Methyl Methacrylate)/graphene/magnetite nanocomposites for electromagnetic interference shielding. Acs Appl Mater Inter 2017; 9(16):14171-9.
[25] Yan DX, Pang H, Li B, Vajtai R, Xu L, Ren PG, et al. Structured reduced graphene oxide/polymer composites for ultra‐efficient electromagnetic interference shielding. Adv Funct Mater 2015; 25(4):559-66. [26] Wu HY, Jia LC, Yan DX, Gao JF, Zhang XP, Ren PG, et al. Simultaneously improved
ACCEPTED MANUSCRIPT electromagnetic interference shielding andmechanical performance of segregated carbon nanotube/polypropylene composite via solid phase molding. Compos Sci Technol 2018; 156:87-94.
RI PT
[27] Wang H, Zheng K, Zhang X, Du TX, Xiao C, Ding X, et al. Segregated poly(vinylidene fluoride)/MWCNTs composites for high-performance electromagnetic interference shielding. Compos Part A–Appl S 2016; 90:606-13.
SC
[28] Zhai W, Zhao SG, Wang Y, Zheng GQ, Dai K, Liu CT, Shen CY. Segregated conductive
A–Appl S, 2018, 105: 68-77.
M AN U
polymer composite with synergistically electrical and mechanical properties. Compos Part
[29] Zhao SG, Lou DD, Zhan PF, Li GJ, Dai K, Guo J, Zheng GQ, Liu CT, Shen CY, Guo ZH. Heating-induced negative temperature coefficient effect in conductive graphene/polymer
TE D
ternary nanocomposites with a segregated and double-percolated structure. Journal of Materials Chemistry C, 2017, 5: 8233-8242. [30] Li T, Ma LF, Bao RY, Qi GQ, Yang W, Xie BH, et al. A new approach to construct
EP
segregated structures in thermoplastic polyolefin elastomers towards improved conductive
AC C
and mechanical properties. J Mater Chem A 2015; 3(10):5482-90. [31] Hu HL, Zhang G, Xiao LG, Wang HJ, Zhang QS, Zhao ZD. Preparation and electrical conductivity of graphene/ultrahigh molecular weight polyethylene composites with a segregated structure. Carbon 2012; 50(12):4596-9.
[32] Cui CH, Pang H, Yan DX, Jia LC, Jiang X, Lei J, et al. Percolation and resistivity-temperature behaviours of carbon nanotube-carbon black hybrid loaded ultrahigh molecular weight polyethylene composites with segregated structures. RSC Adv 2015;
ACCEPTED MANUSCRIPT 5(75):61318-23. [33] Pang H, Yan DX, Bao Y, Chen JB, Chen C, Li ZM. Super-tough conducting carbon nanotube/ultrahigh-molecular-weight
polyethylene
composites
with
segregated
and
RI PT
double-percolated structure. J Mater Chem 2012; 22(44):23568-75. [34] Zhan YH, Lavorgna M, Buonocore GG, Xia HS. Enhancing electrical conductivity of rubber
mixing. J Mater Chem 2012; 22(21):10464-8.
SC
composites by constructing interconnected network of self-assembled graphene with latex
M AN U
[35] Yoonessi M, Gaier JR. Highly conductive multifunctional graphene polycarbonate nanocomposites. Acs Nano 2010; 4(12):7211-20.
[36] Jin Y, Gerhardt RA. Percolation and electrical conductivity modeling of novel microstructured insulator-conductor nanocomposites fabricated from PMMA and ATO. Mrs
TE D
Proce 2014; 1692(4):22264-71.
[37] Xu L, Jia LC, Yan DX, Ren PG, Xu JZ, Li ZM. Efficient electromagnetic interference shielding of lightweight carbon nanotube/polyethylene composites via compression molding
EP
plus salt-leaching. Rsc Adv 2018; 8(16):8849-55.
AC C
[38] Huang HD, Liu CY, Li D, Chen YH, Zhong GJ, Li ZM. Ultra-low gas permeability and efficient reinforcement of cellulose nanocomposite films by well-aligned graphene oxide nanosheets. J Mater Chem A 2014; 2(38):15853-63.
[39] Maharana T, Pattanaik S, Routaray A, Nath N, Sutar AK. Synthesis and characterization of poly(lactic acid) based graft copolymers. React Funct Polym 2015; 93:47-67. [40] Tan BH, Muiruri JK, Li ZB, He CB. Recent progress in using stereocomplexation for enhancement of thermal and mechanical property of polylactide. Acs Sustain Chem Eng
ACCEPTED MANUSCRIPT 2016; 4(10):5370-91. [41] Gupta TK, Singh BP, Dhakate SR, Singh VN, Mathur RB. Improved nanoindentation and microwave shielding properties of modified MWCNT reinforced polyurethane composites. J
RI PT
Mater Chem A 2013; 1(32):9138-49. [42] Yan DX, Pang H, Xu L, Bao Y, Ren PG, Lei J, et al. Electromagnetic interference shielding
graphene oxide. Nanotechnology 2014; 25(14):145705.
SC
of segregated polymer composite with an ultralow loading of in situ thermally reduced
M AN U
[43] Yu WC, Xu JZ, Wang ZG, et al. Constructing highly oriented segregated structure towards high-strength carbon nanotube/ultrahigh-molecular-weight polyethylene composites for electromagnetic interference shielding. Compos Part A–Appl S 2018; 110: 237-45. [44] Song WL, Zhou Z, Wang LC, et al. Constructing Repairable Meta-Structures of
TE D
Ultra-Broad-Band Electromagnetic Absorption from Three-Dimensional Printed Patterned Shells. Acs Appl Mater Inter 2017; 9(49): 43179-87. [45] Tsuji H. Poly (lactic acid) stereocomplexes: A decade of progress. Adv Drug Deliver Rev
AC C
EP
2016; 107:97-135.
ACCEPTED MANUSCRIPT Highlights: 1. Segregated structure PLA conductive composites were easily fabricated by injection molding from PLASC, PLLA and MWCNT particles.
RI PT
2. The prepared composite exhibited good conductivity and high EMI SE under low MWCNT content due to the selective dispersion of the conductive MWCNT in the continuous PLLA
SC
phase.
3. Similar molecular structure between PLLA and PLASC endowed excellent interfacial
AC C
EP
TE D
M AN U
adhesion, thus results in favourable mechanical properties of composites.