Publications Prior to Beihang (2006–2012)

2012 | 2011 | 2010 | 2009 | 2008 | 2006

2012

  1. Comparative Characterization of Multiscale Carbon Fiber Composite with Long and Short MWCNTs at Higher Weight Fractions
    Michael Zimmer*, Qunfeng Cheng, Shu Li, James Brooks, Richard Liang, Ben Wang, and Chuck Zhang
    J. Nanomater., 2012, 532080. DOl: 10.1155/2012/532080
    Abstract
    There are documented advantages to using carbon nanotubes (CNTs) in composites for various property enhancements. However, to date, only limited studies have been conducted on using of longer CNTs over 1 mm in length. This study used long multiwalled carbon nanotubes (LMWCNTs) and their longer extended networks to test multiple properties in thermal conductivity, electrical conductivity, mechanical strength, and modulus and then compared these properties to those of shorter multi-walled carbon nanotubes (SMWCNTs). For carbon fiber-reinforced composites, the longer graphite paths from LMWCNTs in the matrix were expected to improve all properties. The longer networks were expected to allow for more undisturbed phonon transportation to improve thermal conductivity. This in turn relates to improved electrical conductivity and better mechanical properties. However, results have shown that the LMWCNTs do not improve or decrease thermal conductivity, whereas the shorter MWCNTs provide mixed results. LMWCNTs did show improvements in electrical, mechanical, and physical properties, but compared to shorter MWCNTs, the results in other certain properties varied. This perplexing outcome resides in the functioning of the networks made by both the LMWCNTs and shorter MWCNTs.
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  2. Preform-based toughening technology for RTMable high-temperature aerospace composites
    Xiao-Su Yi*, Qunfeng Cheng, and Zhizhen Liu
    Sci. China-Technol. Sci., 2012, 55, 2255-2263. DOI: 10.1007/s11431-012-4949-8
    Abstract
    This article describes the efforts that led to the development of surface-loaded preforms that may be used to significantly improve the compression-after-impact strength of high-temperature composites and correspondingly to dramatically reduce the area of damage because of impact. Moreover, by matching the toughening polymer surface-loaded and design of the surface pattern, in-plane mechanical properties are unaffected or even improved over laminates made from the identical materials. The proprietary preforms, so-called ES™-Fabrics, may be handled and infused with the high-temperature RTMable resins such as bismaleimide and polyimide in exactly the same manner as traditional fabrics without surface modification. The RTM conditions for the preform-based toughening is fully compatible with the traditional process procedure, making the technology cost-effective in production. This technology represents a key enabler for the use of low-cost RTM processes for high-temperature resins to supplant prepreg as the building-block material of choice for aeronautical composite structures.
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  3. Thermal conductivity of MWCNT/epoxy composites: The effects of length, alignment and functionalization
    Jin Gyu Parka*, Qunfeng Cheng, Jun Lu, Jianwen Bao, Shu Lia, Ying Tian, Zhiyong Liang*, Chuck Zhang, and Ben Wang
    Carbon, 2012, 50, 2083-2090. DOI: 10.1016/j.carbon.2011.12.046
    Abstract
    Carbon nanotubes (CNTs) show great promise to improve composite electrical and thermal conductivity due to their exceptional high intrinsic conductance performance. In this research, long multi-walled carbon nanotubes (long-MWCNTs) and its thin sheet of entangled nanotubes were used to make composites to achieve higher electrical and thermal conductivity. Compared to short-MWCNT sheet/epoxy composites, at room temperature, long-MWCNT samples showed improved thermal conductivity up to 55 W/mK. The temperature dependence of thermal conductivity was in agreement with κ ∝ Tn (n = 1.9-2.3) below 150 K and saturated around room temperature due to Umklapp scattering. Samples with the improved CNT degree of alignment by mechanically stretching can enhance the room temperature thermal conductivity to over 100 W/mK. However, functionalization of CNTs to improve the interfacial bonding resulted in damaging the CNT walls and decreasing the electrical and thermal conductivity of the composites.
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  4. In situ characterization of structural changes and the fraction of aligned carbon nanotube networks produced by stretching
    Shu Lia, Jin Gyu Park, Zhiyong Liang*, Theo Siegrist, Tao Liu, Mei Zhang, Qunfeng Cheng, Ben Wang, and Chuck Zhang
    Carbon, 2012, 50, 3859-3867. DOI: 10.1016/j.carbon.2012.04.029
    Abstract
    The mechanism of carbon nanotube (CNT) alignment during stretching was examined by the in situ characterization of carbon nanotube networks (CNTNs) under tensile strains using X-ray and Raman scattering techniques. A method of quantifying the inhomogeneous alignment of macroscopic CNTNs is explored based on bulk property measurements of their electrical anisotropy and X-ray diffraction diagrams. The results show that the process of stretch-induced alignment of CNTNs included straightening the waviness of the long nanotube ropes, as well as the self-assembling and denser packing of the nanotubes. For samples at a strain of 40%, the fraction of aligned nanotubes was as high as 0.85. The aligned fraction of CNTs serves as an important parameter for the quality control of the alignment process and numerical simulations of structure–property relationships of CNTNs and their composites.
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2011

  1. Janus interface materials: superhydrophobic air/solid interface and superoleophobic water/solid interface inspired by a lotus leaf
    Qunfeng Cheng, Mingzhu Li, Yongmei Zheng, Bin Su, Shutao Wang*, and Lei Jiang
    Soft Matter, 2011, 7, 5948-5951. DOI: 10.1039/C1SM05452J
    Abstract
    We discovered underwater superoleophobicity on the lower side of a lotus leaf, and fabricated Janus interface materials with in-air superhydrophobicity on one side and underwater superoleophobicity on the other side inspired by the Janus feature of the lotus leaf. The ingenious design on lotus leaf surfaces, superhydrophobicity on its upper side and underwater superoleophobicity on its lower side, not only helps us thoroughly understand the special surface wettability of the lotus leaf, but also gives a typical example of multi-functionality in biological systems. This study supplies us with an intelligent strategy to design and create bionic multi-functional interface materials.
    PDF | Supplementary Information
  2. Highly reflective superhydrophobic white coating inspired by poplar leaf hairs toward an effective “cool roof”
    Changqing Ye, Mingzhu Li*, Junping Hu, Qunfeng Cheng, Lei Jiang, and Yanlin Song*
    Energy Environ. Sci., 2011,4, 3364-3367. DOI: 10.1039/C0EE00686F
    Abstract
    The hair layer consisting of hollow fibers provides the poplar leaf with an energy efficient “cool roof” to protect it from being burned by strong light. Inspired by the hair structure, we use coaxial electro-spinning technology to achieve a highly reflective and superhydrophobic white coating towards making an eco-friendly and effective “cool roof”.
    PDF | Supplementary Information

2010

  1. Carbon nanotube/epoxy composites fabricated by resin transfer molding
    Qunfeng Cheng, Jiaping Wang*, Jiajia Wen, Changhong Liu, Kaili Jiang, and Shoushan Fan
    Carbon, 2010, 48, 260-266. DOI: 10.1016/j.carbon.2009.09.014
    Abstract
    Carbon nanotube (CNT)/epoxy composites with controllable alignment of CNTs were fabricated by a resin transfer molding process. CNTs with loading up to 16.5 wt.% were homogenously dispersed and highly aligned in the epoxy matrix. Both mechanical and electrical properties of the CNT/epoxy composites were dramatically improved with the addition of the CNTs. The Young’s modulus and tensile strength of the composites reach 20.4 GPa and 231.5 MPa, corresponding to 716% and 160% improvement compared to pure epoxy. The electrical conductivity of the composites along the direction of the CNT alignment reaches over 1 × 104 S/m.
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  2. Functionalized Carbon-Nanotube Sheet/Bismaleimide Nanocomposites: Mechanical and Electrical Performance Beyond Carbon-Fiber Composites
    Qunfeng Cheng, Ben Wang, Chuck Zhang, and Zhiyong Liang*
    Small, 2010, 6, 763-767. DOI: 10.1002/smll.200901957
    Abstract
    Since their discovery in 1991, carbon nanotubes (CNTs) have been considered as the next-generation reinforcement materials to potentially replace conventional carbon fibers for producing super-high-performance lightweight composites. Herein, it is reported that sheets of millimeter-long multi-walled CNTs with stretch alignment and epoxidation functionalization reinforce bismaleimide resin, which results in composites with an unprecedentedly high tensile strength of 3081 MPa and modulus of 350 GPa, well exceeding those of state-of-the-art unidirectional carbon-fiber-reinforced composites. The results also provide important experimental evidence of the impact of functionalization and the effect of alignment reported previously on the mechanical performance and electrical conductivity of the nanocomposites.
    PDF | Supplementary Information

2009

  1. The fabrication of single-walled carbon nanotube/polyelectrolyte multilayer composites by layer-by-layer assembly and magnetic field assisted alignment
    Ying Tian, Jin Gyu Park, Qunfeng Cheng, Zhiyong Liang*, Chuck Zhang, and Ben Wang
    Nanotechnology, 2009, 20, 335601. DOI: 10.1088/0957-4484/20/33/335601
    Abstract
    Single-walled carbon nanotube (SWNT)/polymer composites are widely studied because of their potential for high mechanical performance and multifunctional applications. In order to realize highly ordered multilayer nanostructures, we combined the layer-by-layer (LBL) assembly method with magnetic force-induced alignment to fabricate SWNT/poly(ethylamine) (PEI) multilayer composites. The SWNTs were functionalized with the anionic surfactant sodium dodecylbenzenesulfonate (NaDDBS) to realize negative charge at pH>7, while the PEI is positively charged at pH<7. The LBL method is based on the electrostatic absorption between the charged SWNTs and PEI resin to form multilayer composites on a solid substrate polydimethylsiloxane. Since the fabricated thickness of each SWNT-NaDDBS/PEI bilayer is uniform (~150 nm), the multilayer film thickness can be strictly controlled via the number of deposition cycles. A high magnetic field (8.5 Tesla) was used to align the SWNTs during the LBL process. The resultant LBL composite samples demonstrated high SWNT loading of approximately 50 wt% and uniform distribution of SWNTs in the multilayer structures, which was verified using a quartz crystal microbalance. Good alignment was also realized and observed through using high magnetic fields to align the nanotubes during the LBL deposition process. The results indicate that the LBL/magnetic alignment approach has potential for fabricating nanotube composites with highly ordered nanostructures for multifunctional materials and device applications.
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  2. Electromagnetic interference shielding properties of carbon nanotube buckypaper composites
    Jin Gyu Park*, Jeffrey Louis, Qunfeng Cheng, JianwenBao, Jesse Smithyman, Richard Liang,Ben Wang, Chuck Zhang, James S Brooks, Leslie Kramer,  Percy Fanchasis, and David Dorough
    Nanotechnology, 2009, 20, 415702. DOI: 10.1088/0957-4484/20/41/415702
    Abstract
    Preformed carbon nanotube thin films (10-20 µm), or buckypapers (BPs), consist of dense and entangled nanotube networks, which demonstrate high electrical conductivity and provide potential lightweight electromagnetic interference (EMI) solutions for composite structures. Nanocomposite laminates consisting of various proportions of single-walled and multi-walled carbon nanotubes, having different conductivity, and with different stacking structures, were studied. Single-layer BP composites showed shielding effectiveness (SE) of 20-60 dB, depending on the BP conductivity within a 2-18 GHz frequency range. The effects on EMI SE performance of composite laminate structures made with BPs of different conductivity values and epoxy or polyethylene insulating layer stacking sequences were studied. The results were also compared against the predictions from a modified EMI SE model. The predicted trends of SE value and frequency dependence were consistent with the experimental results, revealing that adjusting the number of BP layers and appropriate arrangement of the BP conducting layers and insulators can increase the EMI SE from 45 dB to close to 100 dB owing to the utilization of the double-shielding effect.
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  3. Morphological and Spatial Effects on Toughness and Impact Damage Resistance of PAEK-toughened BMI and Graphite Fiber Composite Laminates
    Qunfeng Cheng, Zhengping Fang, Yahong Xu, and Xiao-Su Yi*
    Chin. J. Aeronaut., 2009, 22, 87-96. DOI: 10.1016/S1000-9361(08)60073-4
    Abstract
    The microstructure property relationships have been studied in terms of glass transition behavior, phase morphology, and fracture toughness on thermoplastic polyetherketone with a phenolphthalein side group (PAEK) toughened bismaleimdes (BMI) resins, and in terms of interlaminar morphology and compression after impact (CAI) on the graphite fiber (T700SC), the reinforced BMI matrix composites that are toughened with a so-called ex-situ concept, respectively. The characteristic morphology spectrum has been found to occur as the concentration of PAEK is varied. In particular, the relationship between the morphology and the fracture toughness has been explored on the PAEK-BMI blends. The fracture micromechanism has then been used to explain the delamination and impact damage behavior on the graphite laminated systems, where the morphology properties relationship held true. The complex nature of the diffusion-controlled phase behavior has also qualitatively been studied, which served as a model for understanding the ex-situ toughening concept.
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  4. High Mechanical Performance Composite Conductor: Multi-Walled Carbon Nanotube Sheet/Bismaleimide Nanocomposites
    Qunfeng Cheng, Jianwen Bao, JinGyu Park, Zhiyong Liang*, Chuck Zhang, and Ben Wang
    Adv. Funct. Mater., 2009, 19, 3219-3225. DOI: 10.1002/adfm.200900663
    Abstract
    Multi-walled carbon nanotube (MWNT)-sheet-reinforced bismaleimide (BMI) resin nanocomposites with high concentrations (~60 wt%) of aligned MWNTs are successfully fabricated. Applying simple mechanical stretching and prepregging (pre-resin impregnation) processes on initially randomly dispersed, commercially available sheets of millimeter-long MWNTs leads to substantial alignment enhancement, good dispersion, and high packing density of nanotubes in the resultant nanocomposites. The tensile strength and Young’s modulus of the nanocomposites reaches 2088 MPa and 169 GPa, respectively, which are very high experimental results and comparable to the state-of-the-art unidirectional IM7 carbon-fiber-reinforced composites for high-performance structural applications. The nanocomposites demonstrate unprecedentedly high electrical conductivity of 5500 S cm−1 along the alignment direction. Such unique integration of high mechanical properties and electrical conductance opens the door for developing polymeric composite conductors and eventually structural composites with multifunctionalities. New fracture morphology and failure modes due to self-assembly and spreading of MWNT bundles are also observed.
    PDF | Supplementary Information

2008

  1. Fabrication and properties of aligned multiwalled carbon nanotube-reinforced epoxy composites
    Qunfeng Cheng, Jiaping Wang*, Kaili Jiang, Qunqing Li, and Shoushan Fan
    J. Mater. Res., 2008, 23, 2975-2983. DOI: 10.1557/JMR.2008.0356
    Abstract
    A method to fabricate continuous and aligned multiwalled carbon nanotube (CNT)/epoxy composites is presented in this paper. CNT/epoxy composites were made by infiltrating an epoxy resin into a stack of continuous and aligned multiwalled CNT sheets that were drawn from super-aligned CNT arrays. By controlling the amount and alignment of the continuous multiwalled CNT sheets, a CNT/epoxy composite with high content of well-dispersed CNTs can be obtained. Differential scanning calorimetry (DSC) and thermogravimetric analysis (TGA) results show that the thermal stability of these CNT/epoxy composites was not affected by the addition of CNTs. The mechanical properties and electrical properties of the CNT/epoxy composites were dramatically improved compared to pure epoxy, suggesting that the CNT/epoxy composites can serve as multifunctional materials with combined mechanical and physical properties.
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  2. Ex-situ concept for toughening the RTMable BMI matrix composites. II. Improving the compression after impact
    Qunfeng Cheng, Zhengping Fang, Xiao-Su Yi*, Xuefeng An, Bangming Tang, and Yahong Xu
    J. Appl. Polym. Sci., 2008, 108, 2211-2217. DOI: 10.1002/app.27864
    Abstract
    The compression after impact (CAI) properties of bismaleimide (BMI) matrix composites manufactured by resin transfer molding (RTM) were significantly improved by ex-situ RTM technique. The thermoplastic polyetherketone with a functional group of phenolphthalein (PAEK) was used as toughener. The optical microscopy images of the cross-section of post-impact specimens revealed that the delamination resistance of specimens toughened through ex-situ RTM technique was dramatically improved. The energy absorption mechanism of composites toughened through ex-situ RTM technique was changed from the delamination to fiber fracture, which contributed to the improvement in CAI. The particle microstructure in interlaminar region of composites toughened through ex-situ RTM technique revealed that a reaction-induced phase decomposition and inversion happened in the interlaminar region. The BMI particles were surrounded with the PAEK phase, which can significantly improve the delamination resistance of composites. The in-plane static mechanical properties of G827/BMI composite toughened through ex-situ RTM technique were very well kept.
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  3. Ex situ” concept for toughening the RTMable BMI matrix composites, Part I: Improving the interlaminar fracture toughness
    Qunfeng Cheng, Zhengping Fang, Xiao-Su Yi*, Xuefeng An, Bangming Tang, and Yahong Xu
    J. Appl. Polym. Sci., 2008, 109, 1625-1634. DOI: 10.1002/app.27868
    Abstract
    Aerospace-grade bismaleimide matrix composites was toughened based on a novel ex situ resin transfer molding (RTM) technique using a special manufactured ES™ carbon fabrics. The toughening mechanism and toughening effect by the technique are studied using thermoplastic PAEK as toughener. Mode I fracture toughness (GIC) of the composites toughened by ex situ RTM technique increased up to three times higher than that of the control system, and Mode II fracture toughness (GIIC) increased two times higher as well. The composite without toughening was denoted as control system. The microstructure revealed that a reaction-induced phase decomposition and inversion happened in the interlaminar region, which resulted in a particles morphology that showed the thermosetting particles were surrounded with the PAEK phase. The plastic deformation and rupture of the continuous PAEK phase are responsible to the fracture toughness improvement. And the influence of PAEK concentration on toughness improvement was also investigated.
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2006

  1. Improvement of the Impact Damage Resistance of BMI/Graphite Laminates by the Ex-situ Method
    Qunfeng Cheng, Zhengping Fang, Yahong Xu, and Xiao-Su Yi*
    High Perform. Polym., 2006, 18, 907-917. DOI: 10.1177/0954008306068296
    Abstract
    High-performance bismaleimide (BMI) matrix composites reinforced with graphite fibers were prepared and toughened with a thermoplastic component (PEK-C) by using different toughening methods. Four experimental options were conducted using the neat BMI matrix, toughened BMI matrix with PEKC, BMI laminates periodically interleaved with neat PEK-C films (Ex-situ concept 1) and BMI laminates periodically interleaved with BMI/PEK-C blend films (Ex-situ concept 2), respectively. The laminates were tested for compression strength after impact using an impact energy of 2 J mm-1. The highest impact damage resistance was obtained for the laminates toughened using the Ex-situ concept 2, especially, when PEK-C/BMI two-component films, cast from a mixture of PEK-C: BMI = 60: 40 were interleaved between the BMI laminate plies. Interleaving the pure thermoplastic film also gave good results (Ex-situ concept 1). There were two peak temperatures evident in the dynamic mechanical thermal analyses of the ex-situ toughened laminates implying that phase separation had occurred. The glass transition temperature of the toughened BMI laminates was slightly reduced due to the lower glass transition temperature of PEK-C. Morphological investigations revealed that a granular structure was present in the interply region presumably due to spinodal decomposition and coarsening. The results of this study are presented herein.
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