首页/文章/ 详情

【新文速递】2024年11月7日复合材料SCI期刊最新文章

3天前浏览195

   

今日更新:Composites Part B: Engineering 11 篇

Composites Part B: Engineering

Exploring ultrasonic and resistance welding for thermoplastic composite structures: Process development and application potential

Lars Larsen, Manuel Endrass, Stefan Jarka, Simon Bauer, Maximilian Janek

doi:10.1016/j.compositesb.2024.111927

热塑性复合材料结构的超声和电阻焊探索:工艺发展和应用潜力

Thermoplastic composites outperform in aerospace applications compared to thermoset composites due to their weldability, a key advantage. This feature streamlines manufacturing, allowing for precise assembly of complex shapes, reducing costs, and accelerating production. Additionally, it simplifies maintenance, enabling easy repair or replacement of damaged parts, thereby extending vehicle lifespan and minimizing downtime. With exceptional strength-to-weight ratio and resistance to corrosion and fatigue, weldable thermoplastic composites ensure reliable performance in the demanding aerospace environment. Overall, their weldability enhances efficiency, versatility, and safety in aerospace applications. This paper first presents an overview of various welding processes and discusses the special challenges of assembly processes in the aviation industry. This work then focuses from the authors’ perspective with regard to industrializability on the two most promising processes, resistance and ultrasonic welding.

与热固性复合材料相比,热塑性复合材料在航空航天应用中的表现优于热固性复合材料,因为它们的可焊性是一个关键优势。该功能简化了制造,允许复杂形状的精确组装,降低了成本,加快了生产。此外,它简化了维护,使维修或更换损坏的部件变得容易,从而延长了车辆的使用寿命并最大限度地减少了停机时间。可焊接热塑性复合材料具有卓越的强度重量比和耐腐蚀和抗疲劳性能,可确保在苛刻的航空航天环境中具有可靠的性能。总的来说,它们的可焊性提高了航空航天应用的效率、通用性和安全性。本文首先概述了各种焊接工艺,并讨论了航空工业中装配工艺的特殊挑战。这项工作然后从作者的角度关注两种最有前途的工艺的工业化,电阻和超声波焊接。


“Janus” PEEK Implant with Sandwich Mg-Containing Coating for Infected Tissue Repair

Xingdan Liu, Haifeng Zhang, Ji Tan, Ziyi Lu, Xiaochun Peng, Liping Ouyang, Xuanyong Liu

doi:10.1016/j.compositesb.2024.111938

 

夹心含镁涂层的“Janus”PEEK植入物用于感染组织修复

Having good antibacterial properties and promoting soft and hard tissue repair are the keys to successful implantation of intraosseous transcutaneous. Polyether ether ketone (PEEK) is a class of FDA-approved polymer implants. However, the surface of PEEK is bioinert, which is easy to cause postoperative infection and poor tissue integration. In this study, polypyrrole (Ppy) was polymerized on sulfonated PEEK, Mg3(PO4)2 nanosheets were grown in situ on one side, and polycaprolactone (PCL) was then spun on the surface to form a Janus-like surface on PEEK. The Ppy/Mg3(PO4)2/PCL composite coating could inhibit bacterial adhesion, and the excellent photothermal properties of Ppy/Mg3(PO4)2/PCL and Ppy coatings further promote the removal of bacteria due to the accumulated heat. After the infection was eliminated, the Janus-like surface of modified PEEK switched macrophages to anti-proinflammatory response and promoted both soft and hard tissue repair. The Ppy modified sulfonated PEEK could promote collagen secretion in the soft tissue, while the PCL films on Ppy/Mg3(PO4)2/PCL was densified by temperature response under near-infrared light treatment to close the exposed interface of Mg3(PO4)2 nanosheets that was more conducive to bone repair. In summary, PEEK with Janus-like surface consisting of Ppy/Mg3(PO4)2/PCL and Ppy has multiple biological functions of sequential antibacterial and soft and hard tissue repair, and is a promising candidate material for intraosseous transcutaneous implants.

具有良好的抗菌性能和促进软硬组织修复是骨内经皮植入成功的关键。聚醚醚酮(PEEK)是一类经fda批准的聚合物植入物。但PEEK表面具有生物惰性,易引起术后感染,组织整合性差。在本研究中,聚吡啶(Ppy)在磺化PEEK上聚合,Mg3(PO4)2纳米片在一侧原位生长,聚己内酯(PCL)在PEEK表面旋转形成Janus-like表面。Ppy/Mg3(PO4)2/PCL复合涂层可以抑制细菌粘附,并且Ppy/Mg3(PO4)2/PCL和Ppy涂层优异的光热性能进一步促进了细菌因积热而被去除。感染消除后,改性PEEK的janus样表面使巨噬细胞产生抗促炎反应,促进软硬组织修复。Ppy修饰的磺化PEEK可以促进软组织中胶原的分泌,而在近红外光处理下,Ppy/Mg3(PO4)2/PCL上的PCL膜通过温度响应致密化,关闭Mg3(PO4)2纳米片暴露的界面,更有利于骨修复。综上所述,由Ppy/Mg3(PO4)2/PCL和Ppy组成的Janus-like surface PEEK具有顺序抗菌和软硬组织修复等多种生物学功能,是一种很有前景的经皮骨内植入材料。


Laser powder bed fusion of high-strength crack-free Al7075 alloy with the in-situ formation of TiB2/Al3Ti-reinforced phases and nucleation agents

Yanzhen Liang, Quanquan Han, Zhongyang Sui, Zhenhua Zhang, Han Zhang, Heng Gu, Defan Wu, Liqiao Wang, Hanlian Liu, Rossitza Setchi

doi:10.1016/j.compositesb.2024.111940

激光粉末床熔接高强无裂纹Al7075合金,原位形成TiB2/ al3ti增强相和成核剂

The existence of solidification cracks caused by columnar grains in precipitation-hardened aluminium alloys limit the applicability of Al7075 components manufactured via laser powder bed fusion (LPBF) additive manufacturing. A novel approach was developed to co-incorporate submicron-sized B and micron-grade Ti6Al4V to eliminate hot cracks and to effectively transform coarse columnar grains into fine equiaxed grains, thus improving the mechanical performance of LPBF-fabricated modified Al7075 material. The grain refinement was mainly attributable to the heterogeneous nucleation promoted by the combination of in-situ-formed L12-Al3Ti and TiB2 nano-sized phases. After an optimised T6 heat treatment, excellent comprehensive mechanical properties were achieved, with a tensile strength of 460 MPa and an elongation of 13%. This research provides an efficient and cost-effective path for addressing crack-sensitive metallic materials used for LPBF additive manufacturing processes.

析出硬化铝合金中存在由柱状晶粒引起的凝固裂纹,限制了激光粉末床熔合(LPBF)增材制造Al7075部件的适用性。提出了一种将亚微米级B和微米级Ti6Al4V共掺杂的新方法,以消除热裂纹,并有效地将粗柱状晶粒转变为细等轴晶粒,从而提高lpbf制备的改性Al7075材料的力学性能。晶粒细化的主要原因是原位形成的L12-Al3Ti和TiB2纳米相结合促进了晶粒的非均相形核。经过优化的T6热处理后,获得了优异的综合力学性能,抗拉强度为460 MPa,伸长率为13%。该研究为解决用于LPBF增材制造工艺的裂纹敏感金属材料提供了一种高效且经济的途径。


Vine-inspired 3D self-supporting spiral networks enable all-polymer composites advanced dielectric properties and isotropic thermal management

Qibin Xu, Shengchang Zhang, Yingying Zhao, KaiXiang Wang, Shuheng Liang, Yuanyuan Yu, Yan Jiang, Baolong Xue, Mengjin Jiang, Pengqing Liu

doi:10.1016/j.compositesb.2024.111942

 

葡萄藤启发的3D自支撑螺旋网络使全聚合物复合材料具有先进的介电性能和各向同性热管理

Traditionally, it has been considered impossible to overcome the directional limitations associated with polarization and thermal conductivity (λ) in laminated all-polymer composites, which are essential for signal transmission and heat dissipation in fifth-generation equipment shells. Herein, by utilizing hierarchical weaving technology, a vine-like three-dimensional (3D) ultrahigh molecular weight polyethylene (UHMWPE) spiral network is created in laminated ramie-reinforced composites. This unique spiral structure ensures polarization balance by continuously dispersing functional UHMWPE crystals in multiple directions, and it safeguards the micro/nanopores (air carriers) of ramie through self-support, thereby achieving exceptional microwave transmittance (98.3 %). Remarkably, this structure effectively overcomes the limitations of thermal paths in laminated composites along their vertical plane directions, thus simultaneously obtaining high in-plane λ (3.3354 W/mK) and through-plane λ (3.2756 W/mK). This novel approach based on a functional crystal-based 3D spiral network challenges the stereotypes regarding all-polymer composites, particularly in terms of advanced dielectric properties and isotropic thermal management.

传统上,人们认为不可能克服层压全聚合物复合材料中与极化和导热系数(λ)相关的方向限制,而这对于第五代设备外壳的信号传输和散热至关重要。本文利用分层编织技术,在层叠苎麻增强复合材料中创建了藤蔓状三维超高分子量聚乙烯(UHMWPE)螺旋网络。这种独特的螺旋结构通过在多个方向上连续分散功能性超高分子量聚乙烯晶体来确保极化平衡,并通过自支撑来保护苎麻的微/纳米孔(空气载体),从而实现优异的微波透过率(98.3%)。值得注意的是,这种结构有效地克服了层合复合材料沿垂直方向热路径的限制,从而同时获得高的面内λ (3.3354 W/mK)和通面λ (3.2756 W/mK)。这种基于功能晶体三维螺旋网络的新方法挑战了关于全聚合物复合材料的刻板印象,特别是在先进的介电性能和各向同性热管理方面。


hUCMSC-derived exosomes mitigate blood-spinal cord barrier disruption by activating AMPK/mTOR-mediated autophagic flux after acute spinal cord injury

Zhiheng Chen, Shengting Wu, Shihao Sheng, Sicheng Wang, Yuxuan Qian, Xin Wang, Fengjie Lu, Qi Han, Xiao Chen, Jiacan Su, Xiaofeng Lian

doi:10.1016/j.compositesb.2024.111944

 

急性脊髓损伤后,hucmsc衍生的外泌体通过激活AMPK/ mtor介导的自噬通量来减轻血脊髓屏障破坏

After spinal cord injury (SCI), the integrity of the blood-spinal cord barrier (BSCB) can be disrupted, leading to the secondary injuries such as inflammatory cell infiltration, neuronal death, and spinal cord hematoma. It is important to maintain the integrity of the BSCB to help restore function following SCI. While some studies have demonstrated the therapeutic effects of exosomes derived from human umbilical cord mesenchymal stem cells (hUCMSC-exos), their role in preserving BSCB integrity remains unclear. In our study, we demonstrated the protective effects of hUCMSC-exos on the BSCB and its mechanism. The results of this study indicate that hUCMSC-exos promote motor function recovery, preserve spinal cord structure, and reduce neuronal loss by inhibiting BSCB leakage following SCI. Experimental investigations conducted in vivo and in vitro have demonstrated that hUCMSC-exos can mitigate the loss of adherens junctions (AJs) and tight junctions (TJs) and stimulate autophagy in spinal cord endothelial cells. The protective effects were also found to be significantly reversed following the inhibition of autophagy using 3-MA. In conclusion, our study demonstrates that hUCMSC-exos protect the integrity of BSCB by promoting the repair of spinal endothelial cells through activation of autophagy, thereby exerting a protective role in SCI.

脊髓损伤(SCI)后,血脊髓屏障(BSCB)的完整性可被破坏,导致炎症细胞浸润、神经元死亡、脊髓血肿等继发性损伤。维持BSCB的完整性对于帮助脊髓损伤后的功能恢复是很重要的。虽然一些研究已经证明了来自人脐带间充质干细胞(hUCMSC-exos)的外泌体的治疗作用,但它们在保持BSCB完整性方面的作用尚不清楚。在我们的研究中,我们证明了hUCMSC-exos对BSCB的保护作用及其机制。本研究结果表明,humcc -exos通过抑制脊髓脊髓液渗漏,促进运动功能恢复,保护脊髓结构,减少神经元损失。体内和体外实验研究表明,hUCMSC-exos可以减轻粘附连接(AJs)和紧密连接(TJs)的丢失,并刺 激脊髓内皮细胞的自噬。在使用3-MA抑制自噬后,这种保护作用也被发现明显逆转。综上所述,我们的研究表明,hUCMSC-exos通过激活自噬来促进脊髓内皮细胞的修复,从而保护BSCB的完整性,从而在脊髓损伤中发挥保护作用。


Mechanical and Electromagnetic Interference Shielding Properties of In-situ Grown Si3N4nw Synergistic Defective-Graphene Reinforced Alumina Ceramics

Yameng Jiao, Qiang Song, Xu Yang, Liyuan Han, Caixiang Xiao, Fei Zhao, Hejun Li

doi:10.1016/j.compositesb.2024.111945

原位生长Si3N4nw协同缺陷-石墨烯增强氧化铝陶瓷的机械和电磁干扰屏蔽性能

Ceramic matrix composites have versatile application potential but are astricted by brittleness and single function. It can be ameliorated assisted by reinforcements, but the uneven distribution of reinforcements seriously limits the reinforcing efficiency. In this work, the layered porous skeleton of alumina (Al2O3) and silicon dioxide (SiO2) was prepared, then defective-graphene (DG) and silicon nitride nanowires (Si3N4nw) were successively grown in-situ in the skeleton to concurrently strength and toughen, as well as endow Al2O3 ceramic with electromagnetic interference (EMI) shielding performance. Subsequently, Al2O3/SiO2-G-Si3N4nw preform was sintered to construct a uniform Si3N4nw synergistic DG enhancement network. The optimum flexural strength and fracture toughness of the sintered ceramic reached 388.52 MPa and 11.29 MPa∙m1/2, respectively. This was mainly since DG can fine the ceramic grains, induce crack deflection and furcation, while the uniformly distributed Si3N4nw consumed additional energy during the pull-out process. In addition, the EMI shielding effectiveness of the sintered ceramics in X-band was up to 31.77 dB, which is mainly attributed to the conductive loss, dipole polarization loss and interfacial polarization loss of DG. Remarkably, this work provides an idea for efficient strengthening, toughening and integration of structure and function.

陶瓷基复合材料具有广泛的应用潜力,但受脆性和单一功能的限制。在加固的辅助下,加固效果可以得到改善,但加固分布不均匀严重限制了加固效果。本工作制备了氧化铝(Al2O3)和二氧化硅(SiO2)的层状多孔骨架,然后在骨架中依次原位生长缺陷石墨烯(DG)和氮化硅纳米线(Si3N4nw),以同时增强和增韧,并赋予Al2O3陶瓷具有电磁干扰(EMI)屏蔽性能。随后,烧结Al2O3/SiO2-G-Si3N4nw预制体,构建均匀的Si3N4nw协同DG增强网络。烧结陶瓷的最佳抗弯强度和断裂韧性分别达到388.52 MPa和11.29 MPa∙m1/2。这主要是因为DG可以细化陶瓷晶粒,诱导裂纹偏转和分叉,而均匀分布的Si3N4nw在拔出过程中会消耗额外的能量。此外,烧结陶瓷在x波段的电磁干扰屏蔽效能高达31.77 dB,这主要归因于DG的导电损耗、偶极极化损耗和界面极化损耗。值得注意的是,这项工作为结构和功能的有效强化、增韧和整合提供了思路。


Frequency insensitive electromagnetic absorption core-shell sandwich structure with excellent electromagnetic damage tolerance

Yiming Zhao, Suli Xing, Changliang Li, Naifeng Yang, Yonglyu He, Ke Duan, Jianwei Zhang

doi:10.1016/j.compositesb.2024.111946

 

频率不敏感电磁吸收芯壳夹层结构,具有优异的电磁损伤容忍度

The compatibility of broadband electromagnetic absorption and electromagnetic damage tolerance poses challenges to the regulation of electromagnetic response characteristics, which are typically restricted by the intrinsic dispersion of materials and strong resonant features of unit cell structures. In this work, triply-periodic-minimal-surfaces (TPMS) based gradient core-shell sandwich structure is proposed to address this challenge for its mathematical defined unique conductive pore structure. The reflection loss-frequency curve is less than -10 dB in 2-18 GHz frequency band, accompanied by two separate resonant absorption peaks at 2.4 GHz and 17.5 GHz. The reflection loss curve is insensitive to frequency in a wide frequency band of 4-14 GHz, using merely three kinds of absorbing materials. When the damage proportion is less than 40%, effective electromagnetic absorption can be maintained in panel damage, core damage and penetrating damage modes, thanks to the extraordinary conduction-dissipation effect. Our study provides valuable insights for the design of damage tolerant electromagnetic absorption structures.

宽带电磁吸收和电磁损伤容限的兼容性对电磁响应特性的调节提出了挑战,而电磁响应特性的调节通常受到材料的本征色散和单胞结构的强谐振特性的限制。在这项工作中,提出了基于三周期最小表面(TPMS)的梯度核壳夹层结构,以其数学定义的独特导电孔隙结构来解决这一挑战。在2 ~ 18 GHz频段,反射损耗频率曲线小于-10 dB,在2.4 GHz和17.5 GHz频段存在两个独立的共振吸收峰。在4 ~ 14ghz宽频带内,仅使用三种吸波材料,反射损耗曲线对频率不敏感。当损伤比例小于40%时,由于超常的传导耗散效应,在面板损伤、铁芯损伤和穿透损伤模式下均能保持有效的电磁吸收。我们的研究为容损电磁吸收结构的设计提供了有价值的见解。


Interfacial property optimization through the co-deployment of MOF-derived nickel phyllosilicate and DOPO: Effective reinforcement and flame retardancy of epoxy resin

Shibin Nie, Zongquan Zhao, Wenli Zhai, Jinian Yang, Hong Zhang, Dongyue Zhao, Jingwen Wang

doi:10.1016/j.compositesb.2024.111947

 

mof衍生的层状硅酸镍和DOPO共配优化界面性能:环氧树脂的有效增强和阻燃

Epoxy resin (EP) is a versatile material widely employed in diverse fields such as electronic encapsulation, coatings, and adhesives. The optimization of flame-retardant, mechanical and interfacial properties in composites through material modification and compounding represents a prominent research focus within the field of EP. This study presents a novel approach by synthesizing MOF-derived nickel phyllosilicate (K-NiPS) and compounding it with 9,10-dihydro-9-oxa-10-phosphaphenanthrene-10-oxide (DOPO) into the EP matrix. The incorporation of 5 wt% total K-NiPS and DOPO, with a mass ratio of 2:3, achieves a UL-94 V-0 rating and enhances the limiting oxygen index from 23.5 to 28.8%. This combination also reduced the peak heat release rate, peak smoke release rate, and total smoke release by 44.6%, 53.6%, and 37.8% respectively. Besides, the interface optimization effect of K-NiPS in collaboration with DOPO improved the tensile strength of EP/2K-NiPS/3DOPO from 77.5 MPa to 94.3 MPa, and the wear rate was only 1.25 × 10-5 mm3/(N·m), which is 82.2% lower than that of pure EP. This study will pave the way for the applied interface design of multi-functional EP.

环氧树脂(EP)是一种用途广泛的材料,广泛应用于电子封装、涂料、粘合剂等领域。通过材料改性和复合来优化复合材料的阻燃性能、力学性能和界面性能是EP领域的一个突出研究热点。本研究提出了一种合成mof衍生的叶状硅酸镍(K-NiPS)的新方法,并将其与9,10-二氢-9-氧-10-磷酸菲-10-氧化物(DOPO)复配到EP基质中。总K-NiPS和DOPO的掺入量为5 wt%,质量比为2:3,达到UL-94 V-0等级,并将极限氧指数从23.5提高到28.8%。该组合还使峰值放热率、峰值放烟率和总放烟率分别降低了44.6%、53.6%和37.8%。此外,K-NiPS与DOPO协同作用的界面优化效果使EP/2K-NiPS/3DOPO的抗拉强度从77.5 MPa提高到94.3 MPa,磨损率仅为1.25 × 10-5 mm3/(N·m),比纯EP降低82.2%。本研究将为多功能EP的应用界面设计奠定基础。


Highly deformable self-sensing cementitious composites enabled by monomer polymerization for full-scale shear wall seismic monitoring

Nanxi Dang, Chengji Xu, Dan Yu, Jiayi Tu, Wei Zhu, Jiyang Wang, Qiang Zeng, Weijian Zhao

doi:10.1016/j.compositesb.2024.111948

高变形自传感胶凝复合材料单体聚合实现全尺寸剪力墙地震监测

Cementitious composites generally possess high brittleness and low deformability, which greatly limits their engineering applications. Herein, we proposed a method of in-situ polymerization of sodium acrylate (SA) monomers in cement matrix to fabricate highly deformable self-sensing cementitious composites (HD-SSCC) with graphene nanoplatelets (GNP). Engineering performances, sensibility and multi-scale structures of the HD-SSCC specimens were tested. Results demonstrate that the HD-SSCC specimens possessed superior water resistivity, strength and deformability. Specifically, the HD-SSCC with 4% SA showed the increases of flexural strength and compression strength by 139% and 50%, and the improvement of fractional change in resistance (FCR) by almost 6 times. The cement hydrates, polyacrylate and GNP jointly built a composite structure that strengthens the cement matrix and enhances the sensibility. An HD-SSCC assembly was installed in a full-scale shear wall for seismic monitoring, which shows excellent sensibility at low loading stage. Our findings provide a simple way towards low-cost yet high-strength SSCC for structural health monitoring.

胶凝复合材料普遍具有脆性高、变形能力低的特点,极大地限制了其工程应用。在此,我们提出了一种在水泥基体中原位聚合丙烯酸钠(SA)单体的方法,以制备具有石墨烯纳米片(GNP)的高变形自传感胶凝复合材料(HD-SSCC)。对HD-SSCC试件的工程性能、敏感性和多尺度结构进行了测试。结果表明,HD-SSCC试样具有优异的水阻、强度和变形性能。其中,添加4% SA的HD-SSCC的抗弯强度和抗压强度分别提高了139%和50%,阻力分数变化(FCR)改善了近6倍。水泥水合物、聚丙烯酸酯和GNP共同构成复合结构,强化水泥基体,增强敏感性。HD-SSCC组件安装在全尺寸剪力墙中进行地震监测,在低荷载阶段表现出良好的灵敏度。我们的发现为低成本、高强度的SSCC结构健康监测提供了一种简单的方法。


Electrophoretic deposition of curcumin-loaded mesoporous bioactive glass nanoparticle-chitosan composite coatings on titanium for treating tumor-induced bone defect

Yuhan Zhang, Jingjie Yu, Chenhuan Wu, Lehao Han, Yunru Tai, Boyan Wang, Yujing Yan, Yekai Liu, Yihan Sun, Qinqin Lu, Kai Zheng, Tian Zhou, Qiang Chen

doi:10.1016/j.compositesb.2024.111950

 

负载姜黄素的介孔生物活性玻璃纳米颗粒-壳聚糖复合涂层在钛上的电泳沉积治疗 肿瘤性骨缺损

Clinical treatment of osteosarcoma (OS) presents significant challenges in postoperative tumor recurrence and large segmental bone defects, often necessitating joint replacement or artificial bone implantation to repair failed or defective bone tissue. At the same time, fibroblastic encapsulation can impede direct contact between implants and bones, leading to implant failure. To tackle these issues, mesoporous bioactive glass nanoparticles (MBN) were synthesized and then loaded with curcumin (CUR). Subsequently, chitosan (CTS) was chosen as the charger and coating matrix, and electrophoretic deposition (EPD) was utilized to fabricate a CTS-MBN-CUR composite coating with triple functionality on Ti implants aiming for OS-induced bone repair. MBN-CUR nanoparticles are encapsulated in CTS and uniformly distributed within the coating, achieving robust adhesion and long-term release of CUR. Concurrently, the developed CTS-MBN-CUR coating exhibits moderate hydrophilicity, and good bioactivity. Moreover, three different types of cells, MC3T3-E1, L929, and MG63 cells, were individually cultured with the composite coating and subjected to comprehensive cellular studies. The coating presented favorable bioactivities, and osteogenic performance, and the ability to resist the activity of fibroblast and OS cells. These findings suggest that CTS-MBN-CUR holds promising potential for bone regeneration following OS resection surgery.

骨肉瘤(osteosarcoma, OS)的临床治疗面临着术后肿瘤复发和大节段性骨缺损的重大挑战,通常需要关节置换或人工骨植入来修复失败或缺陷的骨组织。同时,纤维母细胞包封会阻碍种植体与骨骼的直接接触,导致种植体失效。为了解决这些问题,合成了介孔生物活性玻璃纳米粒子(MBN),然后负载姜黄素(CUR)。随后,选择壳聚糖(CTS)作为充电剂和涂层基质,利用电泳沉积(EPD)法制备了具有三功能的CTS- mbn - cur复合涂层,用于钛种植体os诱导的骨修复。MBN-CUR纳米颗粒被包裹在CTS中,并均匀分布在涂层内,实现了优异的黏附和长效释放,同时所制备的CTS-MBN-CUR涂层具有中等亲水性和良好的生物活性。此外,将MC3T3-E1、L929和MG63三种不同类型的细胞分别用复合涂层培养,并进行全面的细胞研究。该涂层具有良好的生物活性和成骨性能,并能抵抗成纤维细胞和骨肉瘤细胞的活性。这些研究结果表明,CTS-MBN-CUR具有骨切除术后骨再生的良好潜力。


Carbon nanotube intermediate layer intercalation and its influence on surface charge of thin film composite membrane

Luyao Deng, Ralph Rolly Gonzales, Joy Thomas, Ryosuke Takagi, Wenming Fu, Cheng-Liang Liu, Shang Xiang, Hideto Matsuyama

doi:10.1016/j.compositesb.2024.111951

 

碳纳米管中间层嵌入及其对薄膜复合膜表面电荷的影响

The surface charge of a separation membrane is a critical factor affecting its performance in ion separation and fouling resistance. Thin-film composite (TFC) polyamide (PA) membrane, commonly used in water treatment, often suffer from excessive surface negative charges, which significantly limits their application and fouling resistance. To address this issue, this work introduces a carbon nanotubes (CNT) intermediate layer to adjust the surface charge of TFC PA membranes, aiming to achieve a PA layer with neutral properties. Novel grazing-incidence wide-angle x-ray scattering (GIWAXS) measurements were employed to elucidate the effect of CNT on the molecular chain stacking of PA. The CNT intermediate layer was found to influence the PA cross-linking, which is related to surface negative charge, by controlling the storage and release of the m-phenylenediamine monomer during interfacial polymerization. The neutral CNT-TFC membrane demonstrated improved NH4 + retention and increased resistance to fouling by protein, surfactant, and E. coli. However, other surface properties, such as roughness and hydrophilicity, could counteract the antifouling benefits of a neutral surface. This work provides insights into additional advantages of CNT intermediate layer intercalation in TFC PA membranes, such as enhanced cross-linking and surface charge control.

分离膜的表面电荷是影响其离子分离性能和抗污染性能的关键因素。薄膜复合材料(TFC)聚酰胺(PA)膜是水处理中常用的一种膜材料,其表面负电荷过多,严重限制了其应用和抗污性能。为了解决这一问题,本工作引入了碳纳米管(CNT)中间层来调节TFC PA膜的表面电荷,旨在实现具有中性特性的PA层。采用新型掠入射广角x射线散射(GIWAXS)测量方法研究了碳纳米管对聚酰胺分子链堆积的影响。在界面聚合过程中,碳纳米管中间层通过控制间苯二胺单体的储存和释放来影响与表面负电荷有关的聚丙烯腈交联。中性碳纳米管- tfc膜表现出改善的NH4 +潴留和增强的抵抗蛋白质、表面活性剂和大肠杆菌的污染。然而,其他表面特性,如粗糙度和亲水性,可能会抵消中性表面的防污作用。这项工作为碳纳米管中间层嵌入TFC PA膜的其他优点提供了见解,例如增强交联和表面电荷控制。




来源:复合材料力学仿真Composites FEM
ACTMechanicalAdditiveFluxInspire疲劳断裂复合材料通用航空航天电子增材裂纹材料多尺度控制装配
著作权归作者所有,欢迎分享,未经许可,不得转载
首次发布时间:2024-11-14
最近编辑:3天前
Tansu
签名征集中
获赞 3粉丝 0文章 503课程 0
点赞
收藏
作者推荐

【新文速递】2024年5月26日固体力学SCI期刊最新文章

今日更新:International Journal of Solids and Structures 1 篇,International Journal of Plasticity 1 篇,Thin-Walled Structures 2 篇International Journal of Solids and StructuresSurface wrinkling of a hyperelastic half-space coated by a liquid crystal elastomer filmYang Liu, Qianqian Ji, Alain Gorielydoi:10.1016/j.ijsolstr.2024.112895液晶弹性体膜涂覆的超弹性半空间的表面起皱We consider the stability of a hyperelastic substrate coated by a liquid crystal elastomer film and subjected to compressive forces. In this problem, the liquid crystal elastomer directors are free to evolve and this possible variation needs to be included in the stability analysis. We consider the case where the initial directors are aligned either in the horizontal or in the vertical direction and obtain an exact bifurcation condition for surface wrinkling. We show that director reorientation increases both the critical compressive strain and the critical wavenumber, hence stabilizing the material. In the small wavenumber limit we carry out an asymptotic analysis and obtain analytical solutions for the critical stretch and the critical wavenumber, which can be useful in applications.我们考虑了一种被液晶弹性体薄膜包裹并受到压缩力作用的超弹性衬底的稳定性。在此问题中,液晶弹性体导向是自由演化的,需要在稳定性分析中考虑这种可能的变异。我们考虑了初始方向在水平或垂直方向上对齐的情况,并得到了表面起皱的精确分岔条件。我们发现,定向取向增加了临界压缩应变和临界波数,从而稳定了材料。在小波数极限下进行了渐近分析,得到了临界拉伸和临界波数的解析解,具有一定的应用价值。International Journal of PlasticityA multiscale constitutive model of magnesium-shape memory alloy compositeBo Xu, Aonan Su, Ziyi Wang, Chao Yu, Guozheng Kangdoi:10.1016/j.ijplas.2024.104011镁形记忆合金复合材料的多尺度本构模型In this work, a multiscale constitutive model is established to describe the deformation behaviors of magnesium-shape memory alloy (Mg-SMA) composite in a wide temperature range and reveal the strengthening mechanism of SMA reinforcement on Mg. The model is established at the grain scale firstly and gradually transited to the macroscopic scale by employing a newly developed three-level scale transition rule. At the grain scale, the thermodynamic-consistent constitutive models of Mg and SMA are, respectively, constructed by addressing different inelastic deformation mechanisms. The basal, prismatic, pyramidal, slip systems and extension twinning system are considered for the Mg phase, and the martensite transformation (MT) and austenitic plasticity are addressed for SMA reinforcement. Thermodynamic driving forces of each inelastic deformation mechanism are derived from the dissipative inequality and the constructed Gibbs free energies. At the polycrystalline scale, to evaluate the interactions among the grains and pores, and obtain the whole responses of the polycrystalline Mg and SMA, a thermo-mechanically coupled self-consistent homogenization scheme is employed. At the mesoscopic scale, a modified thermo-mechanically coupled Mori-Tanaka's homogenization scheme is adopted to evaluate the interaction between the Mg phase and SMA phase, and predict the whole responses for the representative volume element (RVE) of the composite. According to the geometrical features and mechanical loadings applied on the specimen, a hypothesis of homogeneous stress and strain fields at the macroscopic scale is adopted to achieve the scale transition from the RVE of the composite to the whole specimen. The capacity of the multiscale model is verified by comparing the predictions with the existing experimental data (Aydogmus, 2015). Moreover, the influences of characteristic information for the microstructures at different spatial scales on the deformation behaviors of the composite are predicted and discussed.本文建立了镁形状记忆合金(Mg-SMA)复合材料在宽温度范围内的变形行为的多尺度本构模型,揭示了镁形状记忆合金对镁的强化机理。该模型首先在颗粒尺度上建立,然后采用新提出的三级尺度过渡规则逐步过渡到宏观尺度。在晶粒尺度上,通过处理不同的非弹性变形机制,分别建立了Mg和SMA的热力学一致本构模型。Mg相考虑基相、棱柱相、锥体相、滑移体系和延伸孪晶体系,SMA强化研究马氏体相变(MT)和奥氏体塑性。利用耗散不等式和构造的吉布斯自由能推导出各非弹性变形机制的热力学驱动力。在多晶尺度上,为了评估晶粒与孔隙之间的相互作用,获得多晶Mg和SMA的整体响应,采用了热-机械耦合自一致均匀化方案。在介观尺度上,采用改进的热-机械耦合Mori-Tanaka均一化方案评价了Mg相与SMA相的相互作用,并预测了复合材料的代表性体积元(RVE)的整体响应。根据试件的几何特征和受力情况,采用宏观尺度均质应力场和应变场假设,实现了从复合材料的RVE到整个试件的尺度转换。通过将预测结果与现有实验数据进行比较,验证了多尺度模型的能力(Aydogmus, 2015)。此外,还预测和讨论了不同空间尺度下微观组织特征信息对复合材料变形行为的影响。Thin-Walled StructuresInvestigating the relationship between fracture entropy and stress amplitude in CFRP laminates under low-cycle fatigue loadingBo An, Aijia Li, Qianzhu Mao, Jia Huangdoi:10.1016/j.tws.2024.112040研究低周疲劳载荷下CFRP层合板断裂熵与应力幅值的关系Fracture fatigue entropy (FFE) is considered to be independent of the loading amplitude in fatigue experiments, and this conclusion has been applied to fatigue life prediction of composites and metals with satisfactory prediction accuracy. However, the existing research work mainly focuses on high-cycle fatigue, and it is not clear whether the FFE is independent of the loading amplitude in low-cycle fatigue, which requires more in-depth research. Fatigue experiments were conducted on three CFRP laminates with different ply orientations, and the FFE values corresponding to low-cycle fatigue were obtained by thermographic analysis. The results show that the FFE value is no longer independent of the loading amplitude under low-cycle fatigue conditions. On the contrary, it decreases with the increase of fatigue loading amplitude and also varies with different ply orientations. The relationship between low-cycle fracture fatigue entropy and loading amplitude of composites with different ply orientations was analyzed and modeled, and a novel low-cycle fatigue life prediction method based on FFE was developed.在疲劳试验中,断裂疲劳熵与载荷幅值无关,这一结论已应用于复合材料和金属的疲劳寿命预测,预测精度令人满意。然而,现有的研究工作主要集中在高周疲劳上,在低周疲劳下,FFE是否与加载幅值无关尚不清楚,这需要更深入的研究。对3种不同铺层取向的CFRP复合材料进行了疲劳试验,通过热像分析得到了其低周疲劳的FFE值。结果表明,在低周疲劳工况下,FFE值不再与加载幅值无关。相反,随着疲劳载荷幅值的增大而减小,并随层向的不同而变化。对不同铺层取向复合材料的低周断裂疲劳熵与加载幅值的关系进行了分析和建模,提出了一种基于FFE的低周疲劳寿命预测方法。Collision-induced adhesion behavior and mechanism for metal particle and grapheneHaitao Hei, Jian Wang, Yonggang Zheng, Hongfei Yedoi:10.1016/j.tws.2024.112045 金属颗粒与石墨烯的碰撞诱导粘附行为及机理Micro- and nano-scale collisions exhibit extraordinary behavior compared to the common macroscopic collisions. Understanding the size-dependent collision behavior and the relevant mechanism is of great significant for molecular movement, drug delivery, and the design of novel anti-collision materials. In this work, we explore the comprehensive impact dynamics of metal projectiles on graphene by using molecular dynamics simulations. It has been discovered that in addition to the normal penetration and rebound behaviors, ultrasoft two-dimensional materials can also capture impacting metal projectiles, i.e., the adhesion behavior. This abnormal behavior is primarily attributed to the dissipation of kinetic energy during impact, which leads to the weak rebounded kinetic energy relative to the interactions between the impacting objects. Additionally, in the case of finite-sized graphene, the projectile may receive additional energy from the reflected cone wave at the boundary to escape the adhesion. This phenomenon is referred to as adhesion-rebound behavior. We present the phase diagrams illustrating the impact behaviors under various conditions such as projectile stiffness, impact velocity, graphene size, projectile sizes, and projectile density. This work provides an insight into the multiscale collision phenomena and an instructive strategy for the design of transfer printing, collision protection, etc.与普通的宏观碰撞相比,微观和纳米尺度的碰撞表现出不同寻常的行为。了解尺寸依赖性碰撞行为及其相关机制对分子运动、药物传递和新型抗碰撞材料的设计具有重要意义。在这项工作中,我们通过分子动力学模拟探索了金属弹丸对石墨烯的综合撞击动力学。研究发现,除了常规的侵彻和回弹行为外,超软二维材料还可以捕捉金属弹丸的冲击,即粘附行为。这种异常行为主要是由于撞击过程中动能耗散,导致相对于撞击物体之间的相互作用,反弹动能较弱。此外,在有限尺寸石墨烯的情况下,弹丸可能会从边界处反射的锥波中获得额外的能量,以逃避粘附。这种现象被称为粘附-反弹行为。我们展示了不同条件下的相图,如弹丸刚度、冲击速度、石墨烯尺寸、弹丸尺寸和弹丸密度。本研究为多尺度碰撞现象的研究提供了新的视角,并为转移印刷、碰撞保护等的设计提供了指导策略。来源:复合材料力学仿真Composites FEM

未登录
还没有评论
课程
培训
服务
行家
VIP会员 学习 福利任务 兑换礼品
下载APP
联系我们
帮助与反馈