Flexible Carbon(柔性碳)研究综述
Flexible Carbon 柔性碳 - However, the low energy density of the flexible carbon-based flexible solid supercapacitor has become a major bottleneck for their wide application in the future. [1] Flexible carbon-based catalysts for ORR/OER catalysis can be broadly categorized into two types: (i) self-supporting catalysts based on the in situ modification of flexible substrates; (ii) non-self-supporting catalysts based on surface coatings of flexible substrates. [2] In this study, we describe the fabrication of flexible carbonized paper (f-CP) from toilet paper samples using a sandwich-type installation technique in a thermal chemical vapor deposition system. [3] In this study, we fabricated a flexible carbon-nanotube/polydimethylsiloxane composite with a high content of carbon nanotube (20 wt%) for airplane de-icing. [4] Herein, the latest advances in the preparation of flexible carbon-based strain sensors are reviewed according to the strain types. [5] The proposed TEG device architecture is easily scalable, enabling large-scale printing manufacturing opportunities towards highly efficient, high-operating temperature, printed and flexible carbon-based TEGs. [6] Herein, a flexible carbon-based composite membrane embedded with nano-silicon particles and graphene is successfully developed via simple precursor preparation and carbonization processes. [7] The flexible carbon-based [TiO2/C]//[Bi2WO6/C] Janus nanofiber with one side responding to ultraviolet light and the other capturing visible light is fabricated by conjugate electrospinning, and then g-C3N4 nanosheets are uniformly grown in-situ on the surface of the Janus nanofibers by using gas-solid reaction via gasification of urea. [8] The relatively low specific capacitance of flexible carbons hinders their practical application for fabricating high-performance flexible supercapacitors. [9] After subsequently two-step morphology-preserved thermal transformation process, the derived superstructures are comprised of hollow Co3O4 nanosphere embedded in carbon frameworks on flexible carbon-fiber cloth (CC/ZIFs-300). [10] Herein, the flexible carbon-fibersupported carbon-sulfur electrode was prepared, and its physical properties and electrochemical performance were characterized. [11] Our study paves the way for developing highly efficient and flexible carbon-based perovskite solar cells. [12] The overall inhibitory profile is comparable to or better than that of previous HPD subtypes with a flexible C-6 linker, suggesting that the nonflexible carbonyl linker can be tolerated in the design of novel HIV RNase H active site inhibitors. [13]然而,柔性碳基柔性固体超级电容器的低能量密度已成为其未来广泛应用的主要瓶颈。 [1] 用于 ORR/OER 催化的柔性碳基催化剂可大致分为两类:(i)基于柔性基底原位改性的自支撑催化剂; (ii) 基于柔性基材表面涂层的非自支撑催化剂。 [2] 在这项研究中,我们描述了在热化学气相沉积系统中使用夹层式安装技术从卫生纸样品制造柔性碳化纸 (f-CP)。 [3] 在这项研究中,我们制造了一种柔性碳纳米管/聚二甲基硅氧烷复合材料,其碳纳米管含量高(20 wt%),用于飞机除冰。 [4] 本文根据应变类型回顾了制备柔性碳基应变传感器的最新进展。 [5] 所提出的 TEG 设备架构易于扩展,从而为高效、高工作温度、印刷和柔性碳基 TEG 提供大规模打印制造机会。 [6] 在此,通过简单的前驱体制备和碳化工艺成功开发了一种嵌入纳米硅颗粒和石墨烯的柔性碳基复合膜。 [7] 采用共轭静电纺丝制备柔性碳基[TiO2/C]//[Bi2WO6/C] Janus纳米纤维,一侧响应紫外光,另一侧捕获可见光,然后原位均匀生长g-C3N4纳米片通过尿素的气化利用气固反应在 Janus 纳米纤维的表面上。 [8] 柔性碳相对较低的比电容阻碍了它们在制造高性能柔性超级电容器中的实际应用。 [9] 在随后的两步形态保持热转变过程之后,衍生的超结构由嵌入在柔性碳纤维布(CC/ZIFs-300)上的碳框架中的空心 Co3O4 纳米球组成。 [10] 在此,制备了柔性碳纤维负载碳硫电极,并对其物理性质和电化学性能进行了表征。 [11] 我们的研究为开发高效和灵活的碳基钙钛矿太阳能电池铺平了道路。 [12] 总体抑制谱与先前具有柔性 C-6 接头的 HPD 亚型相当或更好,这表明在设计新型 HIV RNase H 活性位点抑制剂时可以耐受非柔性羰基接头。 [13]
facile two step
In this work, a hybrid structure of CoO nanowires coated with conformal polypyrrole (Ppy) nanolayer is proposed, designed and fabricated on a flexible carbon substrate through a facile two-step method. [1] Here we investigated a facile two-step hydrothermal approach to fabricate MoS2/Ketjen black (KB) composites on flexible carbon cloth. [2] CuO nanorods have been directly fabricated on flexible carbon cloth (CC) substrate via a facile two-step strategy of magnetron sputtering Cu followed by thermal oxidation, forming a C-doped CuO nanorods/CuO layer/Cu2O layer/CC hierarchical network composite (CC-CuO). [3]在这项工作中,通过简便的两步法,在柔性碳基板上提出、设计和制造了一种涂覆有保形聚吡咯 (Ppy) 纳米层的 CoO 纳米线的混合结构。 [1] 在这里,我们研究了一种在柔性碳布上制造 MoS2/科琴黑 (KB) 复合材料的简便两步水热法。 [2] nan [3]
nitrogen doped carbon 氮掺杂碳
Herein, hierarchical MoC@Ni-NCNT arrays are reported as a multifunctional sulfur host in Li-S batteries, which comprised a flexible carbon fiber cloth substrate decorated with vertical MoC porous nanorods rooted by interconnected nitrogen-doped carbon nanotubes (NCNTs). [1] In this work, we developed a novel and facile strategy for the synthesis of a highly active and stable electrocatalyst based on PdCu alloy nanoparticles (PdCu-ANPs) embedded in 3D nitrogen-doped carbon (NC) nanofoam arrays (NFAs), which were assembled on flexible carbon fiber (CF) microelectrode for in situ sensitive electrochemical detection of biomarker H2O2 in cancer cells. [2]在此,分层 MoC@Ni-NCNT 阵列被报道为 Li-S 电池中的多功能硫主体,它包含一个柔性碳纤维布基板,该基板装饰有垂直的 MoC 多孔纳米棒,该纳米棒植根于互连的氮掺杂碳纳米管 (NCNT)。 [1] 在这项工作中,我们开发了一种新颖而简便的策略,用于合成基于嵌入 3D 氮掺杂碳 (NC) 纳米泡沫阵列 (NFA) 中的 PdCu 合金纳米颗粒 (PdCu-ANPs) 的高活性和稳定的电催化剂,并组装柔性碳纤维 (CF) 微电极用于原位灵敏电化学检测癌细胞中的生物标志物 H2O2。 [2]
Highly Flexible Carbon 高弹性碳
Additionally, the highly flexible carbon fiber matrix could bear the load of bending and twisting, leading to excellent flexibility and reliability. [1] Herein, vertical-aligned SnS2 nanosheet arrays (SnS2 NSA) with intrinsic lithiophilic nature, endowed by in situ formed Li13Sn5 via the alloying reaction of SnS2, are uniformly decorated on highly flexible carbon foam (SnS2 NSA@CF) to overcome the encountered issues of ordinary carbon skeletons. [2] Herein, we report a controlled growth of single crystal mesoporous zinc ferrite (ZnFe2O4) nanowall arrays on highly flexible carbon textile for flexible supercapacitors. [3] The highly flexible carbon nanofibers mixed with differently functionalized carbon nanotubes (MWNTs) and terephthalic acid (PTA) were fabricated and further applied as a binder-free electrode. [4]此外,高度柔韧的碳纤维基体可以承受弯曲和扭曲的载荷,从而具有出色的柔韧性和可靠性。 [1] 在此,通过 SnS2 的合金化反应原位形成的 Li13Sn5 赋予具有固有亲锂性质的垂直排列的 SnS2 纳米片阵列 (SnS2 NSA),均匀地装饰在高柔性碳泡沫 (SnS2 NSA@CF) 上,以克服遇到的问题普通的碳骨架。 [2] 在这里,我们报告了单晶介孔铁酸锌 (ZnFe2O4) 纳米壁阵列在用于柔性超级电容器的高柔性碳织物上的受控生长。 [3] 制备了与不同功能化碳纳米管 (MWNT) 和对苯二甲酸 (PTA) 混合的高柔性碳纳米纤维,并进一步用作无粘合剂电极。 [4]
Conductive Flexible Carbon 导电柔性碳
In this work, we fabricated the three-dimensional hierarchical structure ZnO@MnO2 hybrid material on highly conductive flexible carbon cloth (CC) via hydrothermal method and thermal decomposition method for high-performance supercapacitors. [1] The strategy consists of producing interpenetrated networks of highly conductive flexible carbon nanotube (CNT) fibre fabrics and nanostructured metal oxides, γAl2O3 and TiO2, through ultrasound-assisted nanoparticle infiltration and sintering. [2] In this study, we fabricated the hierarchical NiCo2S4@CoS2 nanostructures on highly conductive flexible carbon cloth (CC) via two-steps hydrothermal method for high-performance supercapacitor hybrid electrode material. [3]在这项工作中,我们通过水热法和热分解法在高性能超级电容器中制备了高导电柔性碳布(CC)上的三维分层结构 ZnO@MnO2 杂化材料。 [1] 该策略包括通过超声辅助纳米颗粒渗透和烧结生产高导电柔性碳纳米管 (CNT) 纤维织物和纳米结构金属氧化物 γAl2O3 和 TiO2 的互穿网络。 [2] nan [3]
Performance Flexible Carbon 高性能柔性碳
Due to this, a fast and feasible non-solvent induced phase separation method, combining with stabilization and carbonization, was provided to fabricate high performance flexible carbon membrane from polyacrylonitrile (PAN) with the presence of N,N-dimethylformamide (non-solvent). [1] In this work, converting cotton fabrics into high-performance flexible carbon electrodes are achieved successfully by using traditional dyeing, flame retardant finishing and carbonization processes for wearable supercapacitors. [2]鉴于此,提供了一种快速可行的非溶剂诱导相分离方法,结合稳定化和碳化,在 N,N-二甲基甲酰胺(非溶剂)的存在下从聚丙烯腈(PAN)制备高性能柔性碳膜。 . [1] 在这项工作中,通过对可穿戴超级电容器采用传统的染色、阻燃整理和碳化工艺,成功地将棉织物转化为高性能柔性碳电极。 [2]
flexible carbon cloth 柔性碳布
The ratio of O/C on the surface of flexible carbon cloth was well tuned through O2-plasma to achieve the desired geometric structure of NiMoO wafers with features of rich porosity and abundant active site. [1] Here, novel Fe-Co-Ni-P nanosheet arrays are in situ synthesized on a flexible carbon cloth substrate via an electrodeposition method followed by a phosphorization treatment. [2] We prepared 1T-PtSe2 films on a flexible carbon cloth through a facile yet effective approach. [3] In this study, we developed a hydrothermal growth of free-standing cobalt oxide (Co3O4) nanoneedle arrays on a flexible carbon cloth (CC) substrate and used them as electrode materials with a high catalytic activity for nonenzymatic glucose sensing. [4] In this work, Pd@UiO-66-on-ZIF-L nanomaterials were successfully synthesised onto a self-supported flexible carbon cloth (Pd@UiO-66-on-ZIF-L/CC) through a novel strategy called MOF-on-MOF. [5] With this perspective notion, herein, we fabricated electrically conducting polymer-based flexible carbon cloth (CC) electrodes and assessed their electrochemical performance. [6] In this work, we fabricated the three-dimensional hierarchical structure ZnO@MnO2 hybrid material on highly conductive flexible carbon cloth (CC) via hydrothermal method and thermal decomposition method for high-performance supercapacitors. [7] Herein, Co is introduced into conductive Cu-catecholate (Cu-CAT) nanorod arrays directly grown on a flexible carbon cloth for hydrogen evolution reaction (HER). [8] The promising cathode (NVPOF@FCC) with high conductivity and outstanding flexibility is prepared by efficiently coating Na3V2(PO4)2O2F (NVPOF) on flexible carbon cloth (FCC), which exhibits remarkable electrochemical performance and the significantly improved reaction kinetics. [9] We report a facile strategy to prepare carbon nanotubes embedded with hollow CoP nanoparticles arrays (H-CoP-NPs@CNTs) on flexible carbon cloth through hydrothermal synthesis, carbothermal reduction and phosphorization. [10] Then, this flexible carbon cloth was doped with nickel. [11] Herein, a 3D conductive host comprising lithiophilic ZnO nanoneedle arrays grown on a flexible carbon cloth is designed to pre-store Li via thermal infusion strategy and Li@ZnO@carbon cloth (denoted as Li@ZnO@CC) electrode is formed. [12] In this report, for the first time, we have fabricated 1T-WS2 in 3D-dendritic nanostructures over flexible carbon cloth (CC) following doping and intercalation of Fe and P (1T-Fe/P-WS2@CC). [13] Herein, a phosphate-modified hierarchical nanoarray consisting of a heterojunction with a well-aligned cobalt phosphide nanowire core and nickel phosphide nanosheet shell on flexible carbon cloth (denoted as CoP@Ni2P-CC) is engineered. [14] Herein, a free-standing Ni–Mn–S@NiCo2S4core–shell heterostructure has been rationally synthesized on flexible carbon cloth through a two-step electrodeposition method. [15] A novel sulfur matrix integrating self-branched Nb2O5 nanoarrays and flexible carbon cloth (NBCC) is designed. [16] The Prussian blue analogue (PBA) is an electrochemically active material grafted on flexible carbon cloth substrates, which had been precoated with polyaniline. [17] Herein, a flexible carbon cloth nanocomposite with a biomimetic pelargonium hortorum-petal-like surface that embraces all desirable chemical and physical properties, that is, enhanced light acquisition, excellent photothermal property, and operational durability, for high-performance solar-driven interfacial water evaporation distillation is reported. [18] The present work reports, direct growth of binary metal hydroxide ((Mn(OH)2)/(Co(OH)2)) nanocomposite on flexible carbon cloth substrate by a simple and affordable chemical bath deposition method. [19] The 3D FeCoP@NiCoP nanosheet arrays grown on a flexible carbon cloth substrate can provide an efficient nanoporous framework, facilitate the electron/ion transport, and generate the effective synergy of good conductivity from FeCoP and superior redox activity from NiCoP. [20] Herein, we have fabricated three-dimensional (3D) GN nanosheets (GNSs) on flexible carbon cloth (CC) by thermal chemical vapor deposition (CVD). [21] For this, the 2D WO3/Se nanocomposite synthesized by a hydrothermal method followed by air annealing was coated on a flexible carbon cloth current collector and combined separately with both 0. [22] For this purpose, herein, we demonstrate the design and synthesis of ultrathin α-Ni(OH)2 nanosheets branched onto metal-organic frameworks (MOFs)-derived 3D cross-linked N-doped carbon nanotubes encapsulated with tiny Co nanoparticles (denoted as Co@NCNTs/α-Ni(OH)2), which are directly supported on a flexible carbon cloth (CC). [23] Here, we account a unique multifunctional flake-like CoS deposited over the flexible carbon cloth (CoS@CC) by a facile hydrothermal technique. [24] Herein, we design a new 3D hierarchical hybrid sandwich flexible structure by anchoring SnO2 nanosheets (SnO2-NSs) on flexible carbon cloth and coating with thin amorphous carbon (AC) layer (CF@SnO2-NS@AC). [25] Herein, we propose a facile strategy to prepare hierarchical flower-like MoO2@ N, P co-doped carbon (NPC) hybrids on flexible carbon cloth (CC) as a self-standing and binder-free anode for sodium ion batteries. [26] Herein, a strategy called MOF‐on‐MOF (MOF, metal‐organic framework) is presented for the structural design of air cathodes, which creatively develops an efficient oxygen catalyst comprising hierarchical Co3O4 nanoparticles anchored in nitrogen‐doped carbon nano‐micro arrays on flexible carbon cloth (Co3O4@N‐CNMAs/CC). [27] Herein, bimetallic sulfide (ZnxCo1−xS) nanoparticle-embedded in nitrogen-doped carbon directly grown on a flexible carbon cloth (ZnxCo1−xS-NC) as a binder-free electrode with high pseudocapacitive charge storage and excellent stability was designed. [28] A convenient and scalable hydrothermal method was developed for the fabrication of the core-branch Fe2O3@NiO nanorods arrays directly grown on flexible carbon cloth (denoted as Fe2O3@NiO/CC). [29] The low-cost continuous preparation method with high performance endows the flexible carbon cloth various promising applications, such as flexible asymmetric supercapacitors, flexible battery, catalysts and surface treatment. [30] In this work, we successfully printed graphite oxide and Ag nanoparticles on the substrate of flexible carbon cloth to form a flexible, conductive and hydrophilic layer, which could be used as a new substrate with an electron transport layer of large surface area. [31] Herein, we report the direct growth of mesoporous 2D zinc cobaltite nanosheets on a flexible carbon cloth substrate (Zn–Co–O@CC) with an average thickness of ∼45 nm by a facile hydrothermal method at low temperature. [32] Herein, a facile and versatile sol-gel fabrication strategy followed by heat treatment is developed to synthesize Na4Fe3(PO4)2(P2O7)@NaFePO4@C core-double-shell architectures grown on flexible carbon cloth, which can be directly used as a binder-free cathode for high-performance sodium ion batteries. [33] Herein, we present a facile strategy in which cobalt nitride (Co4N) nanoparticles embedded leaf-like porous carbon nanosheet arrays are grown on flexible carbon cloth as a free-standing cathode for high-performance LSBs. [34] When loaded on flexible carbon cloth for electrochemical capacitor, the CoNi2S4 nanosheets deliver a high specific capacitance of 247 mAh g−1 at 8 A g−1 with an excellent rate capability of 91% from 1 to 20 A g−1. [35] The as-prepared LaCrO 3 powders is mingled with activated carbon and subsequently glazed on a flexible carbon cloth current collector (LCO@CC). [36] In this study, we fabricated the hierarchical NiCo2S4@CoS2 nanostructures on highly conductive flexible carbon cloth (CC) via two-steps hydrothermal method for high-performance supercapacitor hybrid electrode material. [37] Herein, the hierarchical Co(OH)2@Ni(OH)2 core-shell nanosheets on flexible carbon cloth (CC) were designed and prepared as advanced OER catalysts. [38] Here we investigated a facile two-step hydrothermal approach to fabricate MoS2/Ketjen black (KB) composites on flexible carbon cloth. [39] MoO 2 and MoO 3 with specific morphologies are synthesized on flexible carbon cloth through a facile hydrothermal method as supercapacitor electrodes. [40] CuO nanorods have been directly fabricated on flexible carbon cloth (CC) substrate via a facile two-step strategy of magnetron sputtering Cu followed by thermal oxidation, forming a C-doped CuO nanorods/CuO layer/Cu2O layer/CC hierarchical network composite (CC-CuO). [41] Herein, a novel sulfur cathode integrating sulfur, flexible carbon cloth, and metal-organic framework (MOF)-derived N-doped carbon nanoarrays with embedded CoP (CC@CoP/C) is designed. [42] In this work, the hybrid binder-free supercapacitor electrode material of MoS2 nanosheets FeCo2O4 nanowires on flexible carbon cloth (CC) substrate was fabricated using two-step hydrothermal approach. [43] The specific areal capacitance of the flexible carbon cloth-based electrodes reaches 2. [44] A hierarchical core-shell Co3O4/CuO nanorod array (NRA) anchored on flexible carbon cloth (CC) has been fabricated through a stepwise process consisting of magnetron sputtering of Cu, its anodic oxidation, and chemical bath deposition of Co3O4. [45]通过O2-等离子体对柔性碳布表面的O/C比进行了很好的调节,以实现具有丰富孔隙率和丰富活性位点的NiMoO晶片所需的几何结构。 [1] 在这里,新型 Fe-Co-Ni-P 纳米片阵列通过电沉积方法在柔性碳布基板上原位合成,然后进行磷化处理。 [2] 我们通过一种简单而有效的方法在柔性碳布上制备了 1T-PtSe2 薄膜。 [3] 在这项研究中,我们在柔性碳布 (CC) 基板上开发了一种独立的氧化钴 (Co3O4) 纳米针阵列的水热生长方法,并将它们用作具有高催化活性的非酶葡萄糖传感电极材料。 [4] nan [5] 有了这个观点,我们在此制造了基于导电聚合物的柔性碳布 (CC) 电极并评估了它们的电化学性能。 [6] 在这项工作中,我们通过水热法和热分解法在高性能超级电容器中制备了高导电柔性碳布(CC)上的三维分层结构 ZnO@MnO2 杂化材料。 [7] 在此,Co 被引入直接生长在柔性碳布上的导电铜邻苯二酚 (Cu-CAT) 纳米棒阵列中,用于析氢反应 (HER)。 [8] 通过在柔性碳布 (FCC) 上高效包覆 Na3V2(PO4)2O2F (NVPOF) 制备了具有高导电性和出色柔韧性的有前景的正极 (NVPOF@FCC),该正极材料表现出显着的电化学性能和显着改善的反应动力学。 [9] 我们报告了一种简便的策略,通过水热合成、碳热还原和磷化来制备在柔性碳布上嵌入空心 CoP 纳米颗粒阵列 (H-CoP-NPs@CNTs) 的碳纳米管。 [10] 然后,在这种柔性碳布上掺杂镍。 [11] 在此,设计了一种包含在柔性碳布上生长的亲锂ZnO纳米针阵列的3D导电主体,通过热灌注策略预储存锂,并形成了Li@ZnO@碳布(表示为Li@ZnO@CC)电极。 [12] 在本报告中,我们首次在掺杂和嵌入 Fe 和 P (1T-Fe/P-WS2@CC) 后,在柔性碳布 (CC) 上制造了 3D 树枝状纳米结构的 1T-WS2。 [13] 在此,设计了一种磷酸盐修饰的分级纳米阵列,该阵列由具有良好排列的磷化钴纳米线核心和磷化镍纳米片壳在柔性碳布(表示为 CoP@Ni2P-CC)上的异质结组成。 [14] 在此,通过两步电沉积法在柔性碳布上合理合成了一个独立的Ni-Mn-S@NiCo2S4核壳异质结构。 [15] 设计了一种集成自支化 Nb2O5 纳米阵列和柔性碳布 (NBCC) 的新型硫基体。 [16] nan [17] nan [18] nan [19] nan [20] nan [21] nan [22] nan [23] 在这里,我们考虑了一种独特的多功能片状 CoS,它通过一种简便的水热技术沉积在柔性碳布 (CoS@CC) 上。 [24] 在此,我们通过将 SnO2 纳米片 (SnO2-NSs) 锚定在柔性碳布上并涂上薄无定形碳 (AC) 层 (CF@SnO2-NS@AC) 设计了一种新的 3D 分层混合夹层柔性结构。 [25] nan [26] nan [27] nan [28] nan [29] nan [30] nan [31] nan [32] nan [33] nan [34] nan [35] nan [36] nan [37] nan [38] 在这里,我们研究了一种在柔性碳布上制造 MoS2/科琴黑 (KB) 复合材料的简便两步水热法。 [39] nan [40] nan [41] nan [42] nan [43] nan [44] nan [45]
flexible carbon nanotube 柔性碳纳米管
This work reports the electrochemical characterization of flexible carbon nanotube (CNT) based asymmetric supercapacitors (SCs) made with ≈90% of biodegradable components. [1] The polar and catalytic CoS can promote the redox process and reduce the dissolution of polysulfides, while the flexible carbon nanotubes can buffer the expansion/shrinkage of the electrode during charging and discharging. [2] Ultrathin, lightweight, and flexible carbon nanotube buckypaper enhanced using MXenes (Ti 3 C 2 T x ) for high-performance electromagnetic interference shielding is synthesized through facile electrophoretic deposition. [3] The strategy consists of producing interpenetrated networks of highly conductive flexible carbon nanotube (CNT) fibre fabrics and nanostructured metal oxides, γAl2O3 and TiO2, through ultrasound-assisted nanoparticle infiltration and sintering. [4] In this work the parallel component of the static dielectric permittivity, ϵII of ionic liquids ultraconfined into flexible carbon nanotubes of radius of 1. [5] A free-standing flexible carbon nanotube/sulfur (CNT/S) composite cathode based on CNT film to form a conductive network on a sulfur substrate is proposed herein. [6] The fabrication and electrochemical characterization of flexible carbon nanotube (CNT) based supercapacitors (SCs) with and without Ni@TiO2:W (TiNiW) nanoparticles (NPs) are reported. [7] In this study, to build a low-voltage activating, fast responding ETA, a robust and flexible carbon nanotube film (CNTF) with excellent electrical and thermal conductivity was adopted as the conductive material. [8] Herein, we report a silicon/carbon nanotube (Si/CNT) composite made of an externally grown flexible carbon nanotube (CNT) network to confine inner multiple Silicon (Si) nanoparticles (Si NPs). [9] A multifaceted photo-thermoelectric device design based on flexible carbon nanotube films facilitates the prototype demonstrations of non-destructive, target-structure-independent, free-form multi-view examinations on actual three-dimensional industrial components. [10] Furthermore, the overall perfromance of LMC is further evaluated by employing a Li dendrite-free flexible carbon nanotube network current collector, the constructed LMC based on the weight of the entire device still delivered a high energy density of 115. [11] Here, we report a multimodal artificial sensory-memory system consisting of sensors for generating biomimetic visual, auditory, tactile inputs, and flexible carbon nanotube synaptic transistor that possesses synapse-like signal processing and memorizing behaviors. [12] Owing to above-mentioned properties, the highest porous film (PM66) shows improved electrochemical properties with flexible carbon nanotube-based composite electrode, which makes it a potential candidate as a separator for the flexible Li-ion batteries. [13] Here, inspired by the flexible scales of the Morpho aega butterfly wing, synthetic surfaces coated with flexible carbon nanotube (CNT) microscales with anisotropic drop adhesion properties are fabricated. [14] Herein, MOFs derived NiCo-layered double-hydroxide (NiCo-LDH) and nitrogen-doped carbon nanosheets (NC) on the flexible carbon nanotubes (CNTs) film are rationally designed, both of which as the binder-free electrodes can greatly improve the specific surface area and reaction sites. [15] Herein, flexible carbon nanotube (CNT) interconnects were formed from Ni alloy (Ni95AlSiMn) wires to the SiCN semiconductor through the direct growth of CNT on the Ni alloy wires during the synthesis of SiCN itself by a polymer-ceramic conversion reaction. [16] HighlightsAn ultrathin and flexible carbon nanotubes/MXene/cellulose nanofibrils composite paper with gradient and sandwich structure was successfully fabricated via a facile alternating vacuum-assisted filtration process. [17] We have developed a stretchable Li anode by infusing molten Li into the robust and flexible carbon nanotube (CNT) fibers modified with lithiophilic ZnO nanowire arrays. [18]这项工作报告了由约 90% 的可生物降解成分制成的基于柔性碳纳米管 (CNT) 的不对称超级电容器 (SC) 的电化学表征。 [1] 极性和催化的CoS可以促进氧化还原过程并减少多硫化物的溶解,而柔性碳纳米管可以缓冲电极在充放电过程中的膨胀/收缩。 [2] 通过简便的电泳沉积合成了使用 MXenes (Ti 3 C 2 T x ) 增强的超薄、轻质和柔性碳纳米管巴基纸,用于高性能电磁干扰屏蔽。 [3] 该策略包括通过超声辅助纳米颗粒渗透和烧结生产高导电柔性碳纳米管 (CNT) 纤维织物和纳米结构金属氧化物 γAl2O3 和 TiO2 的互穿网络。 [4] 在这项工作中,离子液体的静态介电常数 εII 的平行分量被超限制在半径为 1 的柔性碳纳米管中。 [5] nan [6] 报道了具有和不具有 Ni@TiO2:W (TiNiW) 纳米粒子 (NPs) 的柔性碳纳米管 (CNT) 基超级电容器 (SCs) 的制造和电化学表征。 [7] 在这项研究中,为了构建低电压激活、快速响应的 ETA,采用坚固且灵活的碳纳米管薄膜 (CNTF) 作为导电材料,该薄膜具有优异的导电性和导热性。 [8] nan [9] 基于柔性碳纳米管薄膜的多面光热电器件设计有助于对实际 3D 工业部件进行无损、与目标结构无关、自由形式的多视图检查的原型演示。 [10] nan [11] nan [12] nan [13] 在这里,受 Morpho aega 蝴蝶翅膀的柔性鳞片的启发,制造了涂有具有各向异性滴粘附特性的柔性碳纳米管 (CNT) 微尺度的合成表面。 [14] 在这里,MOFs衍生的NiCo层状双氢氧化物(NiCo-LDH)和柔性碳纳米管(CNTs)薄膜上的氮掺杂碳纳米片(NC)经过合理设计,两者作为无粘合剂电极可以大大提高比表面积和反应位点。 [15] nan [16] nan [17] nan [18]
flexible carbon fiber 柔性碳纤维
Herein, hierarchical MoC@Ni-NCNT arrays are reported as a multifunctional sulfur host in Li-S batteries, which comprised a flexible carbon fiber cloth substrate decorated with vertical MoC porous nanorods rooted by interconnected nitrogen-doped carbon nanotubes (NCNTs). [1] Additionally, the highly flexible carbon fiber matrix could bear the load of bending and twisting, leading to excellent flexibility and reliability. [2] Herein, we report a three-component photocatalyst by constructing porous amine functionalized zirconium metal organic framework (UiO-66-NH2) and broad photo-responsive AgI on flexible carbon fiber cloth (CFC). [3] We hypothesized that patients who wear a flexible carbon fiber insole for 1st metatarsophalangeal arthritis will report reduced pain, and higher physical function and compliance rate when compared with a rigid Mortons extension insole. [4] In this work, we developed a novel and facile strategy for the synthesis of a highly active and stable electrocatalyst based on PdCu alloy nanoparticles (PdCu-ANPs) embedded in 3D nitrogen-doped carbon (NC) nanofoam arrays (NFAs), which were assembled on flexible carbon fiber (CF) microelectrode for in situ sensitive electrochemical detection of biomarker H2O2 in cancer cells. [5] We reported an efficient fabrication strategy for a three-dimensional structure based on large-area flexible carbon fiber cloth decorated by Ag nanoparticles (AgNPs-CFC). [6] Herein, a flexible carbon fiber cloth/UCNP composite probe was fabricated for sensing copper(II) (Cu2+) ions and an electrochemical (E-chem) technique was implemented for the first time to enhance its sensing performance. [7] In this work, the design and synthesis of vertically grown MoS2 nanosheet arrays, decorated with graphite carbon and Fe2 O3 nanoparticles, on flexible carbon fiber cloth (denoted as Fe2 O3 @C@MoS2 /CFC) is reported. [8] Here, a flexible integrated sensor based on Au nanoparticle modified copper hydroxide nanograss arrays on flexible carbon fiber cloth (Au@Cu(OH)2/CFC) is fabricated by a facile electrochemical method. [9] In this work, with the flexible carbon fiber (CF) fabric and polyphenylene sulfide (PPS) nonwovens as reinforcement and matrix, respectively, the composites were prepared by thermo-compression lamination to obtain the rigid CF/PPS composite laminates. [10] In the present work, spinel lithium titanate (Li4 Ti5 O12 , LTO) cuboid arrays are grown on flexible carbon fiber cloth (CFC) to fabricate a binder-free composite electrode (LTO@CFC) for flexible lithium-ion batteries. [11] They consist of thin flexible carbon fiber and latex rubber membranes of varying strengths. [12] Hafnium carbide nanowires (HfCnw) and a small amount of hafnium carbide nanobelts (HfCnb) were incorporated in a flexible carbon fiber felt by catalysis-assisted chemical vapor deposition to fabricate an electromagnetic interference (EMI) shielding carbon-based material with excellent electromagnetic wave absorption properties. [13] Moreover, the conductivity, physical flexibility, and stability of the flexible carbon fiber cloth gives this substrate potential in other fields such as electrochemistry. [14] Viewed through the lens of the recently completed series of quarter-scale cloudMAGNET prototypes tested in the cloud forests of Monteverde, Costa Rica, this research utilized a wound, flexible carbon fiber framework and a lightweight fabric skin coated with varying densities of microPCM. [15] This study aimed to develop a flexible carbon fiber/oxide layer coating composite with improved electrical properties for use in electronic devices. [16] In this work, Pt nanoparticles modified nanoporous AuSn(Pt@NP-AuSn) alloy on Ni buffered flexible carbon fiber paper (CFP) is fabricated by a simple replacement reaction in which NP-AuSn is fabricated by controllable dealloy of electrodeposited Au-Sn alloy films. [17] A noteworthy enhancement on the scratch resistance of flexible carbon fiber-reinforced polymer composites (FCFRPCs), by a rapid deposition (a short exposure duration of 150 s) of organosilicon oxide (SiOxCy) films, with an atmospheric pressure plasma jet (APPJ), via the addition of air gases at various flow rates, has been investigated. [18]在此,分层 MoC@Ni-NCNT 阵列被报道为 Li-S 电池中的多功能硫主体,它包含一个柔性碳纤维布基板,该基板装饰有垂直的 MoC 多孔纳米棒,该纳米棒植根于互连的氮掺杂碳纳米管 (NCNT)。 [1] 此外,高度柔韧的碳纤维基体可以承受弯曲和扭曲的载荷,从而具有出色的柔韧性和可靠性。 [2] 在此,我们通过在柔性碳纤维布 (CFC) 上构建多孔胺功能化锆金属有机骨架 (UiO-66-NH2) 和宽光响应 AgI,报告了一种三组分光催化剂。 [3] 我们假设,与刚性 Mortons 延伸鞋垫相比,佩戴柔性碳纤维鞋垫治疗第一跖趾关节炎的患者会报告疼痛减轻,身体机能和顺应性更高。 [4] 在这项工作中,我们开发了一种新颖而简便的策略,用于合成基于嵌入 3D 氮掺杂碳 (NC) 纳米泡沫阵列 (NFA) 中的 PdCu 合金纳米颗粒 (PdCu-ANPs) 的高活性和稳定的电催化剂,并组装柔性碳纤维 (CF) 微电极用于原位灵敏电化学检测癌细胞中的生物标志物 H2O2。 [5] nan [6] 在此,制备了一种柔性碳纤维布/UCNP复合探针用于传感铜(II)(Cu2+)离子,并首次实施了电化学(E-chem)技术以提高其传感性能。 [7] 在这项工作中,报道了在柔性碳纤维布(表示为 Fe2 O3 @C@MoS2 /CFC)上垂直生长的 MoS2 纳米片阵列的设计和合成,该阵列装饰有石墨碳和 Fe2O3 纳米颗粒。 [8] nan [9] nan [10] nan [11] nan [12] nan [13] nan [14] nan [15] nan [16] nan [17] nan [18]
flexible carbon nanofiber 柔性碳纳米纤维
To solve these obstacles, we design a cobalt sulfide nanoparticle-embedded flexible carbon nanofiber membrane (denoted as CoS2@NCF) as sulfiphilic functional interlayer materials. [1] Herein, we synthesize and design metal–organic framework-derived CoNi-P nanoparticles confined into a flexible carbon nanofiber skeleton (C@CoNi-P@C) as ORR catalysts with excellent activity. [2] In this study, a lignin/polyacrylonitrile (PAN) composite nanofiber membrane is prepared by electrospinning and used as the precursor to prepare flexible carbon nanofibers (CNFs) through pre-oxidat. [3] Herein, a poly (acrylonitrile-co-methylhydrogen itaconate) copolymer (P(AN-co-MHI)) was synthesized for flexible carbon nanofiber (CNF) by electrospinning. [4] Furthermore, the flexible carbon nanofiber paper (CNP) has also been investigated as a novel current collector with lithium storage for application in LIBs, and the capacity of free-standing α-Fe2O3/50 wt%MWCNTs/CNP hybrids electrode can retain 467. [5] In this study, flexible carbon nanofiber/boron nitride composites were prepared via a facile electrospinning and subsequent carbonization treatment for lithium ion battery. [6] The highly flexible carbon nanofibers mixed with differently functionalized carbon nanotubes (MWNTs) and terephthalic acid (PTA) were fabricated and further applied as a binder-free electrode. [7] Sol-gel and electrospinning techniques were employed to produce flexible carbon nanofibers and polyaniline coating was applied via in-situ chemical polymerization to further improve the electrochemical properties of the electrodes. [8]为了解决这些障碍,我们设计了一种嵌入硫化钴纳米颗粒的柔性碳纳米纤维膜(表示为 CoS2@NCF)作为亲硫功能层间材料。 [1] 在此,我们合成并设计了金属有机骨架衍生的 CoNi-P 纳米粒子,该纳米粒子被限制在柔性碳纳米纤维骨架(C@CoNi-P@C)中,作为具有优异活性的 ORR 催化剂。 [2] nan [3] 在此,通过静电纺丝合成了用于柔性碳纳米纤维(CNF)的聚(丙烯腈-共-衣康酸甲基氢)共聚物(P(AN-co-MHI))。 [4] 此外,柔性碳纳米纤维纸(CNP)也被研究作为一种具有锂存储的新型集电器,用于锂离子电池,自支撑α-Fe2O3/50wt%MWCNTs/CNP混合电极的容量可以保持467。 [5] nan [6] 制备了与不同功能化碳纳米管 (MWNT) 和对苯二甲酸 (PTA) 混合的高柔性碳纳米纤维,并进一步用作无粘合剂电极。 [7] nan [8]
flexible carbon chain 柔性碳链
The longer and flexible carbon chains may be aggregated to form the hydrophobic region, repulsing the hydrated ReO4- anions. [1] Because the flexible carbon chain of HDI has the advantages of easy bending and deformation, the problem of large steric hindrance and low reactivity of -OH during water-based CDA can be solved by using the method of converting reactive functional groups and transferring reactive sites. [2] The flexible carbon chain of the citrate (3-) anion exhibits conformational disorder in 3, whereas the citrate (3-) anion in 2 as well as the citrate (−) mono anion in 1 are ordered. [3] The excellent durability of the molecular anode should be attributed to the key charge-neutral catalytic intermediates (Ru1a∼d) of the catalytic step and the two long flexible carbon chains of the catalyst. [4] The results are discussed in terms of the length of the CmH2m flexible carbon chain of the homologues. [5] ABSTRACT Polyamines are small polycationic molecules with flexible carbon chains that are found in all eukaryotic cells. [6]较长且柔韧的碳链可以聚集形成疏水区域,排斥水合的 ReO4- 阴离子。 [1] 由于HDI的柔性碳链具有易于弯曲和变形的优点,水性CDA中-OH的空间位阻大、反应性低的问题可以通过反应性官能团的转换和反应性位点转移的方法来解决。 [2] 柠檬酸盐(3-)阴离子的柔性碳链在3中表现出构象无序,而2中的柠檬酸盐(3-)阴离子以及1中的柠檬酸盐(-)单阴离子是有序的。 [3] 分子阳极的优异耐久性应归功于催化步骤的关键电荷中性催化中间体(Ru1a∼d)和催化剂的两条长柔性碳链。 [4] nan [5] nan [6]
flexible carbon foam 柔性碳泡沫
In this study, we propose a carbon-coated SnS nanosheet on flexible carbon foam composite materials as anodes for Li- and Na-ion batteries. [1] The flexible carbon foam matrix intrinsic metamaterials whose double negative properties can be regulated by deformation are successfully synthesized. [2] Herein, vertical-aligned SnS2 nanosheet arrays (SnS2 NSA) with intrinsic lithiophilic nature, endowed by in situ formed Li13Sn5 via the alloying reaction of SnS2, are uniformly decorated on highly flexible carbon foam (SnS2 NSA@CF) to overcome the encountered issues of ordinary carbon skeletons. [3] A novel ultralight and flexible carbon foam (CF)-based phase change composite was fabricated by encapsulating n-eicosane into CF skeleton that had been pre-coated with titanium (III) oxide (Ti2O3) nanoparticles (NPs). [4]在这项研究中,我们提出了一种在柔性碳泡沫复合材料上涂有碳的 SnS 纳米片作为锂离子和钠离子电池的阳极。 [1] 成功合成了具有双负性能可通过变形调控的柔性碳泡沫基本征超材料。 [2] 在此,通过 SnS2 的合金化反应原位形成的 Li13Sn5 赋予具有固有亲锂性质的垂直排列的 SnS2 纳米片阵列 (SnS2 NSA),均匀地装饰在高柔性碳泡沫 (SnS2 NSA@CF) 上,以克服遇到的问题普通的碳骨架。 [3] nan [4]
flexible carbon textile
The unique 3D self-branched nanostructure anchored on flexible carbon textiles (CTs) can offer short ion diffusion length, fast and continuous electron transport pathway, and abundant reaction active sites. [1] Herein, we report a controlled growth of single crystal mesoporous zinc ferrite (ZnFe2O4) nanowall arrays on highly flexible carbon textile for flexible supercapacitors. [2] Herein, we design a novel binder-free anode via N-doped graphene quantum dot (N-GQD) decorated Na2Ti3O7 nanofibre arrays (Na2Ti3O7 NFAs) directly grown on flexible carbon textiles (CTs) for high-performance sodium-ion batteries (SIBs). [3]锚定在柔性碳纺织品(CTs)上的独特的3D自支化纳米结构可以提供较短的离子扩散长度、快速和连续的电子传输路径以及丰富的反应活性位点。 [1] 在这里,我们报告了单晶介孔铁酸锌 (ZnFe2O4) 纳米壁阵列在用于柔性超级电容器的高柔性碳织物上的受控生长。 [2] nan [3]
flexible carbon fabric 柔性碳纤维织物
The compatibility between flexible carbon fabric skeleton and brittle pure graphene matrix empowers this CFG film with adequate flexibility. [1] These solids comprise of carpet-like arrays of covalently bonded carbon nanotubes (CNT) on the surface of strong and flexible carbon fabric. [2] The eco-friendly chemical route was followed to synthesize RGO enfolded cobalt (II, III) oxide nanowires on flexible carbon fabric substrate (CONW-RGO), which disclosed prevailing electrochemical performances rather than cobalt (II, III) oxide nanowires on flexible carbon fabric (CONW). [3]柔性碳纤维骨架和脆性纯石墨烯基体之间的相容性使这种CFG薄膜具有足够的柔韧性。 [1] 这些固体由位于坚固而柔韧的碳纤维织物表面上的地毯状共价键碳纳米管 (CNT) 阵列组成。 [2] nan [3]
flexible carbon material 柔性碳材料
This study investigates active sites and reaction mechanisms for CO2 electroreduction over metal N-doped flexible carbon materials using Phthalocyanine (Pc) and Iron Phthalocyanine (FePc) molecules as model catalysts. [1] This indicates that the delignified wood-based flexible carbon material is an ideal basic flexible self-supporting electrode material, which has a good application potential in the field of flexible solid-state energy storage. [2] In this work, a flexible free-standing supercapacitor was designed, with in-situ grown hollow-structured NiCo layered double hydroxide (H–NiCo LDH) as the active material based on a partial Ni ion substitution of Co ion in ZIF-67, and flexible carbon material as the substrate. [3]本研究使用酞菁 (Pc) 和铁酞菁 (FePc) 分子作为模型催化剂,研究了金属 N 掺杂柔性碳材料上 CO2 电还原的活性位点和反应机制。 [1] 这表明脱木质素基柔性碳材料是一种理想的基础柔性自支撑电极材料,在柔性固态储能领域具有良好的应用潜力。 [2] nan [3]
flexible carbon coating
Owing to the cooperative effect of well-defined interior voids and conductive and flexible carbon coating, the hollow nanostructural SnO2/C composites exhibit significantly improved electrochemical performance over their pure nanostructured SnO2 counterparts, and hence attracts increasing research interests. [1] Secondly, the inherently adequate free space including void (between shells and yolks) and hollow cavity as well as flexible carbon coating can accommodate the volume variation of SnO2, and therefore boosts the structural stability of whole composite. [2]由于明确的内部空隙和导电和柔性碳涂层的协同作用,中空纳米结构的 SnO2/C 复合材料比纯纳米结构的 SnO2 复合材料表现出显着改善的电化学性能,因此吸引了越来越多的研究兴趣。 [1] nan [2]
flexible carbon capture
Here, we examine the synergistic integration of renewables and flexible carbon capture with individual fossil power plants. [1] The review paper provides an insight to the development and the technological needs of different energy system sectors, as well the limitations, challenges and research gaps to the integration of the variable renewable energy sources and flexible carbon capture and utilization technologies. [2]在这里,我们研究了可再生能源和灵活碳捕获与单个化石发电厂的协同整合。 [1] nan [2]
flexible carbon matrix
The developed complex allows us to implement a promising technology for creating a new generation of electrode materials based on a flexible carbon matrix with a highly developed surface. [1] Among the materials for preparing the FSs, the flexible carbon matrix composites (FCMCs) have become the widely used material since the good performance in the properties of electrochemistry and mechanics, which could be divided into three types: the carbon nanofibers (CNFs), the carbon nanospheres (CNSs) and the carbon nanotubes (CNTs). [2]开发的复合体使我们能够实施一项有前途的技术,以创建基于具有高度发达表面的柔性碳基质的新一代电极材料。 [1] nan [2]
flexible carbon membrane 柔性碳膜
The flexible carbon membranes can be directly used as self-standing electrodes for various batteries, that is, with no current collectors, organic binders, or additional conductive agents. [1] Due to this, a fast and feasible non-solvent induced phase separation method, combining with stabilization and carbonization, was provided to fabricate high performance flexible carbon membrane from polyacrylonitrile (PAN) with the presence of N,N-dimethylformamide (non-solvent). [2]柔性碳膜可直接用作各种电池的自立电极,即无需集电器、有机粘合剂或额外的导电剂。 [1] 鉴于此,提供了一种快速可行的非溶剂诱导相分离方法,结合稳定化和碳化,在 N,N-二甲基甲酰胺(非溶剂)的存在下从聚丙烯腈(PAN)制备高性能柔性碳膜。 . [2]
flexible carbon fibrou 柔性碳纤维
The targeted super-flexible carbon fibrous film possesses outstanding electrochemical performance with a specific capacitance of up to 331 F g−1 at a current density of 1 A g−1. [1] Self-supporting and flexible carbon fibrous mats are promising electrode materials for wearable devices. [2]目标超柔碳纤维膜具有出色的电化学性能,在 1 A g-1 的电流密度下比电容高达 331 F g-1。 [1] 自支撑和柔性碳纤维垫是可穿戴设备的有前途的电极材料。 [2]
flexible carbon electrode 柔性碳电极
The flexible sensors were fabricated on top of flexible carbon electrodes that were screen-printed on polyethylene terephthalate (PET) substrate. [1] In this work, converting cotton fabrics into high-performance flexible carbon electrodes are achieved successfully by using traditional dyeing, flame retardant finishing and carbonization processes for wearable supercapacitors. [2]柔性传感器是在柔性碳电极的顶部制造的,这些电极丝网印刷在聚对苯二甲酸乙二醇酯 (PET) 基板上。 [1] 在这项工作中,通过对可穿戴超级电容器采用传统的染色、阻燃整理和碳化工艺,成功地将棉织物转化为高性能柔性碳电极。 [2]