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]