Fe-Ni/C复合纳米纤维的原位制备与微波吸收性能

采用静电纺丝技术结合稳定化和碳化处理原位制备了Fe-Ni/C复合纳米纤维, 其平均直径约为215 nm, 所生成的Fe-Ni合金纳米颗粒较均匀地分布在碳基纳米纤维的内部和表面, 且被石墨化碳层所包覆. 以Fe-Ni/C复合纳米纤维为吸收剂、 硅橡胶为基质制备成吸波涂层, 研究了碳化温度对电磁特性和微波吸收性能的影响. 结果表明, 涂层厚度为1.2~2.0 mm、 Fe-Ni/C复合纳米纤维质量分数为5%的吸波涂层表现出优良的微波吸收性能, 在7.4~18 GHz频率范围内的反射损耗均低于-20 dB; 随着复合纳米纤维的碳化温度由800 ℃升高到1200 ℃, 由于阻抗匹配特性的改善, 吸波涂层的微波吸收能力逐步加强, 其最小反射损耗由-22.6 dB降低到-63.0 dB.     

煤基碳泡沫/聚氨酯相变复合材料的制备及储热性能

以煤基碳泡沫(CCF)作为骨架材料来封装改性固-固相变材料聚氨酯(PU),并实现其功能化应用。使用场发射扫描电子显微镜(SEM)、透射电子显微镜(TEM)、X射线粉末衍射仪(PXRD)、傅里叶变换红外(FT-IR)光谱仪、热重分析仪(TGA)、差示扫描量热(DSC)分析仪、热导测试仪对所得到的复合材料(PU@CCF)进行结构和特性表征。结果显示,聚乙二醇(PEG-6000)与异氰酸酯(HDI)反应制备聚氨酯的最优摩尔比例为1:2,煤基碳泡沫可以很好地阻止聚氨酯从复合材料中泄露出来。相较于聚乙二醇,复合材料的导热率上升了54%,经过200次热循环,复合材料保持了良好的稳定性,而且其相变主体材料PU的过冷度降低了10℃以上。基于碳泡沫骨架良好的导电性,加载高于0.8V的低电压就可实现聚氨酯电热相变储能,在1.1V电压驱动下,其电热转换效率可达75%。该工作是目前报道的最低电压下可实现电热相变转换的复合功能材料,为实现低成本相变复合材料的制备与功能化提供重要参考。     

PEG-沸石固-固相变材料的制备及性能

摘要：采用接枝共聚法合成了以聚乙二醇（PEG）为相变物质,沸石为骨架的PEG沸石固-固相变材料。通过红外光谱（FT—IR）、热失重分析（TGA）和差示扫描量热法（DSC）等测试手段对PEG-沸石固-固相变材料的结构、相变行为及热稳定性进行了研究。结果表明：通过改变PEG的分子量,可以得到不同相变焓和不同相变温度的PEG-沸石固-固相变材料,其相变焓可达105．41J／g,热稳定性良好,起始分解温度高于300℃。     

六羟基化合物为骨架的高分子固-固相变材料的合成与性能

分别使用三种含6个羟基的化合物(山梨醇、双季戊四醇和肌醇)作为分子骨架,聚乙二醇(PEG)作为相变功能链,4,4'-二苯基甲烷二异氰酸酯(MDI)为交联剂,合成了3种具有不同交联结构的新型固-固相变储能材料。通过傅里叶变换红外光谱(FT IR)、X-射线衍射(XRD)、偏光显微镜(POM)、示差扫描量热法(DSC)和热重量分析法(TG)分别对合成材料的分子结构、结晶性能、相变行为和热稳定性进行了研究。结果显示,所制备的材料在30~70℃温度范围内具有典型的固-固相变特性,其升温和冷却过程的相变焓最高可达107.5J/g和102.9J/g。此外,通过热重分析发现所合成材料具有较好的可重复使用性和热稳定性。因此,合成的新型固-固相变材料在热能储存和控温领域具有巨大的应用潜力。     

纤维素丙酸酯-g-二乙二醇正十六烷基醚固-固相变材料的制备及性能

以二月桂酸二丁基锡(DBTDL)为催化剂,微晶纤维素为骨架材料,二乙二醇正十六烷基醚(E2C16)为相变材料,采用化学接枝法制备了系列纤维素丙酸酯-g-二乙二醇正十六烷基醚(CP-g-E2C16)固-固相变材料.利用傅里叶变换红外光谱(FTIR)、核磁共振氢谱(1H NMR)、差示扫描量热仪(DSC)、热重分析(TG)和X射线衍射(XRD)对CP-g-E2C16相变材料的结构和热性能进行了表征.结果表明,得到了E2C16的取代度和接枝含量分别为0.12~0.37和17.1%~33.4%的CP-g-E2C16固-固相变材料.CP-g-E2C16接枝共聚物的相变温度和相变焓分别为25~34℃和40~62 J/g,符合人的体感舒适温度范围.CP-g-E2C16固-固相变材料的耐热温度高于237℃,与E2C16相比提高21~40℃,有望应用于熔融纺丝法制备纤维素基储热调温纤维领域.     

KBF4非等温固-固相变热性质的测定

利用DTA-TG和DSC热分析技术研究了无机塑晶材料KBF4固-固相变的热性能,测得转变温度为284.13℃,转变焓为105.73J/g.KBF4固-固相变的机理是随着温度的升高,晶体中离子键部分断裂,晶体逐渐由低对称的正交晶系向高对称立方晶系转变,并在这过程中,同时引入化学键的振动和转动无序,从而吸收大量的相变焓.     

LSMO/SiO2复合材料变温微波吸收特性研究

通过固相反应法制备了LSMO/SiO2复合材料, 测试了LSMO材料500 MHz～18 GHz介电特性和LSMO/SiO2复合材料样品不同温度下X波段介电常数和微波吸收特性. 测试结果表明, 在12 GHz附近复合材料样品有明显的介电损耗特征峰, 随着温度的升高材料的介电常数虚部明显升高, tgδ变大;吸收特性测试表明, 随着温度升高, 吸收峰升高, 吸收峰略微往低频移动.     

石蜡/膨胀石墨/石墨烯复合相变储热材料的制备及性能

以石蜡(PA)作为相变储热材料、 膨胀石墨(EG)作为主导热材料和支撑材料, 石墨烯气凝胶(GA)作为导热增强材料和辅支撑材料制备了PA/EG/GA复合相变材料, 研究了GA添加量对复合相变材料相变温度、 相变潜热、 导热性能以及循环稳定性的影响. 结果表明, 所制备的80%PA-17%EG-3%GA复合相变材料导热性能良好, 循环稳定性出色. 与80%PA-20%EG复合材料相比, 该材料的相变温度、 相变潜热以及循环稳定性无明显变化, 但导热系数由4.089 W/(m·K)提升到了5.336 W/(m·K), 显示出良好的应用前景.     

石蜡/碱改性硅藻土/膨胀石墨复合相变储热材料的制备及性能

通过碱处理,优化了硅藻土(DIA)的孔隙结构,提高了孔隙率,增加了石蜡(paraffin)负载量。通过直接浸渍法制备了新型性状稳定的石蜡/碱改性DIA/膨胀石墨(EG-alDIAP)复合材料,并研究了其结构与性能的关系。结果表明,复合相变材料的石蜡负载量从47.4%提高到了61.1%,进而提高了复合材料的储热性能;向改性DIA中添加膨胀石墨(EG)提高了复合材料的传热能力,添加质量分数10%EG时导热系数提高了113%(从0.276 W·m^-1·K^-1提高到了0.589 W·m^-1·K^-1)。随着EG含量的升高,复合相变材料的相变潜热有所增加,但化学相容性、稳定性等无明显变化。含 10%EG的石蜡/碱改性 DIA复合材料具有可靠的储能性能、良好的温度调节性能和蓄放热能力。     

La0.6Ce0.4Mn1-yFeyO3微波吸收特性

用溶胶-凝胶法制备了La0.6Ce0.4Mn1-yFeyO3 (y=0.00, 0.12, 0.14, 0.16, 0.18)样品. 用微波矢量网络分析仪测试了该样品在2～18 GHz微波频率范围的复介电常数、复磁导率, 根据测量数据计算了电磁损耗角正切及微波反射率与频率的关系. 结果表明, 当B位掺入铁元素时, 样品吸收峰值增大, 有效吸收频带增宽, 在y=0.14时, 样品微波吸收效果最好. 当样品厚度为2.00 mm, y=0.14时, 吸收峰值为38 dB, 10 dB以上频带宽度达4.1 GHz. 初步探讨了该材料的电磁损耗机理, 发现损耗吸收来自磁损耗和介电损耗的共同作用, 吸收峰所在频率介于介电损耗角正切最大值与磁损耗角正切最大值对应的频率之间, 即在12.7 GHz附近. 对样品的电阻率测试表明, 其室温范围内电导在半导体范围内, 有利于降低微波在样品表面的反射率.     

ZnO纳米颗粒锚定的亚微米碳纤维的制备及其吸波性能

使用静电纺丝技术结合水热法制备了表面锚定ZnO纳米颗粒的亚微米碳纤维（ZnO/SDCFs）复合物,并详细研究了反应溶液的pH值对复合物的结构、组成、电磁特性和吸波性能的影响。结果显示,随着pH值的升高,ZnO的含量增加,介电常数、介电损耗以及电磁衰减能力均下降,但阻抗匹配程度提高。相比于纯碳纤维,所有ZnO/SDCFs复合物的吸波性能均得到不同程度的加强。其中,pH值等于8时所制备的ZnO/SDCFs-8复合物拥有最好的吸波性能,主要归因于电磁衰减能力和阻抗匹配间的更好平衡。当ZnO/SDCFs-8的填充量仅为2.5%（质量分数）、厚度为1.7 mm时,相应吸波涂层的最小反射损耗达到-44.1 dB,低于-10 dB的有效吸收带宽为6.1 GHz,频率范围为11.9~18 GHz;当厚度为3.0 mm时,有效吸收带宽可提高到11.8 GHz（6.2~18 GHz）。     

Co(OH)_2/NaY复合材料的制备及其超级电容性能

应用化学共沉淀法制备Co(OH)2/NaY复合材料,并以其组成超级电容器.测试结果表明,该材料具有良好的超级电容性能,Co(OH)2的最高比电容达632.5 F.g-1.     

基于核壳结构Co3Fe7@C的高效微波吸收材料

To reduce the density of the absorbent Co₃Fe₇, a core-shell Co₃Fe₇@C microwave absorbent was synthesized by preparing an iron/cobalt-containing carbon precursor followed by high-temperature carbonization. According to the X-ray diffraction (XRD) and transmission electron microscopy (TEM) results, Co₃Fe₇ particles were coated with graphitized carbon layers to form a core-shell structure. Furthermore, the Co₃Fe₇@C composite with a surface area and density of 358.5 m²·g^-1 and 2.25 g·cm^-3, respectively, exhibited excellent microwave absorbability. A minimum reflection loss (RL) of -43.5 dB and an effective bandwidth (RL below -10 dB) of 4.1 GHz were obtained at the coating thickness of 2 mm, which could be mainly attributed to the effective impedance match and multiple interfacial polarizations. Owing to the low density and remarkable microwave absorption, we believe that the Co₃Fe₇@C composite can be a promising candidate for use as a lightweight and efficient microwave absorbent.     

活性炭/有机质复合相变材料的热-电性能

用活性炭(AC)作为支撑材料,石蜡(PW)、十六酸(PA)和硬脂酸(SA)作为相变主材,通过熔融共混法制备AC/PW、AC/PA和AC/SA复合相变材料,并考察了其热-电性能。结果表明,添加活性炭时有机质均不会泄漏;复合材料充-放热过程中温度场分布都比较均匀,热循环会使材料导热性能略有下降;此外,三种复合材料的电阻率均随压力增加而减小。     

Achieving full effective microwave absorption in X band by double-layered design of glass fiber epoxy composites containing MWCNTs and Fe3O4 NPs

The glass fiber epoxy composites containing MWCNTs and Fe₃O₄ NPs were manufactured by composites liquid molding process. The microwave absorbing properties of single-layered and double-layered glass fiber/MWCNTs/epoxy and glass fiber/Fe₃O₄ NPs/epoxy composites were evaluated. The reflection loss(RL) were calculated by the measured complex permittivity and permeability using waveguide method by vector network analyzer. Based on the mechanism analysis and deficiency of single-layer absorber, the double-layered composites were fabricated by using matching layer and absorbing layer to enhance the microwave absorption performance, which can be modulated by tailoring the electromagnetic parameters and thicknesses of each layer. The optimized microwave absorbing properties of double-layered composites with minimum RL of −45.7 dB and full X-band effective absorption can be achieved when the total thickness of the matching layer and absorbing layer is 1.8 mm, which can be attributed to synergistic effect of improved impedance matching characteristic and superior microwave attenuation characteristic of the absorbing layer. The combined utilization of dielectric loss and magnetic loss absorbent and their double-layered structure design shows great design flexibility and diversity and can be a promising candidate for designing high performance microwave absorbing materials.     

One-step synthesis of CuS-decorated MWCNTs/paraffin composite phase change materials and their light–heat conversion performance

Paraffin wax (PW) is a solid–liquid organic phase change material (PCM). However, the low thermal conductivity and poor light–heat conversion performance limit its feasibility in solar thermal storage applications. In this paper, CuS-decorated carboxyl multi-wall carbon nanotubes (MWCNTs)/PW light–heat conversion composite PCMs were prepared by one step. The structure and properties of the composite PCMs were studied by X-ray diffraction, scanning electron microscopy, transmission electron microscopy, differential scanning calorimeter, thermogravimetric analysis, coefficient of thermal conductivity, UV–visible–near infrared spectrometer and light–heat conversion testing. The results showed that the light–heat conversion performance of CuS–MWCNTs/PW composite PCMs were better than that of MWCNT/PW composite PCMs with the same mass fraction. Therefore, it is expected that this research will open up new avenues of study for the creation of advanced composite PCM with excellent light–heat conversion performance.     

Metal-Organic Framework Derived Hierarchical Co/C@V2O3 Hollow Spheres as a Thin,Lightweight, and High-Efficiency Electromagnetic Wave Absorber

Developing high-efficiency electromagnetic (EM) wave absorbing materials with light weight, thin thickness, and wide absorption bandwidth is highly desirable for ever-developing electronic and telecommunication devices. Herein, hierarchical metal–organic framework (MOF)-derived Co/C@V₂O₃ hollow spheres were designed and synthesized through a facile hydrothermal, precipitation, and pyrolysis method. The composite exhibits both excellent impedance matching and light weight due to the rational combination of hollow V₂O₃ spheres and porous Co/C. Additionally, multiple components enable a large dielectric and magnetic loss of the composite, giving rise to enhanced EM wave absorption performance with a maximum reflection loss (RL) of −40.1 dB and a broad effective absorption bandwidth (RL < −10 dB) of 4.64 GHz at a small thickness of 1.5 mm. This work provides insights into the design of hierarchical hollow and porous composites as thin and lightweight EM wave absorbers with efficient absorption, which can also be extended to energy storage, catalysis, and sensing.     

Co-WC复合电极在碱性介质中的电催化析氢性能

Co-WC复合电极在碱性介质中的电催化析氢性能     

Formation of Nanostructured MnO/Co/Solid–Electrolyte Interphase Ternary Composites as a Durable Anode Material for Lithium‐Ion Batteries

Nanoporous MnO frameworks with highly dispersed Co nanoparticles were produced from MnCO₃ precursors prepared in a gel matrix. The MnO frameworks that contain 20 mol % Co exhibited excellent cycle performance as an anode material for Li‐ion batteries. The solid–electrolyte interphase (SEI) formed in the frameworks through the electrochemical reaction mediates the active materials, such as MnO, Mn, and Li₂O, during the conversion reaction in the charge–discharge cycle. The Co nanoparticles and SEI provide the electron and Li‐ion conductive networks, respectively. The ternary nanocomposites of the MnO framework, metallic Co nanoparticles, and embedded SEI are categorized as durable anode materials for Li‐ion batteries.     

多孔羰基铁/SiO2/聚吡咯核壳结构复合材料的制备及电磁特性

首先对羰基铁进行点腐蚀得到多孔羰基铁,然后采用St?ber法和原位聚合法将SiO_2和导电高分子聚吡咯包覆在多孔羰基铁表面,制备多孔羰基铁/SiO_2/聚吡咯电磁复合吸波材料。采用XRD、SEM、TEM、FT-IR对样品结构、微观形貌进行了表征,在网络分析仪中采用同轴法测试样品电磁参数,并根据传输线理论研究了2~18 GHz微波频段内吡咯含量及涂层厚度对样品吸波性能的影响。实验结果表明:制备的多孔羰基铁/SiO_2/聚吡咯复合电磁吸波材料具有核壳结构;随着吡咯加入量的增加,吸波材料吸收峰逐渐向低频方向移动;当涂层厚度为3.5 mm、吡咯加入量为6%(w/w)时,在9.44~17.56 GHz范围内反射率均低于-10 d B,频带宽度为8.12 GHz,损耗反射率达到-23 d B。良好的吸波性能归因于复合物有效的阻抗匹配特性及多重界面极化效应,多孔羰基铁/SiO_2/聚吡咯是一种轻质、宽频、强吸收的吸波材料。