镍锌铁氧体/膨胀石墨/聚苯胺复合物的电磁损耗性能

用化学共沉淀法和原位乳液聚合法分别制备了镍锌铁氧体(NixZn1-xFe2O4)、Ni0.7Zn0.3Fe2O4/膨胀石墨(NZF/EG)二元复合物及其聚苯胺(PANI)包覆的三元复合物(NZF/EG/PANI)。用现代测试技术表征了样品的组成、结构、形貌和电磁性能。结果表明,NZF粒子较好地嵌入到EG的层间,PANI对NZF/EG的包覆效果良好;三元复合物的磁性能随磁性组分含量的减小而减弱,而电导率与EG和PANI的导电性及其相对含量相关联;复合物的电磁损耗性能优良,其中三元复合物优于二元复合物。含PANI70wt%的NZF/EG/PANI三元复合物,制样厚度分别为1.5、2.0和2.5 mm时,其反射损耗峰值(有效带宽)分别为-19.99 d B(5.82GHz),-20.33 d B(4.08 GHz)和-25.28 d B(3.67 GHz),具有优良的电磁波吸收效果。     

CoFe2O4及其膨胀石墨复合物的制备与电磁性能

通过超声-共沉淀技术合成了CoFe₂O₄(CF)及CoFe₂O₄/膨胀石墨复合物(CF/EG), 并表征了样品的微观结构、形貌、热稳定性和电磁性能.结果表明, CF的磁性能受沉淀剂类型和烧结温度等因素的影响, CF/EG复合物具有良好的导电性、磁性和电磁波吸收性能.EG与CF质量比为0.8的CF/EG复合物和石蜡制成的2.0 mm涂层(质量比1:2)在13.52 GHz处的最小反射损耗为-16.08 dB, 有效带宽达6.6 GHz, 在10~18 GHz频段表现出良好的电磁波吸收性能.复合物的吸波性能主要来自于膨胀石墨的电导损耗和介电损耗、钴铁氧体的磁损耗、组分间的界面弛豫作用及协同效应.     

镍锌铁氧体/膨胀石墨/聚苯胺复合物的电磁损耗性能

用化学共沉淀法和原位乳液聚合法分别制备了镍锌铁氧体(Ni_xZn_1-xFe₂O₄)、Ni_0.7Zn_0.3Fe₂O₄/膨胀石墨(NZF/EG)二元复合物及其聚苯胺(PANI)包覆的三元复合物(NZF/EG/PANI)。用现代测试技术表征了样品的组成、结构、形貌和电磁性能。结果表明,NZF粒子较好地嵌入到EG的层间,PANI对NZF/EG的包覆效果良好;三元复合物的磁性能随磁性组分含量的减小而减弱,而电导率与EG和PANI的导电性及其相对含量相关联;复合物的电磁损耗性能优良,其中三元复合物优于二元复合物。含PANI 70wt%的NZF/EG/PANI三元复合物,制样厚度分别为1.5、2.0和2.5 mm时,其反射损耗峰值(有效带宽)分别为-19.99 dB(5.82 GHz),-20.33 dB (4.08 GHz)和-25.28 dB(3.67 GHz),具有优良的电磁波吸收效果。     

钴铁氧体/膨胀石墨及其聚吡咯复合物的制备和油水分离性能

用化学共沉淀法和原位乳液聚合法分别制备了钴铁氧体/膨胀石墨复合微粒(CF/EG)和钴铁氧体/膨胀石墨/聚吡咯复合物(CF/EG/PPy)。用现代分析技术表征了样品的组成、结构、形貌、电-磁性能和油水分离性能。结果表明,CF粒子已填嵌入到膨胀石墨的层间,CF/EG/PPy复合物的核(CF/EG)和壳(PPy)之间存在着一定的相互作用,样品的油水分离效果与膨胀石墨的层间空隙成正比,其次序为:EG>CF/EG>CF/EG/PPy。磁性的CF/EG微粒回收容易,重复使用性能优良,循环5次的效率不低于90%。     

聚丙烯/石墨导电纳米复合材料的制备与性能

用溶液插层及其与熔体混合相结合的母料熔体混合 (MMM)方法制备了聚丙烯 (PP) 马来酸酐接枝聚丙烯 (gPP) 膨胀石墨 (EG) (gPP EG =3 2wt)导电纳米复合材料 ,其室温逾渗阀值 (c)分别为 6wt%和 8wt % ,明显低于直接熔体混合制得复合材料和PP EG对照材料的c=11wt%和 12wt% .增加gPP含量 (Cg)能提高复合材料的电导率 (σ) ,例如对于MMM法制备的复合材料 ,固定PP gPP =1 1wt时 ,c 降为 7wt% ;保持EG含量 =9wt%时 ,σ在Cg>30wt %后跃升 7个数量级以上 .通过TEM、SEM和OM观察 ,从制备方法、EG和gPP含量影响复合材料形态和微结构的角度 ,分析说明了出现上述差异和现象的原因 .     

聚苯胺/蒙脱土纳米复合材料的制备及吸波性能研究

以十二烷基苯磺酸(DBSA)作为乳化剂和掺杂剂,通过乳液聚合的方法制备了DBSA掺杂聚苯胺/蒙脱土(PANI-DBSA/MMT)纳米复合物,并对其微波吸收特性进行了研究.通过X射线衍射(XRD)、傅立叶红外(FT-IR)和四探针测试仪对复合物进行了初步表征.结果表明,PANI-DBSA/MMT复合物中MMT层间距离明显扩大,纳米复合物中的PANI以emeraldine盐的形式存在,是一种典型的插层型纳米复合物.利用HP8722ES矢量网络分析仪测量了2 mm厚、PANI-DBSA/MMT含量为50 wt%的试样在2.0~18 GHz的复介电常数和复磁导率,经计算得到以反射损耗表示的微波吸收曲线,发现PANI-DBSA/MMT纳米复合物在9.1~12.5 GHz范围内反射损耗小于-10 dB,在11 GHz处存在的最大反射损耗为-15.8 dB.     

ZnTi_(0.6)Fe_(1.4)O_4/膨胀石墨复合物对污染物的吸附-光催化降解活性

用化学共沉淀法制备了Zn Ti0.6Fe1.4O4/膨胀石墨(ZT0.6F1.4/EG)复合物.通过现代分析技术表征了样品的组成、微观结构、磁性能、吸附性能和光催化活性.结果表明,ZT0.6F1.4/EG不仅保持了膨胀石墨原有的特殊结构和吸附性能,并且具有良好的ZT0.6F1.4负载率、磁性能和光催化活性;样品对罗丹明B(Rh B)的去除率取决于EG的吸附作用和ZT0.6F1.4的光催化降解作用;ZT0.6F1.4和EG质量比(mZTF/mEG)为1:1的ZT0.6F1.4/EG复合物对Rh B的最大吸附量(qm)为5.102mg g?1,且吸附行为与Langmuir等温吸附模型相一致.ZT0.6F1.4/EG对工业染料废水、柴油/水混合溶液也具有良好的去污效果.此外,ZT0.6F1.4/EG回收方便、活化处理简便、循环使用性能良好.     

锌铁氧体/膨胀石墨复合物的制备及对腐殖酸的去污性能

用共沉淀法将强吸附性的膨胀石墨与光催化活性优良的锌铁氧体磁粉复合,制备出锌铁氧体/膨胀石墨复合物(ZF/EG)。用现代分析测试技术表征了样品的组成、微观结构,并研究了去污性能。结果表明,实验制备的碳磁复合物不仅保持了EG原有的特殊结构和优良吸附性能,且具有可观的ZF负载率和光催化活性;腐殖酸的去除率与样品中EG和ZF的质量比(mZF/mEG)、吸附时间和溶液的p H值等因素有关。紫外光照射90 min后,0.1 g mEG/mZF=1的ZF/EG复合物对腐殖酸(溶液浓度为15 mg·L~(-1),体积100 m L,p H=7)的去除率达95%,该复合物4次重复使用后,对腐殖酸的去除率仅下降了4%,是一类具有潜在应用前景的绿色环保的高效废水处理剂。     

膨胀石墨/聚苯胺/Fe_3O_4复合材料的制备及吸波性能

采用原位聚合方法制备了膨胀石墨/聚苯胺(EG/PANI)复合材料,将Fe_3O_4负载于EG/PANI表面,得到具有电磁吸收性能的EG/PANI/Fe_3O_4复合材料.通过扫描电子显微镜(SEM)、X射线衍射仪(XRD)、傅里叶变换红外光谱仪(FTIR)及矢量网络分析仪(VNA)等对复合材料的形貌、成分和吸波性能进行了研究.吸波性能分析结果表明,当掺杂浓度为0.05 mol/L,匹配厚度d=2 mm时,样品的最小反射损耗(RLmin)在8.64 GHz处达到-37 dB.随着掺杂浓度的增加,最小反射损耗峰向低频移动,对应的匹配厚度逐渐变厚.材料的介电弛豫极化、涡流损耗及λ/4模型的干涉相消现象出现的双峰,使EG/PANI/Fe_3O_4复合材料在电磁波吸收领域有一定的应用前景.     

改性可膨胀石墨的制备及在硬质聚氨酯泡沫中的阻燃性能

采用表面接枝硅烷偶联剂法将硼酸负载在可膨胀石墨(EG)表面制得了改性EG(MEG), 并考察了MEG在硬质聚氨酯泡沫(RPUF)中的阻燃性能. 利用扫描电子显微镜、 X射线光电子能谱、 傅里叶变换红外光谱、 膨胀试验及热失重分析对MEG进行了形貌、 元素组成及结构性能表征, 通过热失重分析、 极限氧指数(LOI)及锥形量热仪考察了RPUF/MEG的热稳定性及燃烧性能. 结果表明, 硼硅化合物作为硅硼陶瓷前驱体已负载在EG表面; MEG及RPUF/MEG体系膨胀炭层更为致密, 800 ℃时的残余量分别较EG和RPUF/EG提高了8.7%和3.7%; RPUF/MEG体系的LOI较RPUF/EG有所提高, 热释放速率峰值降低了10%, 产烟速率及CO生成速率均显著降低. RPUF/MEG阻燃性能的提高与MEG负载的硅硼陶瓷前驱体促进了阻燃RPUF各组分间的相互作用及增强了炭层的阻隔性有关.     

电解氧化法膨胀石墨形成机理研究

采用现代测试方法对电解氧化法制备的膨胀石墨各阶段产物进行了表征 ,对其形成机理作了一些探讨。结果证实 ,在氧化过程中 ,层间表面的石墨被氧化后 ,与嵌入层间的H2 SO4、H2 O等生成层间化合物 ,该化合物瞬间受高热而分解 ,产生的推力使石墨沿C轴方向膨胀 ,而层平面碳 -碳结构未被破坏。     

酞菁钴/纳米铁复合颗粒的结构与微波电磁特性

一些铁磁性金属及其合金超细粉末,具有比饱和磁化强度高、易于合成与粒径可控等优点,因此被广泛应用于磁流体、电磁流变液、微波吸收材料等领域,但由抗氧化性差、密度较大等主要缺点而使其应用受到限制,采用有机／无机复合技术可制备具有有机包覆层的有机／无机复合颗粒,不仅可以增强铁磁性颗粒的抗氧化性,减小了密度,而且可以提高与有机基体的亲和性,为该类材料向更高层次发展提供了可能。     

Estimate of polarization components in oxygen reduction process on expanded natural graphites and acetylene carbon black in acid and alkaline electrolytes

The polarization curves of oxygen reduction in gas diffusion electrodes of expanded natural graphites (ENG, prepared from graphite intercalation compounds synthesized by intercalation of sulfuric and nitric acids into natural graphites GAK-3 and GT-1) and acetylene carbon black in acid (pH 0.6) and alkaline (3 M KOH) electrolytes were analyzed. The transfer coefficients and oxygen reduction exchange currents on ENG and acetylene carbon black were estimated. The experimental polarization curves were described well with the derived semi-empirical equations.     

Facile preparation of graphite intercalation compounds in alkali solution

Graphite intercalation compounds are often prepared by flake graphite, oxidants, inorganic acids, organic acids and intercalated ions which are usually hydrogen protons between the graphene planes. They are also known as the acid-treated graphite intercalation compounds. In this work, alkaline graphite intercalation compounds were prepared by flake graphite, K₂Cr₂O₇, concentrated H₂SO₄ and NaOH, and the morphology and structure were characterized by Electron microscopy and X-ray techniques. The results display that the combination of neutralisation heat and oxidation capability produced by K₂Cr₂O₇ can break the bonds to produce the spaces between the graphene planes and hydroxyl ions also intercalate into the graphene planes to form alkaline graphite intercalation compounds in alkali solution. The morphology and structure of alkaline graphite intercalation compounds are analogous to the ones of the acid-treated graphite intercalation compounds, but the intercalated ions and the expansion volume are different. The results show that the method is an innovation.     

Theoretical model and experimental study of pore growth during thermal expansion of graphite intercalation compounds

Summary A new technique, which allows one to simultaneously follow the mass and volume of graphite intercalation compounds (GICs) during thermal transformation into expanded graphite, was developed. This enabled us to elucidate the mechanism for the thermal expansion of GICs and formulate a quantitative model for the process. Effective activation parameters of the thermal decomposition of new GICs were obtained by using non-isothermal kinetics procedure. Thermal decomposition was described as a break of intermolecular bonds followed by diffusion.     

中空结构聚苯胺/Fe_3O_4/炭黑复合材料的制备及吸波性能

采用界面聚合和Pickering乳液聚合相结合的方法制备了具有微米尺寸的中空聚苯胺/Fe_3O_4/炭黑微球复合材料,研究了其形貌、电磁性能和吸波性能.结果表明,中空聚苯胺/Fe_3O_4/炭黑微球的平均粒径约为2.0μm;在2~4 GHz范围内的磁损耗主要是自然共振和交换共振,而在4~18 GHz范围内的磁损耗主要是涡流损耗;在2~18 GHz范围内,随着涂层厚度增加,反射损耗峰向低频方向移动,当涂层厚度增大到5.0mm时,反射损耗曲线出现2个反射损耗峰,分别位于C波段(4~8 GHz)和Ku波段(12~18 GHz),说明中空聚苯胺/Fe_3O_4/炭黑微球复合材料可作为特定频段的吸波材料.     

石墨与聚苯乙烯的纳米复合过程研究

石墨具有电导率高、化学稳定性好等优点 ,被广泛应用于聚合物 石墨复合导电材料[1～ 3] .石墨作为聚合物导电填料一般以粉末形态居多 .用粉末状石墨填料往往需要较高的填充量才能得到理想的导电性能 .石墨也可以制备成膨胀石墨 ,将它与聚合物复合 ,可以大幅度降低石墨的填充量 .如一般粉末状石墨填料与聚合物复合制备的导电材料其逾渗阀值为 1 5 %～ 2 0 % ,电导率达到 1 0 -4 ～1 0 -7Ｓ ｃｍ[4 ] ;而若采用膨胀石墨方法 ,逾渗阀值则低于 3% ,电导率可达到 1 0 -2 Ｓ ｃｍ以上[5～ 7] .Ｐａｎ等[7] 报道用膨胀石墨与聚合物复合得到纳米复合…     

Stabilization of Graphite Nitrate by Intercalation of Organic Compounds

New thermally stable intercalation compounds of graphite were obtained by the further intercalation of a series of organic compounds into graphite nitrate. The stabilization is explained by the formation of hydrogen bonds between the protonated form of the modifying substance and neutral surrounding molecules.     

Acylation d'aromatiques sous irradiation micro-onde en présence de graphite

Acylation of aromatics under microwaves in the presence of graphite. Under microwave irradiation, acylations of aromatic compounds could be achieved in the presence of graphite powder, used either to support the reagents (dry medium), or in small amount (solid-liquid medium). The process takes advantage both of the interaction of the graphite with the electromagnetic field and with the organic compounds. Acylations were achieved in an open reactor and at temperatures notably higher than the boiling point of the reagents. A catalytic effect of metallic inclusions present on the graphite surface, in particular iron ones (magnetite), has been established.     

Structure Characterization of CuCl2-FeCl3-H2SO4 Graphite Intercalation Compounds

"Graphite intercalation compounds with CuCl2-FeCl3-H2SO4 were synthesized via a hydrothermal treatment at 150 oC and exfoliation method. The structure and composition of these graphite intercalation compounds were analyzed by means of X-ray diffraction, energy dispersive X-ray and high-resolution transmission electron microscopy. The results demonstrate that the CuCl2-FeCl3-H2SO4 molecules were successfully intercalated into the interlayer of the graphite sheets. The temperature dependence of magnetization was measured from 5 K to 300 K. Two antiferromagnetic transitions of the graphite intercalation compounds were observed at low temperatures. The critical transition temperatures are estimated to be about 50 and 102 K. The related magnetic properties are discussed briefly."