新型锂离子电池三维结构泡沫NiO电极的制备及电化学性能

通过固相氧化方法,以三维结构泡沫镍为基体和金属镍源,制备了三维结构泡沫氧化镍负极。XRD和SEM结果表明,经500℃氧化处理,泡沫镍基体上形成了NiO微米级的致密活性氧化层。通过充放电测试和循环伏安测试研究了电极的电化学性能,结果表明,三维结构泡沫氧化镍在放电电位区间0.05～3.2VvsLi/Li+,0.2C倍率下充放电,初始容量损失为20%,且经40次循环后,质量比容量为950mAh·g-1,三维泡沫氧化镍电极具有优异的循环容量保持性能。三维泡沫氧化镍具有的大的活性表面积,降低了界面反应的极化,从而提高了NiO电极的倍率放电性能。     

锂离子电池正极材料LiNi0.5Co0.2Mn0.3O2的合成及其高温容量衰减研究

采用共沉淀-高温固相烧结法合成了富镍型三元复合正极材料LiNi0.5Co0.2Mn0.3O2.恒流充放电测试表明,材料在3.0～4.4 V下0.2C放电容量达到179.2 mAh.g-1,但在55℃下经历100次充放电循环后发生急剧的容量衰减.电化学交流阻抗谱、X射线光电子能谱和原子发射光谱等实验表明,在高温高电压下,电解液与LiNi0.5Co0.2Mn0.3O2电极材料之间的副反应加剧,导致过渡金属原子溶出,该材料局域结构被破坏.同时,电极材料表面还沉积了高阻抗的LiF/MFx层,使得在电极的充放电过程中电荷转移阻抗和Li+扩散阻抗不断增加,以致电池容量急剧衰减.     

溶剂热法合成不同形貌的Co3O4及其电容特性

采用溶剂热法以不同的钴盐在水-正丁醇体系中合成了不同形貌及尺寸的纳米Co3O4. 采用XRD和TEM对产物的物相和形貌进行表征. 结果表明, 通过改变反应体系中阴离子的种类, 可以控制产物Co3O4的形貌与晶粒尺寸. 通过循环伏安法、恒流充放电和交流阻抗法对Co3O4电极材料的电化学性能进行表征. 结果表明, Co3O4的形貌与晶粒尺寸对其电化学性能有显著影响. 在2 mol·L-1 KOH溶液中, 在-0.40 - 0.55 V (vs SCE)电位范围内, 由Co(NO3)2制备的球形Co3O4表现出更好的电容特性,单电极初始比容量达362.0 F·g-1, 经过400 次循环后比容量仍保持90%.     

纳米钴基氧化物锂离子电池负极材料的研究

采用流变相法合成Co3 O4 ,CoB1.3 6 O2 .8,CoB0 .5Al0 .1O1.5样品 ,并研究其作为锂离子电池负极材料的电化学性能 .当电池在 0 .0 1～ 3.0 0V的电压范围之间循环时 ,Li/Co3 O4 电池表现出最好的充放电性能 :循环 30周后 ,可逆比容量仍能保持为初始比容量 (931mAh/g)的 95 % .掺杂了B ,Al材料 ,其可逆比容量与未掺杂的相比明显降低 ,而且第 1周可逆容量随掺杂的B、Al量的增加而减少 .通过异位XRD方法研究了不同充放电态Co3 O4 电极材料结构的变化 .结果表明 ,Co3 O4 电极在充放电过程中与Li的反应机理不同于传统的过渡金属与Li的反应机理 ,即非Li+ 的嵌入 /脱出或合金的形成 ,而是Co3 O4 的可逆还原氧化以及Li2 O的可逆形成与分解机理     

还原氧化石墨烯/碳纳米管/Co_3O_4三元复合材料的制备与电化学性能

将低温水热反应和低温热处理相结合,制备了含还原氧化石墨烯(RGO)、碳纳米管(CNTs)和Co3O4的三元纳米复合材料RGO-CNTs-Co3O4;利用X射线衍射仪、扫描电子显微镜、透射电子显微镜分析了合成产物的相组成和微观结构,分析了其形成过程;并利用电化学测试装置测定了其作为锂离子电池负极材料的电化学性能.结果表明,在合成反应过程中,氧化石墨烯被还原剂肼还原为石墨烯,同时在石墨烯和CNTs表面生成氢氧化钴;再经低温热处理得到RGO-CNTs-Co3O4三元复合材料.Co3O4纳米颗粒均匀分散在由RGO片层和CNTs组成的三维网络结构中;这种三维网络结构既有利于电子和离子的传输,又能够有效抑制Co3O4在脱嵌锂过程中因体积变化引起的结构破坏.总体而言,合成的新型三元复合材料具有高的比容量以及良好的循环性能与倍率性能.     

锂离子电池负极复合材料Al-Co_3O_4的合成及其电化学性能(英文)

采用流变相反应与热处理相结合的方法合成了锂离子电池用Al-Co3O4负极复合材料;利用充放电循环试验测定了复合材料的电化学性能;利用X射线衍射仪、扫描电镜及粒度分布仪分析了复合材料的微结构,考察了Co3O4含量、热处理温度及循环电压范围对复合材料电化学性能的影响;同时探讨了Co3O4纳米微粒在复合材料充放电过程中的作用机理.结果表明,在Al-Co3O4复合材料中,铝基体表面被Co3O4纳米颗粒所包覆;不同组成的复合材料电极的充放电循环性能均优于纯铝电极.     

掺铝、钴纳米α-Ni(OH)2的固相合成及电化学性能研究

固相法合成了不同铝、钴配比的纳米α-Ni0.8Co2Al0.2-z(OH)2.2-x-0.5yCO3)y·xH2O.采用XRD、FTIR、SEM、CT和恒电流充放电等对其组成、晶相结构和电化学性能进行表征和测定.实验表明,掺Co的物质的量分数在5%～8%时有较高的放电比容量、较好的循环稳定性和电极可逆性,发挥了Co3+强导电性、稳定α相结构的多重作用.为α-Ni(OH)2的应用提供有益的参考.     

泡沫镍载Co（OH）2纳米线的电化学电容性能

以无模板法制备了泡沫镍载Co(OH)2纳米线电极,利用扫描电镜(SEM)和透射电镜(TEM)观测了纳米线的表面形貌,利用X射线衍射(XRD)分析了Co(OH)2纳米线的结构,通过循环伏安、恒流充放电和交流阻抗测试了电极的电化学电容性能.结果表明:Co(OH)2呈线状生长,其直径约为300nm,长度约为8～10μm,密集地生长在泡沫镍骨架上.电流密度为10mA·cm-2时电极的放电比容量高达677F·g-1,循环500次后比容量仍保持在574F·g-1,电化学阻抗测试其电荷传递电阻仅为0.23Ω,500次循环后电荷传递电阻仅增加0.03Ω.     

碱性Al-H_2O_2半燃料电池Au/Ni阴极性能研究

以泡沫镍为基体,AuCl3为沉积液,应用快速自沉积法制备了泡沫镍负载的纳米Au/Ni电极.电化学方法测定AuCl3溶液的浓度和沉积时间对Au粒子的尺寸和分布以及以该电极作为Al-H2O2半燃料电池阴极对H2O2性能的影响.实验表明,泡沫镍经2mmol·L-1AuCl3溶液浸渍60s后,其表面完全被粒径小于100nm的Au粒子覆盖;以其为阴极的Al-H2O2半燃料电池,在0.4mol·L-1H2O2溶液中峰值功率达135mW·cm-2.     

Co3O4纳米颗粒的制备及其电化学性能

采用化学共沉淀方法制备前驱体Co(Ⅱ)1-xCo(Ⅲ)x(OH)2-y(NO3)x+y,经焙烧后得Co3O4纳米颗粒。用红外光谱对所制样品的成分进行分析;用X射线衍射和场发射扫描电子显微镜表征产物的结构和形貌;用循环伏安、恒电流充放电等测试方法对Co3O4电化学性能进行研究。测试表明,Co3O4-300具有最佳的电容性能,单电极比电容可达338F/g,并且在1A/g电流密度下循环1000周后,比电容仍能保持93%,有望成为电化学电容器的电极材料。     

Co/HZSM-5催化剂中Co相态和价态的表征

苯乙烯是一种重要的化工原料 ,是合成聚苯乙烯等高分子材料的单体 .目前 ,工业上苯乙烯的生产采用两步法工艺 ,即苯和乙烯在 Al Cl3或 HZSM- 5催化剂上烷基化合成乙苯 ,然后乙苯再在含有助催化剂的氧化铁系催化剂上脱氢得到苯乙烯 .在另一部分工作中 ,我们采用金属负载 HZSM- 5分子筛催化剂研究了苯和乙烯一步合成苯乙烯反应 ,结果表明 ,Co/HZSM- 5是较好的催化剂[1] ,并提出了反应是经过中间物乙苯脱氢生成苯乙烯的机理 [2 ] .实验还发现 ,催化剂的焙烧和还原温度对苯乙烯的收率有很大影响 .本工作结合 XRD,TPR和 DRS等方法对 Co…     

一步制备高比表面积介孔Co3O4-CeO2及其表征

以有序介孔二氧化硅KIT-6为硬模板,硝酸钴、硝酸铈为金属源,分别在真空辅助条件和普通搅拌条件下制备了介孔CoCeOx复合氧化物。采用XRD、SEM、TEM、N2吸脱附等技术表征了复合氧化物的物化性质,并评价其氧化甲苯的性能。结果表明,在真空辅助和搅拌条件下制备的CoCeOx氧化物是由Co3O4和CeO2组成的介孔Co3O4-CeO2复合氧化物,其比表面积分别为141和89 m^2·g^-1,平均孔径分别为8.7和9.6 nm。真空辅助纳米复制过程有利于金属盐的前驱体充分填充到模板的孔隙中,去除模板后,可以得到有序的介孔复合金属氧化物。所制备介孔钴铈复合氧化物具有孔道有序性好、比表面积大的特点,在挥发性有机化合物的氧化去除方面具有一定的应用前景。     

非贵金属催化剂用于CO选择性氧化脱除的研究

以Co和Ni为催化剂活性组分、活性炭为载体,通过饱和浸渍法制得非贵金属催化剂,采用XRD、SEM和TPD对催化剂性能进行表征,考察了该催化剂用于富氢气中CO选择性氧化活性及H₂O或/和CO₂对催化性能的影响。研究结果表明,催化剂以NiO和高分散的Co₃O₄为主要物相,催化剂吸附O₂的能力随着金属氧化物负载量的增加而增加,且催化剂对O₂分子的吸附能力明显强于CO₂分子。金属氧化物负载量为35%的催化剂表现出较高的CO选择性氧化活性和选择性,在低于473K时O₂氧化选择性达50%以上,此时可将CO浓度降到40×10^-6以下,达到燃料电池对氢燃料气的要求。同时,催化剂表现出较强的抗水蒸气和CO₂的能力。     

Co/Ce0.5Zr0.5O2催化剂的制备及甲烷部分氧化制合成气

利用共沉淀法制备了具有介孔结构的Ce_0.5Zr_0.5O₂固溶体载体,然后浸渍不同质量分数(10%、20%、30%)的活性组分钴,制备了系列Co/Ce_0.5Zr_0.5O₂催化剂。利用N₂物理吸附(BET)、X射线粉末衍射(XRD)、H₂-程序升温还原(H₂-TPR)、扫描电子显微镜(SEM) 、透射电子显微镜(TEM) 、 程序升温氧化(TPO)和热重(TG)等手段对制备和反应后的催化剂进行了表征,研究了它们对甲烷部分氧化制合成气反应的催化性能。研究结果表明,铈锆固溶体负载的钴比较容易被还原,该系列催化剂具有较高的活性和对H₂及CO的选择性,且随Co含量的增加,催化剂的活性和对H₂和CO的选择性得到提高的同时,也增强了催化剂的抗积炭性能。     

Photochemical synthesis of a water oxidation catalyst based on cobalt nanostructures

New cobalt-based nanocomposites have been prepared by photoreduction of Co(2+) salts to generate cobalt nanoparticles deposited on carbon-based materials such as nanocyrstalline diamond and carbon felt. Spontaneous air oxidation converts the metal to Co(2)O(3) which has been tested as a water oxidation catalyst. This work demonstrates that the cobalt oxide nanostructures can be deposited on various carbon surfaces and can catalyze the four-electron oxidation of water to oxygen under anodic bias.     

Cobalt and magnesium ferrite nanoparticles: preparation using liquid foams as templates and their magnetic characteristics

An easy and convenient method for the synthesis of cobalt and magnesium ferrite nanoparticles is demonstrated using liquid foams as templates. The foam is formed from an aqueous mixture of an anionic surfactant and the desired metal ions, where the metal ions are electrostatically entrapped by the surfactant at the thin borders between the foam bubbles and their junctions. The hydrolysis is carried out using alkali resulting in the formation of desired nanoparticles, with the foam playing the role of a template. However, in the formation of ferrites with the formula MFe(2)O(4), where the metal ion and iron possess oxidation states of +2 and +3, respectively, forming a foam from a 1:2 mixture of the desired ionic solutions would lead to a foam composition at variance with the original solution mixture because of greater electrostatic binding of ions possessing a greater charge with the surfactant. In our procedure, we circumvent this problem by preparing the foam from a 1:2 mixture of M(2+) and Fe(2+) ions and then utilizing the in situ conversion of Fe(2+) to Fe(3+) under basic conditions inside the foam matrix to get the desired composition of the metal ions with the required oxidation states. The fact that we could prepare both CoFe(2)O(4) and MgFe(2)O(4) particles shows the vast scope of this method for making even multicomponent oxides. The magnetic nanoparticles thus obtained exhibit a good crystalline nature and are characterized by superparamagnetic properties. The magnetic features observed for CoFe(2)O(4) and MgFe(2)O(4) nanoparticles are well in accordance with the expected behaviors, with CoFe(2)O(4) particles showing higher blocking temperatures and larger coercivities. These features can easily be explained by the contribution of Co(2+) sites to the magnetocrystalline anisotropy and the absence of the same from the Mg(2+) ions.     

Co3O4/CeO2 CO氧化的原位红外光谱研究

采用沉淀氧化法制备了Co₃O₄/CeO₂催化剂。分别在干、湿条件下进行了一氧化碳氧化反应研究。运用FT-IR表征手段,在钴铈复合氧化物上进行了CO吸附及CO/O₂共吸附研究。结果表明,与纯的Co₃O₄样品相比,Co₃O₄/CeO₂具有明显的抗湿气能力。Co₃O₄/CeO₂催化剂在进行CO氧化时,表面形成了类碳酸盐物种。当环境温度低于453 K时,催化剂上类碳酸盐的生成与形成类碳酸盐物种后受热分解存在着动态平衡。当环境温度高于493 K,催化剂上生成的类碳酸盐物全部受热分解。氧化铈的加入提高了催化剂的抗湿气性能。较小粒径的Co₃O₄与CeO₂产生的强相互作用可使CeO₂向Co₃O₄提供氧,因而间接提供了CO氧化需要的氧。     

The Solid-State-Grinding Synthesis of Maganese-Modified Cobalt Oxides and Application in the Low-Temperature CO Preferential Oxidation in H<Subscript>2</Subscript>-Rich Gases

A series of MnOx modified cobalt oxides with different atomic molar ratios of Mn/(Mn?+?Co) were prepared by a soft reactive grinding route and investigated for CO preferential oxidation in H₂. It was found that as-prepared Mn-doped cobalt oxides exhibited superior activity compared to the single constituted oxides, other Mn–Co–O mixed oxides synthesized by solution-based route, and other grinding-derived mixed metal oxides M–Co–O (M?=?Zn, Ni, Cu, Fe). The grinding-derived MnCo10 catalyst with Mn/(Mn?+?Co) molar ration of 10% showed the best CO oxidation activity and higher selectivity at low temperature. The surface richness of Co³⁺ was not found as increasing the Mn molar ratio in the present work. However, the incoporation of MnOx with proper amount into Co₃O₄ could produce high surface area, high structure defects, and rich surface active oxygen species, while the ability to supply the active oxygen species was suggested to play the crucial role in promoting the catalytic performance of Mn–Co–O mixed oxides.     

X-ray absorption spectroscopy of Mn/Co/TiO2 Fischer-Tropsch catalysts: relationships between preparation method, molecular structure, and catalyst performance

The effects of the addition of manganese to a series of TiO(2)-supported cobalt Fischer-Tropsch (FT) catalysts prepared by different methods were studied by a combination of X-ray diffraction (XRD), temperature-programmed reduction (TPR), transmission electron microscopy (TEM), and in situ X-ray absorption fine structure (XAFS) spectroscopy at the Co and Mn K-edges. After calcination, the catalysts were generally composed of large Co(3)O(4) clusters in the range 15-35 nm and a MnO(2)-type phase, which existed either dispersed on the TiO(2) surface or covering the Co(3)O(4) particles. Manganese was also found to coexist with the Co(3)O(4) in the form of Co(3-x)Mn(x)O(4) solutions, as revealed by XRD and XAFS. Characterization of the catalysts after H(2) reduction at 350 degrees C by XAFS and TEM showed mostly the formation of very small Co(0) particles (around 2-6 nm), indicating that the cobalt phase tends to redisperse during the reduction process from Co(3)O(4) to Co(0). The presence of manganese was found to hamper the cobalt reducibility, with this effect being more severe when Co(3-x)Mn(x)O(4) solutions were initially present in the catalyst precursors. Moreover, the presence of manganese generally led to the formation of larger cobalt agglomerates ( approximately 8-15 nm) upon reduction, probably as a consequence of the decrease in cobalt reducibility. The XAFS results revealed that all reduced catalysts contained manganese entirely in a Mn(2+) state, and two well-distinguished compounds could be identified: (1) a highly dispersed Ti(2)MnO(4)-type phase located at the TiO(2) surface and (2) a less dispersed MnO phase being in the proximity of the cobalt particles. Furthermore, the MnO was also found to exist partially mixed with a CoO phase in the form of rock-salt Mn(1-x)Co(x)O-type solid solutions. The existence of the later solutions was further confirmed by scanning transmission electron microscopy with electron energy loss spectroscopy (STEM-EELS) for a Mn-rich sample. Finally, the cobalt active site composition in the catalysts after reduction at 300 and 350 degrees C was linked to the catalytic performances obtained under reaction conditions of 220 degrees C, 1 bar, and H(2)/CO = 2. The catalysts with larger Co(0) particles ( approximately >5 nm) and lower Co reduction extents displayed a higher intrinsic hydrogenation activity and a longer catalyst lifetime. Interestingly, the MnO and Mn(1-x)Co(x)O species effectively promoted these larger Co(0) particles by increasing the C(5+) selectivity and decreasing the CH(4) production, while they did not significantly influence the selectivity of the catalysts containing very small Co(0) particles.