Characterization of Fe/N-doped graphene as air-cathode catalyst in microbial fuel cells

This work proposed a simple and efficient approach for synthesis of durable and efficient non-precious metal oxygen reduction reaction(ORR) electro-catalysts in MFCs. The rod-like carbon nanotubes(CNTs)were formed on the Fe–N/SLG sheets after a carbonization process. The maximum power density of1210 ± 23 m W·m~(-2) obtained with Fe–N/SLG catalyst in an MFC was 10.7% higher than that of Pt/C catalyst(1080 ± 20 mW ·m~(-2)) under the same condition. The results of RDE test show that the ORR electron transfer number of Fe–N/SLG was 3.91 ± 0.02, which suggested that ORR catalysis proceeds through a four-electron pathway. The whole time of the synthesis of electro-catalysts is about 10 h, making the research take a solid step in the MFC expansion due to its low-cost, high efficiency and favorable electrochemical performance. Besides, we compared the electrochemical properties of catalysts using SLG, high conductivity graphene(HCG, a kind of multilayer graphene) and high activity graphene(HAG, a kind of GO) under the same conditions, providing a solution for optimal selection of cathode catalyst in MFCs.The morphology, crystalline structure, elemental composition and ORR activity of these three kinds of Fe–N/C catalysts were characterized. Their ORR activities were compared with commercial Pt/C catalyst.It demonstrates that this kind of Fe–N/SLG can be a type of promising highly efficient catalyst and could enhance ORR performance of MFCs.     

Electrochemical performance of annealed cobalt-benzotriazole/CNTs catalysts towards the oxygen reduction reaction

One of the major limitations yet to the global implementation of polymer electrolyte membrane fuel cells (PEMFCs) is the cathode catalyst. The development of efficient platinum-free catalysts is the key issue to solve the problem of slow kinetics of the oxygen reduction reaction (ORR) and high cost. We report a promising catalyst for ORR prepared through the annealing treatment under inert conditions of the cobalt-benzotriazole (Co-BTA) complex supported on carbon nanotubes (CNTs). The N-rich benzotriazole precursor was chosen based on its ability to complex Co(II) ions and generate under annealing highly reactive radicals able to tune the physicochemical properties of CNTs. X-Ray photoelectron spectroscopy (XPS) was used to follow the surface structure changes and highlight the active electrocatalytic sites towards the ORR. To achieve further evaluation of the catalysts in acidic medium, voltamperometry, rotating disk electrode (RDE), rotating ring-disk electrode (RRDE) and half-cell measurements were performed. The resulting catalysts (Co/N/CNTs) all show catalytic activity towards the ORR, the most active one resulting from annealing at 700 °C. The overall electron transfer number for the catalyzed ORR was determined to be ～3.7 with no change upon the catalyst loading, suggesting that the ORR was dominated by a 4e(-) transfer process. The results indicate a promising alternative cathode catalyst for ORR in fuel cells, although its performance is still lower (overpotential around 110 mV evaluated by RDE and RRDE) than the reference Pt/C catalyst.     

高分散钴氮共掺杂碳纳米纤维氧还原催化剂

过渡金属氮掺杂碳基催化剂已成为替代铂基氧还原反应(ORR)电催化剂的理想选择。本文通过静电纺丝技术制备了高比表面、高度分散的钴原子配位氮掺杂的碳纳米纤维催化剂(Co-N/C)。X射线衍射(XRD)和高分辨率透射电镜(HRTEM)结果证实Co元素高度分散于制备的Co-N/C催化剂中。X射线光电子能谱结果表明N元素主要以吡啶N和石墨N形式存在。该Co-N/C催化剂对ORR反应呈现出较高的电催化活性,其氧还原起始和半波电位分别为0.92 V和0.80 V(相对于标准氢电极),接近于商业化Pt/C催化剂的性能。以制备的Co-N/C催化剂作为阴极,25℃下锌空气燃料电池的开路电位1.54 V、最大功率密度达到了190 m V·cm~(-2)表明该催化剂具有良好的应用前景。     

An Isolated Zinc–Cobalt Atomic Pair for Highly Active and Durable Oxygen Reduction

A competitive complexation strategy has been developed to construct a novel electrocatalyst with Zn‐Co atomic pairs coordinated on N doped carbon support (Zn/CoN‐C). Such architecture offers enhanced binding ability of O₂, significantly elongates the O?O length (from 1.23 Å to 1.42 Å), and thus facilitates the cleavage of O?O bond, showing a theoretical overpotential of 0.335 V during ORR process. As a result, the Zn/CoN‐C catalyst exhibits outstanding ORR performance in both alkaline and acid conditions with a half‐wave potential of 0.861 and 0.796 V respectively. The in situ XANES analysis suggests Co as the active center during the ORR. The assembled zinc–air battery with Zn/CoN‐C as cathode catalyst presents a maximum power density of 230 mW cm^?2 along with excellent operation durability. The excellent catalytic activity in acid is also verified by H₂/O₂ fuel cell tests (peak power density of 705 mW cm^?2).     

Carbon-supported Fe/Co-N electrocatalysts synthesized through heat treatment of Fe/Co-doped polypyrrole-polyaniline composites for oxygen reduction reaction

In this paper,we synthesized cathode catalysts(PANI-PPYR,Fe/PANI-PPYR,Co/PANI-PPYR and Fe-Co/PANI-PPYR)with high performance oxygen reduction by using a simple heat treatment process.These catalysts were fabricated by directly calcining the Fe and/or Co doped polyaniline(PANI)-polypyrrole(PPYR)composites.Their electrocatalytic activity for ORR both in acidic and in alkaline media was investigated by voltammetric techniques.Among the prepared catalysts,Co/PANI-PPYR presents the most positive ORR onset potential of 0.62 V(vs.SCE)in 0.5 mol/L H2SO4 solution or?0.09 V(vs.SCE)in 1 mol/L NaOH solution.In addition,the Co/PANI-PPYR catalyst shows the largest limiting-diffusion current density for ORR,which is 4.3 mA/cm2@0.2 V(vs.SCE)in acidic and 2.3 mA/cm2@?0.3 V(vs.SCE)in alkaline media.In acidic media,a four-electron reaction of ORR on the Co/PANI-PPYR and Fe/PANI-PPYR catalysts is more dominant than a two-electron reaction.In alkaline media,however,a four-electron and a two-electron mechanisms are co-present for the ORR on all the prepared catalysts.Co/PANI-PPYR catalyst also presents good electrocatalytic activity stability for ORR both in acidic and in alkaline media.     

铁、氮掺杂石墨烯/碳黑复合材料的制备及氧还原电催化性能

以高含氮量的2-氨基咪唑为氮源,三氯化铁为铁源,高比表面积的KJ600碳黑为载体,通过水热法制得氨基咪唑聚合物前驱体,再经二次高温热处理,制得石墨烯/碳黑复合材料. 透射电镜表征显示该材料为石墨烯纳米片与碳黑颗粒的复合结构. BET表征表明这是一种多孔结构,具有很高的比表面积（882 m²•g^-1）,这有利于暴露更多活性位点,并促进传质. XRD证实催化剂中存在石墨烯,且石墨烯结构是在第一次热处理过程中形成的. 电化学测试表明,该催化剂在酸性和碱性介质中都具有很高的氧还原电催化活性和低H₂O₂产率,并且在碱性介质中对甲醇小分子的抗毒化性能明显优于商业Pt/C催化剂,展示出在实际燃料电池系统中的应用潜力.     

Metal Phthalocyanine‐Porphyrin‐based Conjugated Microporous Polymer‐derived Bifunctional Electrocatalysts for Zn‐Air Batteries

Conjugated microporous polymers (CMPs) as emerging porous materials with diverse structures and tunable building‐units have attracted much attention in the electrochemical field. Herein, we designed phthalocyanine‐porphyrin‐based conjugated microporous polymers as precursors for fabrication of Co, Fe, N tri‐doped graphene composites towards oxygen reduction and evolution reaction (ORR/OER). As expected, the elements cobalt and iron are well dispersed in graphene carbon and interact with the nitrogen sites, thereby providing extra electrocatalytic active sites and enhancing its overall conductivity. Benefiting from its unique design and structure, the obtained catalyst affords a superior bifunctional catalytic activity with a positive onset potential of 0.957 V for ORR, and a low overpotential of 0.36 V for OER. More attractively, the CoFeNG is employed as an air cathode catalyst in Zn‐air batteries, showing a maximum current density of 215 mA cm^?2 and good cycle stability for 20000 s. The rational design of phthalocyanine‐porphyrin‐based derivatives provides a feasible route for the construction of high‐performance ORR/OER catalysts.     

Mesoporous carbon nitride loaded with Pt nanoparticles as a bifunctional air electrode for rechargeable lithium-air battery

A composite comprised of oxygen reduction reaction (ORR) catalyst and oxygen evolution reaction (OER) catalyst was designed and applied as a bifunctional electrocatalyst for the air electrode of the lithium-air battery. The ordered mesoporous carbon nitride (MCN) prepared by a nano hard-templating approach displayed a surface area as high as 648 m² g^?1 and a large pore volume of 0.7 cm³ g^?1 and acted as both the ORR catalyst and the support for the in situ-formed OER catalyst of Pt particles with a diameter of 3–4 nm. The electrochemical performances of the electrode were examined in a solid-state lithium-air cell structured as Li/LATP-based electrolyte/cathode, which demonstrated a higher round-trip efficiency and lower overpotential compared with the Pt@AB and MCN electrodes. The combination of the OER and ORR catalysts is proved as an effective way to improve the performance of lithium-air batteries.     

Paper-derived cobalt and nitrogen co-doped carbon nanotube@porous carbon as a nonprecious metal electrocatalyst for the oxygen reduction reaction

The oxygen reduction reaction (ORR) is a vitally important process in fuel cells. The development of high-performance and low-cost ORR electrocatalysts with outstanding stability is essential for the commercialization of the electrochemical energy technology. Herein, we report a facile synthesis of cobalt (Co) and nitrogen (N) co-doped carbon nanotube@porous carbon (Co/N/CNT@PC-800) electrocatalyst through a one-step pyrolysis of waste paper, dicyandiamide, and cobalt(II) acetylacetonate. The surface of the hierarchical porous carbon supported a large number of carbon nanotubes (CNTs), which were derived from dicyandiamide through the catalysis of Co. The addition of Co resulted in the formation of a hierarchical micro/mesoporous structure, which was beneficial for the exposure of active sites and rapid transportation of ORR-relevant species (O₂, H⁺, OH^?, and H₂O). The doped N and Co formed more active sites to enhance the ORR activity of the electrocatalyst. The Co/N/CNT@PC-800 material exhibited optimal ORR performance with an onset potential of 0.005 V vs. Ag/AgCl and a half-wave potential of –0.173 V vs. Ag/AgCl. Meanwhile, the electrocatalyst showed an excellent methanol tolerance and a long-term operational durability than that of Pt/C, as well as a quasi-four-electron reaction pathway. The low-cost and simple synthesis approach makes the Co/N/CNT@PC-800 a prospective electrocatalyst for the ORR. Furthermore, this work provides an alternative approach for exploring the use of biomass-derived electrocatalysts for renewable energy applications.     

CoPy/C催化剂应用碱性介质氧还原催化的电化学性能

利用碳黑（Vulcan XC-72R）中加入硫酸钴和吡啶（Py）作为催化剂前驱体,经溶剂分散热处理构建了一类新型的高效氧还原CoPy/C复合催化剂.并运用循环伏安法（CV）和旋转圆盘电极（RDE）技术研究了不同Co含量的CoPy/C催化剂在碱性介质中对氧还原的电催化活性.结果表明:Co的存在对氧的催化剂活性位的形成有重要影响,800℃下所制备的10%Co30%Py/C（质量分数）复合催化剂表现出最佳的氧还原催化活性.以其制备的气体扩散电极在3.0 mol·L^-1KOH电解质溶液（O₂气氛）中0.014 V（相对于标准氧电极（RHE））即可产生明显的氧还原电流.同40%Py/C相比,10%Co30%Py/C催化氧还原的起峰电位正移了71 mV,同时表现出明显的极限扩散电流.在-0.16 V时电流密度达到最大值,电流密度为1.0 mA·cm^-2,半波电位在-0.07 V.透射电镜分析表明所制备的碳黑载吡啶钴（10%Co30%Py/C）催化剂平均粒径为20 nm.     

Ultrahigh‐Loading Zinc Single‐Atom Catalyst for Highly Efficient Oxygen Reduction in Both Acidic and Alkaline Media

Atomically dispersed Zn–N–C nanomaterials are promising platinum‐free catalysts for the oxygen reduction reaction (ORR). However, the fabrication of Zn–N–C catalysts with a high Zn loading remains a formidable challenge owing to the high volatility of the Zn precursor during high‐temperature annealing. Herein, we report that an atomically dispersed Zn–N–C catalyst with an ultrahigh Zn loading of 9.33 wt % could be successfully prepared by simply adopting a very low annealing rate of 1° min^?1. The Zn–N–C catalyst exhibited comparable ORR activity to that of Fe–N–C catalysts, and significantly better ORR stability than Fe–N–C catalysts in both acidic and alkaline media. Further experiments and DFT calculations demonstrated that the Zn–N–C catalyst was less susceptible to protonation than the corresponding Fe–N–C catalyst in an acidic medium. DFT calculations revealed that the Zn–N₄ structure is more electrochemically stable than the Fe–N₄ structure during the ORR process.     

吸电子和亲水性Co-卟啉促进电催化氧还原反应的研究

研究影响电催化氧还原反应活性的因素对于合理设计高效的氧还原反应催化剂至关重要。调节催化剂电子结构通常被用于精确调控电催化氧还原反应活性。然而, 该反应发生在液/气/固界面, 很少有报道调控分子催化剂的亲疏水性来提高其催化活性。在此, 我们报道了两种钴卟啉NO₂-CoP（5,10,15,20-四（4-硝基苯基）钴卟啉）和5F-CoP（5,10,15,20-四（五氟苯基）钴卟啉）并研究了其电催化氧还原反应性能。通过同时调控meso-位取代基的电子结构和亲水性能, NO₂-CoP显示出比5F-CoP更高的电催化氧还原反应活性, 其半波电位向阳极方向移动近60 mV。NO₂-CoP比5F-CoP具有更好的亲水性。理论计算表明, NO₂-CoP比5F-CoP更容易有效地与O₂分子结合形成Co^III-O₂^·-。这项工作提供了一个简单而有效的策略, 通过使用吸电子和亲水取代基来提高钴卟啉的氧还原反应活性。该策略对于设计和开发其他用于电催化的分子催化剂体系也具有重要的启发意义。     

吡啶掺杂碳载钴酞菁催化氧还原的电化学性能及在燃料电池中的应用

以碳黑(Vulcan XC-72R)为载体, 吡啶(Py)和钴酞菁(CoPc)为催化剂前驱体, 经溶剂分散法制备了Py掺杂碳负载纳米钴酞菁复合催化剂(Py-CoPc/C). 通过扫描电镜-能谱分析(SEM-EDS)、X射线光电子能谱(XPS)分析和X射线衍射(XRD)分析技术对催化剂的组成和微观结构进行了表征, 并运用线性扫描循环伏安法(LSV)和旋转圆盘电极(RDE)技术考察了不同Py掺杂含量对碳载钴酞菁(CoPc/C)催化氧还原反应(ORR)活性的影响及稳定性. 结果显示: Py掺杂可以明显改善CoPc/C 对ORR的电催化性能, 其中掺杂20%Py下所制备的20%Py-20%CoPc/C 催化剂对ORR表现出最佳的催化活性, 以其制备的气体扩散电极在O₂气氛饱和的0.1 mol·L^-1 KOH 电解质溶液中, 0.2 V (相对于标准氢电极)即可产生明显的氧还原电流, 半波电位为-0.03 V. 相比于40%Py/C 和未掺杂的40%CoPc/C, 20%Py-20%CoPc/C催化剂的半波电位分别正移了160 和15 mV. 进一步运用RDE理论研究表明, 在Py-CoPc/C 电极上ORR的电子转移总数为2.38, 高于CoPc/C电极上的电子转移总数1.96, 从而使ORR的选择性明显提高. SEM-EDS和XRD分析表明Py掺杂提高了CoPc/C催化剂的分散性和N含量, 更利于O₂的吸附. XPS分析表明: 吡啶结构的N与石墨结构的N均存在于Py-CoPc/C 催化剂中,与催化剂表面的Co离子配位可能是促使ORR活性提高的原因. 最后以20%Py-20%CoPc/C制备了膜电极组装(MEA)电极, 应用于H₂/O₂ 燃料电池单电池发电, 室温下获得最大发电功率密度为21 mW·cm^-2, 相对于CoPc/C提高至2.4倍.     

高温处理对碳载吡啶钴催化氧还原性能的影响

利用碳黑(Vulcan XC-72R) 中加入硫酸钴和吡啶(Py)作为催化剂前躯体, 经溶剂分散热处理构建了一类新型的高效氧还原CoPy/C复合催化剂. 运用循环伏安法和旋转圆盘电极(RDE)技术研究了不同温度(600~900 ℃)处理CoPy/C催化剂在碱性介质中对氧还原的电催化性能. 结果表明, 热处理能显著提高CoPy/C的催化活性, 活性次序为800 ℃>900 ℃>600 ℃>未处理. 其中800 ℃处理的15%Co25%Py/C(质量分数)复合催化剂表现出最佳的氧还原催化性能, 以其制备的气体扩散电极在3.0 mol/L KOH 电解质溶液(O₂气氛)中的半波电位为-0.069 V(相对于标准可逆氢电极), 起峰电位为0.026 V, 同时表现出明显的极限扩散电流. 利用透射电镜、 能谱分析和X射线衍射技术对催化剂的微观形貌、 颗粒大小和活性位结构的研究结果表明, 所制备的碳黑负载吡啶钴催化剂(15%Co25%Py/C)平均粒径为17 nm, 经800 ℃处理后吡啶结构发生了坍塌, 形成了其它价态的钴氧化合物、 硫化物和单质钴, 并协同吡啶中的氮对氧起催化还原作用. RDE结果表明, O₂在CoPy/C催化剂上的反应动力学主要通过4e^-过程还原成H₂O.     

Polymer-Assisted Electrophoretic Synthesis of N-Doped Graphene-Polypyrrole Demonstrating Oxygen Reduction with Excellent Methanol Crossover Impact and Durability

The design and synthesis of metal-free catalysts with superior electrocatalytic activity, high durability, low cost, and under mild conditions is extremely desirable but remains challenging. To address this problem, a polymer-assisted electrochemical exfoliation technique of graphite in the presence of an aqueous acidic medium is reported. This simple, cost-effective, and mass-scale production approach could open the possibility for the synthesis of high-quality nitrogen-doped graphene–polypyrrole (NG-PPy). The NG-PPy catalyst displays an improved half wave potential (E_1/2=0.77 V) in alkaline medium compared with G-PPy (E_1/2=0.66 V). Most importantly, this catalyst demonstrates excellent stability with high methanol tolerance, and it outperforms the commercial Pt/C catalyst and other previously reported metal-free catalysts. The content of graphitic nitrogen atoms is the key factor for the enhancement of electrocatalytic activity towards oxygen reduction reactions (ORR). Interestingly, the NG-PPy catalyst can be used as a cathode material in a zinc–air battery, which demonstrates a higher peak power density (59 mW cm⁻²) than G-PPy (36.6 mW cm⁻²), highlighting the importance of the low-cost material synthesis approach towards the development of metal-free efficient ORR catalysts for fuel cell and metal–air battery applications. Remarkably, the polymer-assisted electrophoretic exfoliation of graphite with a high yield (≈88 wt %) of few-layer graphene flakes could pave the way towards the mass production of high-quality graphene for a variety of applications.     

基于氮掺杂碳载铁复合物的锌空电池氧阴极催化剂

迫在眉睫的环境和能源问题推动人类探索可行、可靠和可再生的能源技术.锌-空气电池和氢氧燃料电池等器件显示出高能量转换效率,但是仍有许多难题有待克服,例如阴极侧上缓慢的氧还原反应(ORR),以及高昂的成本极大地限制了铂基催化剂在商业上的广泛应用.因此,开发高性能的廉价ORR催化剂具有重要意义.过渡金属碳氮化合物(M-N-C, M=Co, Fe等)成为最有希望替代铂基催化剂的一类材料, M-N-C催化剂可以通过直接热解含有过渡金属、氮和碳物种的前驱体合成.然而热解时金属原子易团聚,多孔结构不能被有效地控制,导致相对较差的催化活性.目前, MOF衍生的催化剂在能源转化和储存技术中得到了广泛的关注,其具有丰富的氮含量、高比表面积和可调的孔道结构等特点.本文报道了一种简便可靠可控的合成铁氮共掺杂碳十二面体纳米结构催化剂的方法,并作为阴极电催化剂用于锌空气电池中,测试结果证实,合成的铁氮共掺杂的纳米碳具有与铂基材料相当的活性和更加优异的稳定性.表面吸附了的邻菲罗啉铁的ZIF-8在碳化过程中,氮基团能够结合铁形成Fe Nx结构单元,因此可得到铁氮共掺杂的电催化剂.粉末X射线衍射,扫描电镜证实ZIF-8的成功合成.经过热解得到的催化剂中Fe Nx或Fe Cx衍射峰较弱,表明样品中铁含量较低,存在部分无定型铁.通过拉曼光谱分析发现,引入的邻菲罗啉在热解过程中诱导了缺陷的形成,所以Fe-NCDNA-0的ID/IG比值明显高于NC.同时ID/IG随着铁含量的增加而减少,这是因为铁可以诱导石墨化,诱导效应随着铁含量的增加而增加.分析氮气吸附-脱附等温线得出,引入邻菲罗啉之后,比表面积增加;而铁的引入因其占据了微孔结构,导致比表面积下降.同时电镜证实Fe-NCDNA-2具有较大的形貌扭曲,使得该材料具有较大的比表面积.系统的电化学研究表明,氮掺杂有利于增强ORR活性,在引入铁之后形成高效的活性中心会进一步提高催化性能.因此, Fe-NCDNA-2在碱性条件下表现出优异的ORR性能.线性扫描伏安法曲线表明,铁氮共掺杂的材料表现出与Pt/C相似的性能,其中Fe-NCDNA-2的半波电位(E1/2)为0.863 V,比商业Pt/C的电位更正(E1/2=0.841 V).同时, Fe-NCDNA-2具有更加优异的稳定性,测试30000 s后的电流保持率为80%(Pt/C:64%).在中性介质中,合成的材料也展示了较高的ORR活性.Fe-NCDNA-2的E1/2=0.715 V,催化30000 s后电流保持率77%,均优于商业Pt/C催化剂.组装的锌空气电池进一步验证其作为氧还原催化剂实际应用的可行性.相比于以Pt/C为催化剂做空气阴极的电池,以Fe-NCDNA-2组装的电池表现出更高的开路电压,更高的功率密度(184 m Wcm^-2),以及更加优异的充放电循环稳定性.该工作也有利于启发研究人员探索类似的氮掺杂过渡金属碳材料在各种催化上的应用.     

S‐Doping of an Fe/N/C ORR Catalyst for Polymer Electrolyte Membrane Fuel Cells with High Power Density

Fe/N/C is a promising non‐Pt electrocatalyst for the oxygen reduction reaction (ORR), but its catalytic activity is considerably inferior to that of Pt in acidic medium, the environment of polymer electrolyte membrane fuel cells (PEMFCs). An improved Fe/N/C catalyst (denoted as Fe/N/C‐SCN) derived from Fe(SCN)₃, poly‐m‐phenylenediamine, and carbon black is presented. The advantage of using Fe(SCN)₃ as iron source is that the obtained catalyst has a high level of S doping and high surface area, and thus exhibits excellent ORR activity (23 A g^?1 at 0.80 V) in 0.1 M H₂SO₄ solution. When the Fe/N/C‐SCN was applied in a PEMFC as cathode catalyst, the maximal power density could exceed 1 W cm^?2.     

基于超重力技术开展Co-N-CNTs催化剂制备及其氧还原性能的研究

开发高效的非贵金属氧还原(ORR)催化剂是促进燃料电池商业化进程的关键。本研究利用超重力技术制备了一种优良的非贵金属ORR催化剂Co-N-CNTs。物理表征表明,通过超重力技术可以使作为活性位点的金属Co纳米颗粒均匀分布在Co-N-CNTs催化剂表面,X射线光电子能谱(XPS)揭示Co-N-CNTs催化剂中的N元素不仅可以和碳纳米管(CNTs)中的C元素形成吡咯氮和石墨氮,还可以形成具有更高氧还原活性的吡啶氮结构。电化学测试结果表明,通过超重力技术制备的Co-N-CNTs催化剂的起始电位和半波电位与商业Pt/C催化剂相当;而且,Co-N-CNTs催化剂展现出优良的抗甲醇性能。     

以CaCl2为模板合成的高活性和高稳定性铁、氮、硫共掺杂多子孔碳氧还原电催化剂

燃料电池是一种可将化学能通过电催化反应直接转化成电能的装置,具有能量密度高和清洁无污染等优点.燃料电池阴极氧还原反应(ORR)的动力学较迟缓,是电池能量效率损失的主要原因.目前ORR催化活性最高的是铂基催化剂,但由于贵金属铂价格昂贵,储量稀少,且对燃料小分子渗透的抗性较差,严重制约了燃料电池的大规模应用.因此,高性能、低成本的非贵金属催化剂成为燃料电池领域的研究热点.本文选用含氮量高达45％的三聚氰胺-甲醛树脂为碳源和氮源,Fe(SCN)3为铁源和硫源,以CaCl2为模板,在高温和铁的催化作用下将树脂碳化,经酸洗和二次热处理工艺,制备出铁、氮、硫共掺杂的多孔碳(FeNS-PC).干燥后的CaCl2颗粒可防止树脂在高温下交联形成块状碳颗粒,同时起到造孔模板的作用.CaCl2颗粒在温和条件下即可除去,无需强腐蚀性条件,因此不会对催化活性中心造成破坏.在Fe/N/C催化剂中掺杂S可进一步提高催化活性,不添加碳载体可避免低活性的碳载体降低质量活性,多孔结构可促进传质,充分利用活性位点.我们优化了热处理温度,并对催化剂的结构、组分及催化性能等进行了表征分析.结果表明,热处理温度为900℃时,可将树脂完全转化成多孔碳,并获得较高的杂原子掺杂量,可达到最优活性.CaCl2为模板剂可避免使用强腐蚀性试剂去除模板,有利于保留活性位,并得到多孔结构.FeNS-PC-900的比表面积可达775 m2/g.得益于原位掺杂的合成工艺,各掺杂元素在多孔碳表面均匀分布.在酸性介质中,FeNS-PC-900的半波电位可达到0.811V,仅比商业Pt/C催化剂低78 mV;在0.8V电位下的质量活性为10.2 A/g,表现出优异的催化活性.经过10000圈加速衰减测试后,其半波电位仅下降了20 mV,在0.75V电位下持续放电10000s后,其ORR电流仍保持初始电流的84.4％,具有比Pt/C更加优异的稳定性.以FeNS-PC-900为阴极催化剂的质子交换膜燃料电池的最大功率密度可达到0.49 W/cm2,并在0.6V电压下持续放电10h后,其电流仍可保持初始电流的65％,表现出良好的应用潜力.FeNS-PC-900具有高掺杂含量、高比表面积和多孔结构,并且杂原子在催化剂表面均匀分散,在半电池和燃料电池测试中都表现出优异的催化活性和稳定性,表明其是一种非常有潜力应用于燃料电池的非贵金属氧还原催化剂.     

氧还原和析氧反应的双功能电催化剂--氮磷共掺碳负载四氧化三钴

金属-空气电池具备诸多优势,譬如绿色环保、能量转化率高、启动快速、能量密度高、使用寿命和干态存储时间长等.与燃料电池相比,金属-空气电池结构简单,放电电压平稳,成本低,但依然存在一些制约发展的问题,如阴极催化剂.阴极催化剂在金属-空气电池中发挥催化氧还原反应(oxygen reduction reaction, ORR)和析氧反应(oxygen evolution reac-tion, OER)的关键作用.铂及其合金常用作 ORR的单功能催化剂,而钌和铱等是目前 OER催化效率最高的,但 ORR活性很低,因此需要开发出一种廉价而又具备双功能催化作用的催化剂.单异原子掺杂的碳基催化剂的研究集中在 ORR催化性能上,而多异原子共掺碳最近有研究表明具有双催化氧的性质,如氮磷共掺碳.在这些氮磷共掺的碳架中,氮磷共掺物起着 OER催化作用,掺氮物为 ORR催化的活性位点,而掺磷物起着强化作用.异原子掺杂负载的钴基催化剂(如掺氮还原氧化石墨烯载 Co3O4)是近年来双功能催化剂研究的另一个热点.钴基催化剂有着催化 ORR和 OER的多价价态,然而其本身导电性能差,这一缺陷可通过杂化石墨化碳来弥补,石墨化碳有着优良的导电性能.据我们所知,目前仍没有关于氮磷共掺碳负载的 Co3O4双催化氧的研究.我们合成了氮磷共掺碳(NPC)负载的 Co3O4(Co3O4/NPC),并首次探索了其氧还原和析氧性能. Co3O4/NPC合成分两步进行.首先通过三聚氰胺与植酸之间的酯化或缩聚覆盖在导电炭黑颗粒表面,在保护气氛下焙烧得到 NPC,然后经溶剂热反应以及空气中氧化合成 Co3O4/NPC.催化剂的性能综合考虑了催化活性和稳定性两方面.采用线性扫描伏安法评估了 OER和 ORR的催化活性.对于 OER, Co3O4/NPC的起始电势是0.54 V (以饱和甘汞电极为参比电极),在0.80 V时电流密度达到21.95 mA/cm2,均优于 Co3O4/C和 NPC. Co3O4/NPC的高效 OER催化可归因于氮磷共掺物与 Co3O4之间的协同作用.对于 ORR, Co3O4/NPC的催化效率与商用 Pt/C相近,它们的扩散极限电流密度分别为–4.49和–4.76 mA/cm2(E =–0.80 V).在 ORR过程中, Co3O4起到主要的催化作用.采用计时电流(电流-时间)法评估了催化剂的稳定性.经6 h测定,对于 OER, Co3O4/NPC剩46%电流;而对于 ORR,剩95%电流.整体而言, Co3O4/NPC在 OER和 ORR中都表现出高的催化效率以及良好的稳定性.