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预膨胀制备氮化硼纳米片及其导热复合材料性能
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作者 王晨 聂向导 +5 位作者 彭思侃 柴瑞瑞 石贤斌 班露露 赵亚星 桑欣欣 《高分子材料科学与工程》 EI CAS CSCD 北大核心 2023年第12期103-110,共8页
由六方氮化硼(h-BN)剥离制备氮化硼纳米片(BNNS)需破坏相邻层中B与N原子交替堆积产生的Lip-lip作用,因此,单层或少层BNNS制备效率低是限制其广泛应用的重要原因。文中采用预先膨胀辅助液相超声的方法,利用碳酸氢铵受热分解产生CO_(2)和... 由六方氮化硼(h-BN)剥离制备氮化硼纳米片(BNNS)需破坏相邻层中B与N原子交替堆积产生的Lip-lip作用,因此,单层或少层BNNS制备效率低是限制其广泛应用的重要原因。文中采用预先膨胀辅助液相超声的方法,利用碳酸氢铵受热分解产生CO_(2)和NH3气体插层到h-BN层间,得到预先膨胀的h-BN,后经超声处理成功制备了横向尺寸约1μm、厚度2.5nm的高质量BNNS。所得BNNS与纤维素纳米纤维(CNF)经溶液共混、抽滤,制得了CNF/BNNS复合材料。当CNF/BNNS复合材料中BNNS质量分数为50%时,复合材料的面内热导率高达18.85W/(m·K),相比较基体提高了3.5倍,高度取向的超薄BNNS在基体内形成了有效的导热通路,使得复合材料的导热性能得到显著提高。 展开更多
关键词 六方氮化硼 预膨胀 剥离 纤维素纳米纤维 导热
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Effects of bicarbonate and cathode potential on hydrogen production in a biocathode electrolysis cell 被引量:2
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作者 Dawei LIANG Yanyan LIU +3 位作者 sikan peng Fei LAN Shanfu LU Yan XIANG 《Frontiers of Environmental Science & Engineering》 SCIE EI CAS CSCD 2014年第4期624-630,共7页
A biocathode with microbial catalyst in place of a noble metal was successfully developed for hydrogen evolution in a microbial electrolysis cell (MEC). The strategy for fast biocathode cultivation was demonstrated.... A biocathode with microbial catalyst in place of a noble metal was successfully developed for hydrogen evolution in a microbial electrolysis cell (MEC). The strategy for fast biocathode cultivation was demonstrated. An exoelectrogenic reaction was initially extended with an H2-full atmosphere to enrich Ha-utilizing bacteria in a MEC bioanode. This bioanode was then inversely polarized with an applied voltage in a half-cell to enrich the hydrogen-evolving biocathode. The electrocatalytic hydrogen evolution reaction (HER) kinetics of the biocathode MEC could be enhanced by increasing the bicarbonate buffer concentration from 0.05 mol·L-1 to 0.5 mol· L-1 and/or by decreasing the cathode potential from -0.9 V to - 1.3 V vs. a saturated calomel electrode (SCE). Within the tested potential region in this study, the HER rate of the biocathode MEC was primarily influenced by the microbial catalytic capability. In addition, increasing bicarbonate concentration enhances the electric migration rate of proton carriers. As a consequence, more mass H+ can be released to accelerate the biocathode-catalyzed HER rate. A hydrogen production rate of 8.44 m3. m 3. d1 with a current density of 951.6 A. m-3 was obtained using the biocathode MEC under a cathode potential of - 1.3 V vs. SCE and 0.4 mol· L-1 bicarbonate. This study provided information on the optimization of hydrogen production in biocathode MEC and expanded the practical applications thereof. 展开更多
关键词 microbial electrolysis cell (MEC) BIOCATHODE hydrogen production BICARBONATE cathode potential
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