Micropores regulating enables advanced carbon sphere catalyst for Zn-air batteries

Energy conversion technologies like fuel cells and metal-air batteries require oxygen reduction reaction(ORR)electrocatalysts with low cost and high catalytic activity.Herein,N-doped carbon spheres(N-CS)with rich micropore structure have been synthesized by a facile two-step method,which includes the polymerization of pyrrole and formaldehyde and followed by a facile pyrolysis process.During the preparation,zinc chloride(ZnCl2)was utilized as a catalyst to promote polymerization and provide a hypersaline environment.In addition,the morphology,defect content and activity area of the resultant N-CS catalysts could be regulated by controlling the content of ZnCl2.The optimum N-CS-1 catalyst demonstrated much better catalytic activity and durability towards ORR in alkaline conditions than commercial 20 wt%Pt/C catalysts,of which the half-wave potential reached 0.844 V vs.RHE.When applied in the Zn-air batteries as cathode catalysts,N-CS-1 showed a maximum power density of 175 mW cm^(-2) and long-term discharging stability of over 150 h at 10 mA cm^(-2),which outperformed 20 wt%Pt/C.The excellent performance could be due to its ultrahigh specific surface area of 1757 m2 g
1 and rich micropore channels structure.Meanwhile,this work provides an efficient method to synthesize an ultrahigh surface porous carbon material,especially for catalyst application.

耐盐碱解磷菌Bacillus sp.DYS211对土壤磷溶解和植物生长的促进作用

土壤全磷含量高而速效磷含量不足严重制约盐碱地区磷的高效利用。虽然耐盐碱解磷菌可以溶解不溶性磷,但很少有研究关注其在植物生长中的应用。我们从盐碱地区鸟粪中分离到一株解磷菌,鉴定命名为Bacillus sp.DYS211,并对其生长特性和耐盐碱能力进行了测定。为研究解磷菌对植物种子萌发和生长的影响,在盐地碱蓬中进行解磷菌添加的盆栽试验。该解磷菌菌株在培养前12 h生长迅速,48 h时溶磷量最大,达到258.22 mg L^(−1)。耐盐碱性和解磷能力试验表明,DYS211倾向于溶解无机磷,为嗜盐菌,在1%–8%盐度条件下具有良好的解磷效果(有效磷含量>150 mg L^(−1))。在葡萄糖和蔗糖(C源)以及硫酸铵、硝酸铵和酵母浸膏粉(N源)中均表现出较好的解磷能力。在促生长试验中,该解磷菌对种子萌发有促进作用,特别是在高盐胁迫下,促进率为8.33%。在盐碱条件下,解磷菌均能显著提高盐地碱蓬的株高和生物量(最高可达3倍),且高盐胁迫下茎粗增加。该菌株表现出在盐碱地区植被恢复中的潜力。