新型Ti/Zr-SnO_(2)/β-PbO_(2)电极的构筑及高效降解亚甲基蓝

该文采用热分解法先制备Zr-SnO_(2)中间层,再电沉积β-PbO_(2)层,成功制备了Ti/Zr-SnO_(2)/β-PbO_(2)电极。利用扫描电镜(SEM)、能量散射谱(EDS)、X射线衍射(XRD)、X射线光电子能谱(XPS)技术对电极形貌、晶体结构、元素组成等进行了分析。通过循环伏安法(CV)、电化学交流阻抗法(EIS)、加速寿命实验等测试其电化学性能,考察其电催化降解亚甲基蓝(Methylene Blue,MB)活性,优化电流密度和初始MB浓度。结果表明:Ti/Zr-SnO_(2)/β-PbO_(2)电极的表面为致密四棱锥结构,形成了非化学计量比的β-PbO_(2);与传统的Ti/β-PbO_(2)电极相比,Zr-SnO_(2)中间层可有效提高钛基涂层电极的析氧过电位;修饰电极阻抗为87.64Ω/cm2,电极加速寿命为439 min,是Ti/β-PbO_(2)电极的219.5倍,是Ti/SnO_(2)/β-PbO_(2)电极的1.71倍;在50 mA/cm2的电流密度下降解初始浓度为50.00 mg/L的MB时,180 min内MB去除率可达97%。

Ti／PbO_(2)电极的研制

研究了工艺参数对制备ＰｂＯ２／Ｔｉ电极性能的影响，通过ＳＥＭ、ＸＲＤ和强化寿命结果分析，得出了制备Ｐｂｏ２／Ｔｉ电极的最佳工艺条件即镀β－ＰｂＯ２的最佳电流密度３Ａ／ｄｍ２，镀液温度６０℃。试验结果表明，在Ｈ２ＳＯ４、ＨＮＯ３介质中，对析氧反应而言，Ｔｉ／ＰｂＯ２电极具有好的催化活性和高的阳极电位；在１５０ｇ／ＬＨ２ＳＯ４、６０℃、２００Ａ／ｄｍ２条件下，强化寿命最高达１３０９ｈ。

Can perfluorooctanoic acid be effectively degraded usingβ-PbO_(2)reactive electrochemical membrane?

Aqueous perfluorooctanoic acid(PFOA)elimination has raised significant concerns due to its persistence and bioaccumulation.Althoughβ-PbO_(2)plate anodes have shown efficient mineralization of PFOA,it remains unclear whether PFOA can be effectively degraded usingβ-PbO_(2)reactive electrochemical membrane(REM).Herein,we assessed the performance of Ti/SnO_(2)-Sb/La-PbO_(2)REM for PFOA removal and proposed a possible degradation mechanism.At a current density of 10 mA/cm2and a membrane flux of 8500(liters per square meter per hour,LMH),the degradation efficiency of 10 mg/L PFOA was merely8.8%,whereas the degradation efficiency of 0.1 mg/L PFOA increased to 96.6%.Although the porous structure of theβ-PbO_(2)REM provided numerous electroactive sites for PFOA,the generated oxygen bubbles in the pores could block the pore channels and adsorb PFOA molecules.These hindered the protonation process and significantly impeded the degradation of high-concentration PFOA.Quenching experiments indicated that·OH played dominant role in PFOA degradation.The electrical energy per order to remove 0.1 mg/L PFOA was merely 0.74 Wh/L,which was almost an order of magnitude lower than that of other anode materials.This study presents fresh opportunities for the electrochemical degradation of low-concentration PFOA usingβ-PbO_(2)REM.

动力铅酸电池循环过程性能研究

采用X衍射分析、扫描电镜分析、热分析和含酸量测试等方法,研究了动力用铅酸蓄电池循环期间正极活性物质性能的变化、电解液分层情况和板栅参数变化。随着循环的进行,凝胶区物质[PbO(OH)_(2)]逐渐减少,极板上、下部位的活性物质含量不同,其中上部β-PbO_(2)偏多,下部PbSO_(4)偏多,而且活性物质孔率逐渐增大。最后发现,电池失重、板栅腐蚀和板栅边框厚度损失在100次循环后加速。

化成初期电流对免维护电池正极板组分的影响

通过XRD、SEM,考察了免维护铅酸蓄电池制造过程中化成初期电流对正极板组分产生的影响。初期电流的大小会影响正极板不同部位PbO_(2)总含量和α-PbO_(2)含量,特别是在中心位置α-PbO_(2)含量相对较高,同时会导致微观上部分PbO_(2)晶体形貌改变。随着电池化成初期电流的增大,ω(α-PbO_(2))/ω(β-PbO_(2))的比值呈现先增大后减小的趋势,且在初期电流为20 A时α-PbO_(2)含量最大。

VRLA电池正极板添加红丹的研究

通过添加红丹铅粉的粒径分析和粒度分布图,添加红丹正极板的XRD谱图和化成各阶段效果图,以及试验电池的初期容量和循环性能,验证了红丹对VRLA电池的有利影响。正极铅膏中添加红丹,可以使蓄电池的初期容量提高3%~5%,提高极板的充电效率,使极板表面充电均匀,有利于控制化成中电池内部温度,达到更佳的化成效果。