研究背(bei)景
鋰離子電(dian)池廣(guang)泛應用于便攜式電(dian)子器件(jian)、電(dian)動汽車、智能電(dian)網等(deng)領域。但(dan)是,鋰離子電(dian)池安(an)(an)全(quan)問(wen)題(ti),能量密(mi)度不足以及極(ji)端氣溫(wen)條(tiao)件(jian)下無法工(gong)作(zuo)等(deng)問(wen)題(ti)限(xian)制了其進一步發(fa)展(zhan)。全(quan)固態電(dian)池因具有不可(ke)燃(ran)的(de)固態電(dian)解質,可(ke)顯著(zhu)提(ti)升其安(an)(an)全(quan)性,工(gong)作(zuo)溫(wen)度范圍,成為(wei)一種極(ji)具潛力的(de)電(dian)化學(xue)儲能器件(jian)。但(dan)全(quan)固態電(dian)池的(de)實用化仍面(mian)臨著(zhu)諸多難題(ti)。基于此,加州大學圣地亞哥(ge)分校(xiao)的(de)孟穎教授和Zheng Chen教授聯(lian)合對全固(gu)態(tai)電(dian)池(chi)(chi)中電(dian)解質化學、界面表征技(ji)術、規模化生產以及(ji)可持續回收(shou)利用四個方面進(jin)行綜述,為全固(gu)態(tai)電(dian)池(chi)(chi)研究及(ji)實(shi)用化提供了指導(dao)。
總結(jie)展望
固(gu)(gu)(gu)態(tai)電(dian)(dian)池(chi)(chi)(chi)的(de)發展可(ke)(ke)以(yi)(yi)解決(jue)傳統鋰離子(zi)電(dian)(dian)池(chi)(chi)(chi)能量密度不足以(yi)(yi)及(ji)安全性較(jiao)差的(de)問題,但是距離固(gu)(gu)(gu)態(tai)電(dian)(dian)池(chi)(chi)(chi)實用(yong)(yong)化(hua)仍有較(jiao)大困難。本文綜述了采用(yong)(yong)納米工(gong)程(cheng)解決(jue)等方(fang)法解決(jue)固(gu)(gu)(gu)態(tai)電(dian)(dian)池(chi)(chi)(chi)界(jie)面(mian)(mian)穩(wen)定性的(de)方(fang)法和*先進的(de)固(gu)(gu)(gu)態(tai)電(dian)(dian)池(chi)(chi)(chi)界(jie)面(mian)(mian)表征技術,并提(ti)出了采用(yong)(yong)溶(rong)液法規(gui)模化(hua)制備全固(gu)(gu)(gu)態(tai)電(dian)(dian)池(chi)(chi)(chi)粘接劑和溶(rong)劑的(de)選擇(ze)標準以(yi)(yi)及(ji)全固(gu)(gu)(gu)態(tai)電(dian)(dian)池(chi)(chi)(chi)可(ke)(ke)持(chi)續回收的(de)策略,為全固(gu)(gu)(gu)態(tai)電(dian)(dian)池(chi)(chi)(chi)的(de)研究(jiu)和規(gui)模化(hua)應用(yong)(yong)提(ti)供了指導(dao)。
