一種具有出色儲(chǔ)能潛力的植物型超級(jí)電容器，有可能為電動(dòng)汽車鋪平道路，在幾分鐘內(nèi)就能充電，克服了廣泛采用的障礙之一，并且對(duì)司機(jī)和環(huán)境有益。

　　A plant-based supercapacitor with excellent energy storage potential could pave the way for electric vehicles to be recharged in a few minutes, overcoming one of the barriers to widespread adoption and benefiting drivers and the environment.

　　超級(jí)電容器幾乎可以在瞬間充電，并在需要時(shí)釋放出巨大的能量，是一種具有巨大潛力的儲(chǔ)能技術(shù)。我們已經(jīng)看到了一些有趣的進(jìn)展，用可持續(xù)材料制造設(shè)備，包括循環(huán)利用的塑料瓶、甚至廢棄的煙頭。

　　Supercapacitor can be charged almost instantaneously and release huge energy when needed. It is a kind of energy storage technology with great potential. We've seen some interesting developments in making equipment from sustainable materials, including recycled plastic bottles and even discarded cigarette butts.

　　德克薩斯農(nóng)工大學(xué)的團(tuán)隊(duì)希望利用一種天然聚合物，這種稱為木質(zhì)素的聚合物賦予植物和樹木以剛性，這是由造紙行業(yè)作為廢品大量生產(chǎn)的，實(shí)際上我們已經(jīng)看到了一些有趣的突破，努力將這種聚合物回收到其他產(chǎn)品中，例如更堅(jiān)固的混凝土和3D打印的生物漿。

　　The team at Texas A & M University wants to take advantage of a natural polymer, called lignin, that gives plants and trees rigidity, which is produced in large quantities by the paper industry as waste. In fact, we have seen some interesting breakthroughs in trying to recycle this polymer into other products, such as stronger concrete and 3D printed bio pulp.

　　然而，新研究的作者希望用它來為一種用于超級(jí)電容器電極的材料--二氧化錳。與其他解決方案相比，這種化合物的納米顆粒提供了許多好處，但電化學(xué)性能是它們傾向于下降的地方。

　　However, the authors of the new study hope to use it as a material for supercapacitor electrodes, manganese dioxide. The nanoparticles of this compound offer many benefits over other solutions, but the electrochemical performance is where they tend to decline.

　　“與其他過渡金屬氧化物(如釕或氧化鋅)相比，二氧化錳更便宜，可獲得性豐富，而且更安全，這些過渡金屬氧化物被普遍用于制造電極，”研究作者梁宏說?！暗趸i的一個(gè)主要缺點(diǎn)是它的導(dǎo)電性較低?！?/p>

　　"Compared with other transition metal oxides, such as ruthenium or zinc oxide, manganese dioxide is cheaper, more available and safer, and these transition metal oxides are commonly used to make electrodes," said study author Liang Hong. "But one of the main disadvantages of manganese dioxide is its low conductivity."

　　此前的研究表明，木質(zhì)素與金屬氧化物的結(jié)合可以提升超級(jí)電容器電極的電性能，但該團(tuán)隊(duì)希望研究如何能具體增強(qiáng)二氧化錳的功能。于是他們?cè)O(shè)計(jì)了一種超級(jí)電容器，其中這兩種成分構(gòu)成了關(guān)鍵的構(gòu)件。

　　Previous studies have shown that the combination of lignin and metal oxides can improve the electrical properties of supercapacitor electrodes, but the team hopes to study how to specifically enhance the function of manganese dioxide. So they designed a supercapacitor, and these two components make up the key components.

　　該團(tuán)隊(duì)首先在普通消毒劑中凈化木質(zhì)素，然后施加熱量和壓力，使液體分解，使二氧化錳沉積在木質(zhì)素上。然后用這種混合物涂覆鋁板形成電極，再與另一個(gè)由鋁和活性炭制成的電極配對(duì)形成超級(jí)電容器，中間夾著凝膠電解質(zhì)。

　　The team first purified the lignin in a common disinfectant, then applied heat and pressure to decompose the liquid, causing manganese dioxide to deposit on the lignin. The mixture was then coated with aluminum plates to form electrodes, then paired with electrodes made of aluminum and activated carbon to form supercapacitors, sandwiched with gel electrolytes.

　　研究人員介紹說，這種新裝置輕巧、靈活、成本效益高，增加了其作為汽車結(jié)構(gòu)儲(chǔ)能元件的潛力。他們還報(bào)告說，它在測(cè)試中經(jīng)受住了極好的考驗(yàn)，發(fā)現(xiàn)它具有“非常穩(wěn)定的電化學(xué)特性”，并且在數(shù)千次循環(huán)中保持了存儲(chǔ)電荷的能力。

　　The new device is lightweight, flexible and cost-effective, which increases its potential as an energy storage component for automotive structures, the researchers said. They also report that it has stood an excellent test in tests and found that it has "very stable electrochemical properties" and maintains the ability to store charges over thousands of cycles.

　　在電容方面，超級(jí)電容器的表現(xiàn)都優(yōu)于那些電極完全由活性炭制成的超級(jí)電容器，或石墨烯與其他材料結(jié)合的超級(jí)電容器，這通常被用于衡量該器件存儲(chǔ)電荷的指標(biāo)。當(dāng)與一種采用二硒化錫制成的電極的超級(jí)電容器相比，新裝置提供的電容是其900倍。

　　In terms of capacitance, supercapacitors perform better than those whose electrodes are made entirely of activated carbon or graphene combined with other materials, which is usually used to measure the storage charge of the device. When compared with a supercapacitor with electrodes made of tin selenide, the new device offers 900 times more capacitance.