CoOOH用作陰極催化劑對(duì)非水性鋰-氧氣電池性能的影響

蔡生容　王曉飛　朱丁　母仕佳　張開(kāi)放　黃利武　陳云貴＊,

(1四川大學(xué)材料科學(xué)與工程學(xué)院，成都610065) (2四川大學(xué)新能源與低碳技術(shù)研究院，成都610065)

CoOOH用作陰極催化劑對(duì)非水性鋰-氧氣電池性能的影響

蔡生容1王曉飛1朱丁＊,2母仕佳1張開(kāi)放1黃利武1陳云貴＊,1

(1四川大學(xué)材料科學(xué)與工程學(xué)院，成都610065) (2四川大學(xué)新能源與低碳技術(shù)研究院，成都610065)

利用工藝簡(jiǎn)單，成本低廉的共沉淀法制得CoOOH，并用作非水性鋰-氧氣電池陰極催化劑。通過(guò)恒流充放電、線性伏安掃描(LSV)和電化學(xué)阻抗(EIS)測(cè)試研究了電極的電化學(xué)性能。結(jié)果表明：由于CoOOH能夠明顯提高氧氣還原反應(yīng)(ORR)的催化活性，與未使用CoOOH的電極相比較，使用CoOOH為催化劑的電極首次放電容量高達(dá)5 093 mAh·g-1,提高了1.7倍。電池的充電過(guò)電壓降低了約460 mV,充電可逆性得到增強(qiáng)，充放電可逆性提高，使得循環(huán)性能得到顯著改善。

鋰-氧氣電池；CoOOH；催化劑；高性能

With the demands of energy storage in electric vehicles markets,Li-O2batteries have attracted worldwide attention due to its high theoretical specific energy up to 11 586 Wh·kg-1(excluding O2)[1],which is equal to that of the gasoline[2],and is about eight times higher than that of the Li-ion batteries[3].In general,the non-aqueous Li-O2battery consists of anode metal Li,high Li-ion conductive organic electrolyte,and the oxygen cathode.On the basis of the electrochemical reaction 2Li+O2?Li2O2,the ideal discharge&recharge process of Li-O2batteries is in essence of the oxygen reduction reaction(ORR)and oxygen evolution reaction(OER)[4],which involves no pollution,and makes the batteries environment-friendly.However,in spite of the great prospect,the practical application of Li-O2technology is restricted by several serious issues of the oxygen cathode, including low capacity,large polarization and extremely poor cycle capabilities[4-6].

Developing catalysts has been proved to be a feasible approach to improve the performance of Li-O2batteries[7-9].Among the reported catalysts,noble metal materials display efficient catalytsis for the ORR or the OER[10-11],butthe widespread applicationsare limited due to the high cost.Because of the low cost,ease of preparation and reasonably good catalytic activity, transition metal oxides have drawn more interest,such as Co3O4,MnO2,Fe3O4,NiO and so on[12-13].Except, metal oxyhydroxides which are important precursors for metal oxides have been considered as promising catalysts.Zhang et al.used high aspect ratioγ-MnOOH nanowires as catalysts for non-aqueous Li-O2batteries,enabling the cathode to obtain outstanding performances which were attributed to the cathode porosity and high catalystefficiency[14].Zhang etal.also reported that the lithium-air battery based onγ-MnOOH/MWCNTs composites gave high discharge capacity and low charge potential[15].Lietal.investigated β-FeOOH nanospindles coated on multi-walled carbon nanotubes(β-FeOOH/MWCNTs)in Li-O2batteries which afforded a high capacity of 6 000 mAh·g-1,and good rate capability[16].However,up to now,CoOOH has been rarely researched in Li-O2batteries.Considering the good catalyses of the Co-based oxides and the oxyhydroxides,the catalytic activity of CoOOH is urgent to be studied.

Herein,CoOOH was successfully prepared by a simple one-step co-precipitation method,and the Li-O2batteries using CoOOH as catalyst displayed high electrochemical performance.

1　Experimental

1.1Catalyst synthesis

The preparation of CoOOH was according to previous report[17].In a typicalsynthesis,2 g of CoCl2·6H2O was dissolved in 21 mL of deionized water (H2O).Next,1 g of NaOH was also dissolved in 32 mL of H2O,and dropped into the CoCl2solution with stirring.Subsequently,HCl was used to adjust the pH value to 12.And 50 mL of H2O2(30%)was added into the mixture.Then,the mixture was heated at 60℃for 2 h with magnetic stirring.After cooling to room temperature,the final products were filtered, washed and dried.

1.2Li-O2cellassembly and electrochemical measurements

According to our previous report[18],a swageloktype Li-O2battery was assembled in an argon-filled glove box by placing a lithium foil,two celgard 2500 separators,70μL organic electrolyte(0.9 mol·L-1LiTFSI in tetraethylene glycol dimethyl ether (TEGDME)solvents),and a dried porous cathode into a custom-designed cell.The cathode was prepared by coating a mixture of 50%Super P carbon(SP),30% CoOOH and 20%polyvinylidene fluoride(PVDF)on a nickel foam current collector(1.5 cm-2),and marked as CSP electrode.The cathode was dried at 120℃under vacuum for 12 h.The carbon loading was about 1.5 mg,and the capacity for the Li-O2battery was calculated based on the weight of SP.After standing for 2 hours,the galvanostatic tests were carried out on a LAND 2001A at 25℃under 101.325 kPa pressure of O2.The test voltage was from 2.0 to 4.5 V versus Li+/Li,and the current density was 0.07 mA·cm-2.A cathode composed of SP and PVDF was also made for comparison,and named SP electrode.

1.3Characterizations

After electrochemical test,the battery was disassembled for further analysis,in the glove box.X-ray diffraction(XRD)was carried outusing a Dandong DX-2600 diffractometer,with Cu Kαradiation(λ= 0.154 18 nm)ata scan speed of0.04°·s-1.The operating voltage was 35 kV and the current was 25 mA.The micrograph was collected by scanning electron microscopy(SEM,JSM-7500F)and the operating voltage was 5 kV.Electrochemical impedance spectroscopy(EIS) was measured by a PARSTAT2273 and the frequency was from 100 kHz to 10 mHz.Linear sweep voltammetry(LSV)was also carried out on a PARSTAT2273 with the scan speed of 0.2 mV·s-1.

2　Results and discussion

Fig.1a is the XRD pattern of prepared CoOOH. The main diffraction peaks of the products are well indexed to the(003),(101),(012),(104),(015),(107), (110)and(113)planes of CoOOH(PDF No.07-0169). The morphology was detected by SEM,as shown in Fig.1b.

Fig.1 Characterization of prepared CoOOH:(a)XRD pattern;(b)SEM image

Fig.2 Electrochemical performance of Li-O2batteries with the SP and the CSP electrodes:(a)the first discharge-charge curves;(b)XRD patterns;(c)cathodic LSV curves;(d)EIS spectra

Fig.2a shows the typical discharge-recharge curves of both the SP and the CSP electrodes.At the discharge terminal,the CSP electrode delivers a specific capacity of5 093 mAh·g-1,which is 1.7 times higher than thatofthe SP electrode(1 883 mAh·g-1). The discharge voltage of the CSP electrode(2.6 V)is also 70 mV higher than that of the SP electrode(2.53 V).Obviously,the introduction of CoOOH greatly enhances the energy output of the oxygen cathode. Fig.2b exhibits the XRD patterns of the discharge products for both electrodes.The main peaks around 33°,35°and 58°can be assigned to the Li2O2phase (PDF No.73-1640),indicating that the formation of Li2O2on both the SP and the CSP electrodes duringthe discharge process.Fig.2c presents the cathodic LSV curves of the SP and CSP electrodes.Apparently, the peak current(Ip)ofthe CSP cathode(0.8 mA·cm-2) is much higher than thatof the SP cathode(0.54 mA· cm-2),suggesting a high ORR catalysis of the asprepared CoOOH.Fig.2d displays the EIS spectra of two kinds of electrodes.Two plots exhibita semicircle and a line.According to the literature[16],the high frequency intercept of the semicircle on the real axis is Rs,which includes resistance from electrodes and their contacts to the current collectors and electrolyte resistance.The semicircle at medium frequency is charge-transfer resistance(Rct),corresponding to the kinetic reaction at the air electrode surface.The line atlow frequency is Rw,which is a finite length Warburg element that may be attributed to the diffusion in the cathode.It can be found that the charge-transfer resistance(Rct)in the pristine CSP electrode(36Ω)is much smaller than that in the pristine SP electrode (91Ω),indicating an enhanced kinetics of the ORR, which is in agreement with the result of the LSV(Fig. 2c).The greatly enhanced ORR kinetics significantlyimproves the energy output(Fig.2a).Moreover,the charge voltage plateau of the CSP electrode is 3.99 V, which is 460 mV smaller than that of the SP electrode,suggesting a significantly enhanced recharge-ability ofthe CSP electrode.

Fig.3 Discharge-charge curves,cycling performances and discharge-charge potential plateaus of the Li-O2battery with the SP(a,c,e)and the CSP(b,d,f)electrodes

In order to investigate the cycling performance of Li-O2batteries,the SP and CSP electrodes were tested following the widely used capacity-limited way[19],with a capacity restriction of 500 mAh·g-1.Fig.3a exhibits the discharge-charge curves of the Li-O2battery with the SP electrode.The related discharge-charge capacity and potential plateau against the cycle number are displayed in Fig.3c and 3e,respectively.The battery with the SP electrode can just completely be operated for 8 cycles.It notes that the recharge capacity starts to decrease atthe 9th cycle when the recharge voltage reaches 4.5 V.From the 9th to 15th cycle,only the discharge capacity meets the fixed value indicating the recharge is incomplete.The 15th coulombic efficiency of the SP electrode is simply 72%.On the contrary,the CSP electrode shows the superior cycling performance.It can be found that the battery with the CSP electrode has no fading of discharge and charge capacities during continued 30 cycles and the coulombic efficiency always keeps 100%,as shown in Fig.3b and 3d.These results show thatthe introduction of CoOOH enhances the cycling performance of the Li-O2batteries.The 1st discharge voltage of the CSP electrode(2.64 V)is about 30 mV higher than that of the SP electrode(2.61 V),and the 1stcharge voltage of the CSP electrode is approximately 3.84 V that is 280 mV smaller than that of the SP electrode(4.12 V).Although the charge voltage increases during the subsequent cycling process,the performance of the CSP electrode is still better than that of the SP electrode.When the SP electrode does not achieve the fixed charge capacity reaching the cut-off voltage at the 15th cycle,the charge voltage of the CSP electrode with the 100%coulombic efficiency is about 3.92 V.After 30 cycles,the charge voltage of the CSP electrode is just 4.03 V.Meanwhile,the discharge voltage is as high as 2.53 V(as shown in Fig.3f).

Fig.4 SEM images of the SP(a,b,c)and CSP electrodes(d,e,f)at pristine,discharged and recharged,respectively

SEM was used to investigate the changes in morphology at different discharge-recharge states,as shown in Fig.4.Fig.4b reveals that the typical smooth toroidal Li2O2in the large size coats on the discharged SP cathode,as revealed by the earlier studies[20].At the end of the recharge process,some toroidal Li2O2can still be clearly observed(Fig.4c).That means the SP electrode is irreversible.Dramatically differing from the SP electrode,there is relatively rough chain morphology attached to the surface of the discharged CSP electrode,as exhibited in Fig.4e.In contrast to the SP electrode,the generated Li2O2almostcompletelydecomposes and the surface is relatively clear(Fig.4f). The electrode nearly returns to the pristine.

3　Conclusions

In summary,CoOOH has been successfully prepared by a simple one-step co-precipitation method. Compared with the SP electrode,the CSP electrode displayed a specific capacity as high as 5 093 mAh· g-1,significantly reduced recharge potential and enhanced cycling stability.The CSP electrode had an improved ORR catalysis,and enhanced rechargeability.Our findings indicate that CoOOH is potentially good catalyst for high performance Li-O2batteries.

References:

[1]Bruce P G,Freunberger S A,Hardwick L J,etal.Nat.Mater., 2012,11:19-29

[2]YANG Feng-Yu(楊鳳玉),ZHANG Lei-Lei(張蕾蕾),XU Ji-Jing(徐吉靜),et al.Chinese J.Inorg.Chem.(無(wú)機(jī)化學(xué)學(xué)報(bào)),2013,29(8):1563-1573

[3]Ogasawara T,Débart A,Holzapfel M,et al.J.Am.Chem. Soc.,2006,128(4):1390-1393

[4]Gao R,Zhu J Z,Xiao X L,et al.J.Phys.Chem.C,2015, 119(9):4516-4523

[5]Su W W,Wang W,Li Y L,et al.Mater.Lett.,2016,180:203 -206

[6]Park M,Sun H,Lee H,et al.Adv.Energy Mater.,2012,2(7): 780-800

[7]Prabu M,Ketpang K,Shanmugam S.Nanoscale,2014,6(6): 3173-3181

[8]Kwak W J,Lau K C,Shin C D,et al.ACS Nano,2015,9(4): 4129-4137

[9]Hu X F,Han X P,Hu X,et al.Nanoscale,2014,6(7):3522-3525

[10]JIANG Jie(蔣頡),LIU Xiao-Fei(劉曉飛),ZHAO Shi-Yong (趙世勇),et al.Acta Chim.Sinica(化學(xué)學(xué)報(bào)),2014,4:417-426

[11]Jiang J,He P,Tong S F,etal.NPG Asia Mater.,2016,8:e239

[12]Kuang P,Li L Y,Chen C G,et al.Mater.Lett.,2016,176: 97-100

[13]Tong S F,Zheng M B,Lu Y,et al.J.Mater.Chem.A,2015,3 (31):16177-16182

[14]Zhang L L,Zhang X B,Wang Z L,et al.Chem.Commun., 2012,48(61):7598-7600

[15]Zhang M,Xu Q,Sang L,et al.Chin.Sci.Bull.,2014,59(24): 2973-2979

[16]Li J X,Wen W W,Zou M Z,et al.J.Alloys Compd.,2015, 639:428-434

[17]Zhu L,Wu W Y,Zhu Y S,et al.J.Phys.Chem.C,2015, 119(13):7069-7075

[18]Zhu D,Zhang L,Song M,et al.J.Solid State Electron., 2013,17(11):2865-2870

[19]Wang X F,Cai S R,Zhu D,et al.RSC Adv.,2015,5(107): 88485-88491

[20]Black R,Lee J H,Adams B,et al.Angew.Chem.Int.Ed., 2013,125(1):410-414

CoOOH as Cathode Catalyst for High Performance Non-Aqueous Li-O2Batteries

CAISheng-Rong1WANG Xiao-Fei1ZHU Ding＊,2MU Shi-Jia1ZHANG Kai-Fang1HUANG Li-Wu1CHEN Yun-Gui＊,1
(1College of Materials Science and Engineering,Sichuan University,Chengdu 610065,China) (2Institute of New Energy and Low-Carbon Technology,Sichuan University,Chengdu 610065,China)

CoOOH was synthesized by a simple one-step co-precipitation method,and used as cathode catalyst in non-aqueous Li-O2batteries.The introduction of CoOOH could catalyze the oxygen reduction reaction(ORR) upon discharge,making the CoOOH-contained cathode display a high discharge capacity of 5 093 mAh·g-1, which was about 1.7 times higher than that of the CoOOH-free cathode.Furthermore,the CoOOH-contained cathode exhibited a significantly reduced recharge overpotential(460 mV),enhancing recharge-ability.Thus,the reversibility was improved,and the cycling performance was ameliorated.

Li-O2battery;CoOOH;catalyst;high performance

TM912；O614.81+2

A

1001-4861(2016)12-2082-06

10.11862/CJIC.2016.272

2016-07-26。收修改稿日期：2016-10-07。

中物院——川大協(xié)同創(chuàng)新聯(lián)合基金(No.XTCX2014001)和四川大學(xué)青年教師科研啟動(dòng)基金(No.2015SCU11055)資助項(xiàng)目。

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