Stable Lithium?Carbon Composite Enabled byDual?Salt Additives

Lei Zheng, Feng Guo, Tuo Kang, Yingzhu Fan, Wei Gu, Yayun Mao, Ya Liu,Rong Huang, Zhiyun Li, Yanbin Shen?, Wei Lu, Liwei Chen,4

ABSTRACT Lithium metal is regarded as the ultimate negative elec?trode material for secondary batteries due to its high energy density.However, it suffers from poor cycling stability because of its high reac?tivity with liquid electrolytes. Therefore, continuous efforts have been put into improving the cycling Coulombic efficiency (CE) to extend the lifespan of the lithium metal negative electrode. Herein, we report that using dual?salt additives of LiPF6 and LiNO3 in an ether solvent?based electrolyte can significantly improve the cycling stability and rate capabil?ity of a Li?carbon (Li?CNT) composite. As a result, an average cycling CE as high as 99.30% was obtained for the Li?CNT at a current density of 2.5 mA cm-2 and an negative electrode to positive electrode capacity(N/P) ratio of 2. The cycling stability and rate capability enhancement of the Li?CNT negative electrode could be attributed to the formation of a better solid electrolyte interphase layer that contains both inorganic components and organic polyether. The former component mainly originates from the decomposition of the LiNO3 additive, while the latter comes from the LiPF6?induced ring?opening polymerization of the ether solvent. This novel surface chemistry significantly improves the CE of Li negative electrode, revealing its importance for the practical application of lithium metal batteries.

KEYWORDS Lithium metal battery; Coulombic efficiency; Dual?salt additives; Li?CNT; Solid electrolyte interphase

1 Introduction

Lithium (Li) has been regarded as the ultimate negative elec?trode material for high energy density secondary batteries owing to its high energy density [1-7]. However, Li metal is highly reactive to electrolytes and is prone to the dendrite formation during the Li striping/plating cycling, resulting in limited cycle life and severe safety issue that largely impede the practical application of lithium metal batteries [5, 8-12].Tremendous efforts have been dedicated to addressing the above problems in the last few decades, mainly including(1) regulating the homogeneity of Li deposition through controlling the negative electrode surface chemistry to sup?press the dendrite formation [13-17], (2) employing 2D/3D hosts for the Li metal to increase the specific surface area of the negative electrode thus decrease the current density to suppress the dendrite formation [18-21], and (3) solidify the electrolyte or constructing a solid layer on Li surface to protect it from reacting with electrolytes [22-29].

Although many improvements in Li stability have been reported, typical average cycling Coulombic efficiency (CE)of Li metal in a commercial carbonate or ether solvent?based electrolyte at a practical current density (＞ 3 mA cm-2) is usually lower than 99.0% [30-35] (Table S1), which is far below the standard required for practical application. The lifespan of a lithium metal negative electrode is critically dependent on its CE (Fig. 1). Suppose that the end of life capacity retention is 80%, a lithium metal with an average cycling CE of 99.926% can sustain 300 cycles of Li plating/stripping, but the one with an average cycling CE of 99.0%can only sustain a lifespan less than 30 cycles. As a result, a large excess of lithium metal (negative electrode to positive electrode capacity (N/P) ratio ＞ 50) is required to artificially enhance the cycle life, which brings down the volumetric energy density of the cell. Therefore, despite all the chal?lenges, it is still crucial and worthwhile to push on the effort in improving the average cycling CE of lithium metal.

Recently, we reported a lithium?carbon nanotube (Li?CNT) microsphere composite with a hydrophobic self?assembled monolayer (SAM) surface passivation layer as an negative electrode material [36-42]. With the protection of the SAM layer, the Li?CNT composite exhibited an average cycling CE beyond 99.0% at a small N/P ratio of 2 [41].However, the SAM layer could be damaged during Li plat?ing/stripping cycles, which limited further improvement of CE [42].

In this work, we demonstrated the combined use of two additives, i.e., LiPF6and LiNO3, in an ether?based electro?lyte can generate a thin but robust solid electrolyte inter?phase (SEI) layer on Li?CNT when the SAM passivation layer was damaged, significantly improve the cycling sta?bility and rate capability of the Li?CNT negative electrode.As a result, an average cycling CE as high as 99.30% was obtained for the Li?CNT composite negative electrode at a current density of 2.5 mA cm-2and an N/P of 2.

2 Experimental

2.1 Material Synthesis andLi?CNT Electrode Preparation

Fig. 1 Calculated lifespan of a lithium metal anode based on its CE

The Li?CNT composite was synthesis according to our previous reports [37, 39-43]. 2 g of porous carbon nanotubes microspheres prepared by spray?drying were mixed with 4 g of Li in an Ar?filled glovebox at 180 °C for 20 min under stirring of 500 r min-1[37, 41]. For the SAM passivation, 1 g of the Li?CNT was added to 10 mL of tetrahydrofuran (THF) solution containing 0.1 wt.%dihexadecanoalkyl phosphate (DHP) under stirring for 30 min. The resulting solution was vacuum?dried overnight to obtain the Li?CNT composite. To prepare a Li?CNT negative electrode, 20 mg of poly(styrene?co?butadiene)(Sigma?Aldrich), 20 mg of polystyrene (molecular weight:2,000,000, Alfa Aesar), 40 mg of acetylene black, and 320 mg of Li?CNT composite were dissolved in a 1.5 mL p?xylene solvent (anhydrous, 99.5%, Sigma?Aldrich), and magnetically stirred for 4 h, then the slurry was coated on a copper foil, followed by vacuum?drying at 60 °C for 8 h in an Ar?filled glove box (O2＜ 0.01 PPM, H2O ＜ 0.01 PPM) [37, 41]. The areal capacity loading of the Li?CNT electrode can be controlled by varying the thickness of the electrode. In this work, the areal capacity loading of the Li?CNT electrode used in the Li?CNT||Li?CNT symmetric cell is 10 mA h cm-2. While in the Li?CNT||LFP cell, in order to obtain a low N/P ratio of 2, the areal capacity loading of the Li?CNT electrode is controlled to be 5 mAh cm-2. The deep?depth of discharge for the Li?CNT||Li?CNT symmet?ric cell and the Li?CNT||LiFePO4full battery is 30% and 50%, respectively. All the Li?CNT||LFP cell was charging and discharging between 2.5-4.1 V.

2.2 Physical andChemical Characterizations

The morphology of the sample was characterized by scan?ning electron microscopy (SEM, Hitachi Regulus 8230) at 5 kV. Elemental composition was analyzed by energy?dis?persive X?ray spectroscopy (EDS, Quanta FEG 250) oper?ated at 20 kV. The X?ray photoelectron spectroscopy (XPS,PHI?5000 VersaProbe) of sample measurements all employed Al Kα radiation. The vibrational spectrum of SAM was char?acterized by sum?frequency generation (SFG) spectroscopy using an EKSPLA system with a copropagating configura?tion. The time?of?flight secondary ion mass spectrometry(TOF.SIMS5?100) was equipped with a 10 kV Bi+ions analysis beam and 1 kV Cs+sputtering for detecting nega?tive secondary?ion fragments. The dimethyl carbonate was applied as a cleaning agent for cycled electrodes before the characterization.

2.3 Electrochemical Characterizations

The 2025 button?type cells were assembled using Li?CNT as the negative electrode, polypropylene membrane (Celgard 2400) as the separator, lithium iron phosphate (LFP, Sin?lion Battery Tech, Co., Ltd.) with an area capacity of 2.5 mAh cm-2was used as the positive electrode, 1.0 M LiTFSI dissolved in a mixed solvent of DOL and DME (1:1 in volume) with 2 wt.% LiNO3(Sigma?Aldrich) as the base?line electrolyte. The amount of electrolyte used was esti?mated at 60 μL for each cell. The battery charger system from NEWARE Technology Ltd., Shenzhen was used for the charging/discharging test. The electrochemical impedance spectroscopy was obtained on a VMP300 electrochemical workstation (Bio?Logic, France) in a frequency range from 100 to 1 MHz with an amplitude of 10 mV. Five parallel cells were used for each test.

3 Results andDiscussion

The Li?CNT composite was prepared by impregnating spray?dried CNT microparticles with molten Li to obtain a Li?CNT composite, which was subsequently passivated by a hydrophobic SAM layer of dihexadecanoalkyl phosphate(DHP) via a simple wet chemistry method [41, 42]. The SAM passivated Li?CNT composite has a micro?spherical shape with a diameter of about 5 μm (Fig. S1a). The success?ful preparation of the DHP SAM layer was verified by EDS,XPS, and SFG characterization (Fig. S1b-g). The SAM passivated Li?CNT composite shows a specific capacity of 1912 mAh g-1at room temperature under a current density of 0.25 mA cm-2, and limited capacity loss (150 mAh g-1)was measured after storing in dry air (dew point: - 40 °C)for a week (Fig. S1h).

Li stripping/plating behaviors of SAM passivated Li?CNT(areal capacity loading: 10 mAh cm-2) symmetric cells with two different electrolytes are shown in Fig. 2. When using a typical ether?based electrolyte, that is, 1.0 M LiTFSI in a mixed solvent of DOL and DME (1:1 in volume), with 2 wt.% LiNO3additive, the Li?CNT||Li?CNT cell shows stable Li stripping/plating for only ～ 60 cycles at a current density of 3 mA cm-2and 3 mAh cm-2, and the overpoten?tial quickly ascends, reaching 260 mV at the 250th cycle(Fig. 2a, red color). The overpotential of the Li?CNT||Li?CNT cell with a single LiPF6additive is even larger than that with LiNO3additive and also quickly ascends after ～ 50 cycles (Fig. 2a, orange color). In sharp contrast, the Li?CNT||Li?CNT symmetric cell with a dual?salt additives of LiPF6and LiNO3cycled at the same condition exhibits dramatically improved cycling performance with a signifi?cantly stabilized overpotential. As shown in Fig. 2a (green color), the overpotential of the Li?CNT||Li?CNT symmet?ric cell is around ～ 60 mV for the first 35 cycles and then decrease to ～ 40 mV that remains for 500 cycles, suggesting that the SEI layer formed during the initial cycles is a good conductor for Li?ions compared to that formed in the elec?trolyte with a single LiNO3additive.

Fig. 2 a Voltage profiles of Li?CNT||Li?CNT cells cycling at 3 mA cm-2, 3 mAh cm-2 in ether?based electrolytes with a single LiNO3 additive,a single LiPF6 additive, and dual?salt additives of LiPF6 and LiNO3. b1-b3 Nyquist plots of the Li?CNT||Li?CNT cells showed at 3 mA cm-2,3 mAh cm-2. c The voltage profiles of Li?CNT||Li?CNT cells cycling at 6 mA cm-2, 3 mAh cm-2 in ether?based electrolytes with dual?salt addi?tives of LiPF6 and LiNO3

The impedance evolution of the Li?CNT||Li?CNT sym?metric cells during cycling at a current density of 3 mA cm-2was evaluated by the electrochemical impedance spec?troscopy (EIS) measurement. As shown in Fig. 2b1, the impedance of the cell that cycled with a single LiNO3addi?tive increases gradually during cycling, rising from 28 to 36 Ω after 150 cycles, indicating the formation of ionic insulat?ing SEI layer during cycling. Similar result is observed for that cell with a single LiPF6additive (Fig. 2b2). While for the Li?CNT||Li?CNT symmetric cell cycled with dual?salt additives of LiPF6and LiNO3, the impedance keeps decreas?ing during early cycles from 27 to 6 Ω and then maintains stable at around 10 Ω at 150 cycles (Fig. 2b3), indicating that an ion conductive and robust SEI layer is formed dur?ing earlier cycles. This result is in good agreement with the evolution of the overpotential showed in Fig. 2a.

Importantly, when the Li stripping/plating current density was further increased to 6 mA cm-2(Fig. 2c), 8 mA cm-2(Fig.S2a), and 10 mA cm-2(Fig. S2b), the Li?CNT||Li?CNT sym?metric cells cycled with dual?salt additives of LiPF6and LiNO3still show very stable cyclability with small overpotentials of 65, 118, and 217 mV, respectively, after an SEI formation acti?vation stage at early cycles. These results further suggest that the SEI layer formed in the electrolyte with dual?salt additives of LiPF6and LiNO3is well ionic conductive and robust.

It is worth noting that the concentration of the LiPF6addi?tive was optimized by comparing the overpotential of the Li?CNT||Li?CNT symmetric cells. As shown in Fig. S2c, after 500 cycles under 3 mA cm-2, 3 mAh cm-2, cells cycled with 0, 0.1, 0.2, 0.3, 0.4, and 0.5 wt.% of the LiPF6additive show the average overpotentials of 49, 48, 42, 46, 59, and 79 mV,respectively. Therefore, the optimized concentration of the LiPF6additive was determined to be 0.2 wt.%.

Fig. 3 a Cycle performance of the Li?CNT||LFP batteries in ether?based electrolytes with a single LiNO3 additive, a single LiPF6 additive, and dual?salt additives of LiPF6 and LiNO3, b, c discharge rate ability and charge rate ability of the Li?CNT||LFP batteries

The average cycling CE of the Li?CNT negative elec?trode in the two different electrolytes was evaluated using a LiFePO4positive electrode with a practical areal loading of 2.5 mAh cm-2under a low N/P ratio of 2. As shown in Fig. 3a, the Li?CNT||LFP cell cycled with a single LiNO3additive or a single LiPF6additive at 1 C bewteen 2.5-4.1 V maintains stable for around 330 cycles and 270 cycles,respectively. before rapid capacity decay, corresponding to an average cycling CE of 99.09% and 98.92%, respectively.However, with dual?salt additives of LiPF6and LiNO3, the cycle life of the Li?CNT||LFP cells can be further extended to 430 cycles, resulting in an average cycling CE of 99.30%,which is the best among reported literatures [37, 41, 42]. The voltage profile evolutions of the Li?CNT||LFP cells during cycling in ether?based electrolytes with different additives are showed in Fig. S3. Electrolyte decomposed product can be observed on the Li?CNT electrode in the Li?CNT||LFP cell after 200 cycles at 1 C in the in ether?based electrolytes with dual?salt additives of LiPF6and LiNO3(Fig. S4). However,the thickness of the Li?CNT electrode almost kept the same during cycling.

The Li?CNT||LFP cell cycled with dual?salt additives of LiPF6and LiNO3also shows improved rate performance,especially for the charge rate ability. As shown in Fig. 3b,when cells are charged at a constant current of 0.2 C and discharged at various C rates, the Li?CNT||LFP cell with dual?salt additives of LiPF6and LiNO3show slightly higher specific discharge capacities at 5 C and 10 C than those of the cell with only LiNO3additive or LiPF6additive; when the discharge current density is set at 0.2 C and the charge capacity varies (Fig. 3c), the Li?CNT||LFP cell with dual?salt additives of LiPF6and LiNO3shows even better charge capacities at 5 C and 10 C than that with a single LiNO3or LiPF6additive. These results again suggest that the SEI formed under the presence of both LiPF6and LiNO3addi?tives has a smaller impedance for conducting the Li+ions.

To probe why the Li?CNT SEI layer formed under the presence of dual?salt additives is more conductive and robust, morphology and chemistry evolution of the Li?CNT surface was analyzed by SEM, XPS, and TOF?SIMS.As shown in Fig. 4a, SEM images of the Li?CNT compos?ite before cycling at various magnifications show a clear sponge?like CNT framework. After 50 cycles at a current density of 6 mA cm-2, the surface of the Li?CNT electrode cycled with a single LiNO3additive or a single LiPF6additive is covered with a thick and uneven deposited layer(Fig. 4b, c). However, the surface of the Li?CNT electrode cycled with dual?salt additives of LiPF6and LiNO3is cov?ered with a unique thin surface layer composed of stacked?gossamer?like sheets (Fig. 4d), which could protect the lithium metal from the corrosion of the electrolyte and at the same time be a good conductor for Li?ion.

XPS depth profile analysis of the Li?CNT samples reveals very different surface chemistry evolution during cycling in electrolytes with a single LiNO3additive and with dual?salt additives of LiPF6and LiNO3. As shown in Fig. 5a1-d1,for the cell after the 1st cycle in the electrolyte with a sin?gle LiNO3additive, the SEI layer on the surface of the Li?CNT electrode mainly composed of LiNxOy, Li2CO3, Li2O,and LiF, which could be originated from the decomposition of the LiTFSI salt, the ether solvent, and the LiNO3addi?tive [12, 44]. This layer is very thin at the 1st cycle and not uniformly covered on the surface as Li metal can be detected on the surface, and the peak intensity of SEI com?ponents decreases with the increasing of the depth (except the Li2O, which could come from the reaction of the Li?CNT with dissolved O2/CO2in the electrolyte and decom?position of LiNO3[44-46]). The thickness of the SEI layer grows fast with cycles while the components stay almost the same. The intensity of the Li metal detected on the sur?face of the Li?CNT negative electrode is much weaker at the 10th cycle (Fig. S5a1-d1) and disappears at the 50th cycle (Fig. 5a4-d4) (no signals even after the 30?min Ar sputtering), and the relative intensities of the LiNxOy,Li2CO3, Li2O, and LiF get stable after 10 cycles and present no obvious variation during the 30?min Ar sputtering. The SEI of the cell after the 1st cycle in the electrolyte with a single LiPF6additive is also very thin and mainly composes LiF, LixPOyFz, poly(DOL), organic carbonate, and Li2O(Fig. 5a2-d2). As shown in Fig. 5a5-d5, the relative content of the LixPOyFzand poly(DOL) increase, while that of the LiF decrease with cycling. The organic carbonate compo?nent seems only present on the top surface layer of the SEI.

Fig. 4 a-d SEM images of the Li?CNT electrode before (a) and after 50 cycles at a current density of 6 mA cm-2 in electrolytes with a single LiNO3 additive (b), LiPF6 additive (c), and dual?salt additives of LiPF6 and LiNO3 (d)

The SEI formed on the Li?CNT cycled in the ether elec?trolyte with dual?salt additives of LiPF6and LiNO3exhibits distinct components. As shown in Fig. 5a3-d3, after the 1st cycle, the surface layer of the Li?CNT electrode includes the residual of LiPF6(at 688 eV in the F 1s spectrum) [47]and its decomposition product LixPOyFz[26] (at 686.2 eV on the Li 1s spectrum), a small amount of LiF (684.8 eV on the F 1s spectrum), and prominent poly(DOL) signal (at 291 eV on the C 1 s and 534.5 eV on the O 1s spectra). This means that LiPF6may induce the ring?opening polymeriza?tion of the DOL solvent to form polyether products [22].The SEI layer is quite thin after the 1st cycle, as the intensity of the poly(DOL) decreases gradually during the Ar etch?ing. However, the SEI grows and gets thick enough after the 10th (Fig. S5a2-d2) and 50th cycle (Fig. 5a6-d6), where no intensity variation can be observed for the SEI component during the 30?min Ar etching. The LiF/LixPOyFzcompo?nents formed with the help of the LiPF6additive could guar?antee the mechanical strength and ionic conductivity of the SEI [26, 48, 49], while the organic polyether has better vol?ume tolerance ability than inorganic salts components such as lithium alkyl and lithium carbonate that formed under a single LiNO3additive [24, 50]. This could be the reason that a trace amount of LiPF6additive can significantly improve the cycle performance of the Li?CNT negative electrode.

The different SEI chemistry of the Li?CNT electrodes after 50 cycles in ether?based electrolytes with a single LiNO3addi?tive and dual?salt additives of LiPF6and LiNO3has also been observed at the nano?scale by TOF?SIMS, which is a highly surface?sensitive technique with ultrahigh chemical selectiv?ity. As shown in Fig. 6a2 and b2, a distinguishable PO-and PO2-signal appears in the Li?CNT electrode cycled with dual?salt additives of LiPF6and LiNO3, which confirms the observation of the LixPOyFzcomponent in the XPS spectra.The content of C2HO-(representing organic SEI components that come from the solvent decomposition) on the Li?CNT electrode cycled with a single LiNO3additive was relatively higher than that cycled with dual?salt additives of LiPF6and LiNO3(Fig. 6a1 and b1), indicating that the addition of LiPF6additives can inhibit the decomposition of the organic sol?vents. Last but not the least, much higher LiO-and LiF2-sig?nals can also be observed on the Li?CNT electrode cycled with a single LiNO3additive, revealing the severe decomposi?tion of the ether solvent and the LiTFSI salt.

Fig. 5 a-d Li 1s, F 1s, C 1s, and O 1s XPS depth profiles (etching time: 0 min, 10 min, 20 min, and 30 min) of the Li?CNT electrodes after dif?ferent cycles in electrolytes with a single LiNO3 additive (a1-d1, a4-d4), LiPF6 additive (a2-d2, a5-d5), and dual?salt additives of LiPF6 and LiNO3 (a3-d3, a6-d6)

Fig. 6 a, b TOF-SIMS depth profiles and distributions of PO-, PO2-, C2HO-, LiO-, and LiF2- species on the surface of the Li?CNT electrodes after 50 cycles in electrolytes with a single LiNO3 additive (a1, b1) and dual?salt additives of LiPF6 and LiNO3 (a2, b2)

4 Conclusions

We demonstrated that the combined use of LiPF6and LiNO3additives in an ether?based electrolyte can significantly improve the cycling performance and rate capability of the Li?CNT negative electrode. The LiNO3additive can generate inorganic products like LiNxOy, which have good mechani?cal strength, while the LiPF6additive can help to induce the ring?opening polymerization of the DOL solvent to form polyether with good volumetric variation tolerance. These products together form an ionic conductive and robust SEI layer on the surface of the Li?CNT negative electrode. As a result, the Li?CNT||LFP cells with limited lithium excess(N/P = 2) has obtained an average cycling CE as high as 99.30% under a current density of 2.5 mA·cm-2.

AcknowledgementsThis research was financially supported by the National Natural Science Foundation of China (Grant nos.21625304 and 21733012), and the Ministry of Science and Tech?nology (Grant No. 2016YFA0200703).

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Supplementary InformationThe online version contains supplementary material available at https:// doi. org/ 10. 1007/s40820? 021? 00633?3.