XPS Study of the Interface Evolution of Carbonaceous Electrodes for Li-O₂Batteries during the 1st Cycle

Abstract: The surface chemistry of the commonly employed positive electrode substrate Super C65 carbon was investigated during the 1 st cycle of a Li-O 2 battery with a typical ether electrolyte (0.2 M LiTFSI in Diglyme) by performing in situ online electrochemical mass spectrometry (OEMS), ex situ scanning electron microscopy (SEM), X-ray diffraction (XRD) and X-ray Photoelectron Spectroscopy (XPS). During discharge, a nanometer-thin (< 5 nm) layer of Li 2 O 2 forms homogeneously throughout the electrode before it is p… Show more

“…In addition, they contain other bonds, CÀF x (292.2 AE 0.5 eV) and RÀCÀC( 285.1 eV), ( Figure S5 ba nd e). [43,50] The presence of CÀF x bonds in all samples is likely ar esult of the electrolyte interaction with Nafion binder used in this study.T he O1 ss pectra of cycled FeS-C electrode show am ajor peak at 533.2 eV for the CÀOb ond, am inor peak at 532.0 eV for ÀCO 3 or Li 2 CO 3 ,a nd an egligible Li 2 O 2 peak at 531.5 eV,w hich assertst he maximum oxidation of Li 2 O 2 compound even at the 100th cycle (Figure 5g). [44,50] The cycled MC and FeS cathodes ( Figure S5 ca nd f) present ah igh intensity of Li 2 CO 3 at 532.1 AE 0.2 eV,w hich suggestst he cause of increased high overpotential at the 100th cycle.…”

“…The C1ss pectra of the discharged FeS-C cathode (Figure 5f) show am ajor peak at 284.5 eV for CÀCb onds and other minor peaks related to CÀO, C=O, ÀCO 3 ,a nd CF x . [43,44] Similarly,t he discharged MC and FeS cathodes show am ajor peak at 287.0 AE 0.3eVf or C=O, which is possibly the result of the decomposition of ether solvent( TEGDME)o nt heir cathodes urface. The O1s spectra of the dischargedF eS-C, MC, and FeS cathodes how as ignificant peak at 531.5 AE 0.3eVf or Li 2 O 2 formation, accompanied by other species, such as ÀCO 3 ,C =O, and CÀOf unctional groups (Figures 5e and S5 ca nd f).…”

Dual Heteroatom‐Doped Carbon Nanofoam‐Wrapped Iron Monosulfide Nanoparticles: An Efficient Cathode Catalyst for Li–O₂ Batteries

“…In addition, they contain other bonds, CÀF x (292.2 AE 0.5 eV) and RÀCÀC( 285.1 eV), ( Figure S5 ba nd e). [43,50] The presence of CÀF x bonds in all samples is likely ar esult of the electrolyte interaction with Nafion binder used in this study.T he O1 ss pectra of cycled FeS-C electrode show am ajor peak at 533.2 eV for the CÀOb ond, am inor peak at 532.0 eV for ÀCO 3 or Li 2 CO 3 ,a nd an egligible Li 2 O 2 peak at 531.5 eV,w hich assertst he maximum oxidation of Li 2 O 2 compound even at the 100th cycle (Figure 5g). [44,50] The cycled MC and FeS cathodes ( Figure S5 ca nd f) present ah igh intensity of Li 2 CO 3 at 532.1 AE 0.2 eV,w hich suggestst he cause of increased high overpotential at the 100th cycle.…”

“…The C1ss pectra of the discharged FeS-C cathode (Figure 5f) show am ajor peak at 284.5 eV for CÀCb onds and other minor peaks related to CÀO, C=O, ÀCO 3 ,a nd CF x . [43,44] Similarly,t he discharged MC and FeS cathodes show am ajor peak at 287.0 AE 0.3eVf or C=O, which is possibly the result of the decomposition of ether solvent( TEGDME)o nt heir cathodes urface. The O1s spectra of the dischargedF eS-C, MC, and FeS cathodes how as ignificant peak at 531.5 AE 0.3eVf or Li 2 O 2 formation, accompanied by other species, such as ÀCO 3 ,C =O, and CÀOf unctional groups (Figures 5e and S5 ca nd f).…”

Dual Heteroatom‐Doped Carbon Nanofoam‐Wrapped Iron Monosulfide Nanoparticles: An Efficient Cathode Catalyst for Li–O₂ Batteries

“…Some papers 23,27 have reported very large gravimetric discharge capacities of 5,000-10,000 mAh/g-carbon even though the areal loading of air-electrode material was less than 1 mg/cm 2 . Actually, these gravimetric values correspond to rather small areal capacity of less than 2-3 mAh/cm 2 , [28][29][30][31][32][33][34][35] comparable to that of conventional lithium ion batteries. This low loading might result in the low energy density of practical LAB cells.…”

Electrochemical Properties of Large-Discharge-Capacity Air Electrodes with Nickel Foam Sheet Support for Lithium Air Secondary Batteries

“…The single component Li1s spectra at ~ 55 eV and O1s spectra at ~ 532 eV confirm the deposition of Li 2 O 2 as the major DC product. 36 Besides, The O1s spectra show additional peaks at > 532 eV that can be assigned to -CO 3 , -CO or SO 2 species resulting from parasitic reactions or adsorbed electrolyte residues on the deposited Li 2 O 2 and additionally multiple components in the deconvoluted C1s spectra also indicate presence of several functionalities, such as C-C, CH x , CO x etc., in the discharged electrodes. 36 Consistent with the XPS results, the FTIR spectra of the discharged CMK-3 and N-CMK-3 electrodes in Figure S9 identify Li 2 CO 3 and Li-carboxylates to be the parasitic products during DC.…”

“…36 Besides, The O1s spectra show additional peaks at > 532 eV that can be assigned to -CO 3 , -CO or SO 2 species resulting from parasitic reactions or adsorbed electrolyte residues on the deposited Li 2 O 2 and additionally multiple components in the deconvoluted C1s spectra also indicate presence of several functionalities, such as C-C, CH x , CO x etc., in the discharged electrodes. 36 Consistent with the XPS results, the FTIR spectra of the discharged CMK-3 and N-CMK-3 electrodes in Figure S9 identify Li 2 CO 3 and Li-carboxylates to be the parasitic products during DC. There can be different ways for the formation of parasitic side products in Li-Air cells where, in addition to electrolyte and electrode decomposition, the CO 2 (0.04%) present in air can also undergo electrochemical reaction during DC to directly produce Li 2 CO 3 as an undesired product.…”

Nanoconfined growth of lithium-peroxide inside electrode pores: a noncatalytic strategy toward mitigating capacity–rechargeability trade-off in lithium–air batteries