I. INTRODUCTION
Lithium-ion batteries are found in many portable applications, providing stored energy for use. Although lithium-ion batteries meet the majority of the demands put on them by current applications, emerging applications such as electric vehicles and grid-scale energy storage requires improvements in aspects such as safety, cost, energy density, and high-current performance (Tarascon and Armand, Reference Tarascon and Armand2001; Goodenough and Kim, Reference Goodenough and Kim2011). The cathode plays an essential role in the performance of a lithium-ion battery and often is the limiting factor in performance parameters. The major reason the cathode is the limiting factor is because it is the lithium source and its capacity (reversible lithium content) is lower than that provided by the widely used graphite anode. The cathode has been continuously improved by researchers and industry to deliver the above-mentioned improvements.
The first commercialized lithium-ion battery by SONY in 1991 (Nagaura and Tozawa, Reference Nagaura and Tozawa1990), consisted of a LiCoO2 cathode with a graphite anode. Recently new cathode chemistries have been developed and commercialized both for specialized applications such as electric vehicles and to replace the more widespread use of LiCoO2 cathodes, for example LiFePO4 (Padhi et al., Reference Padhi, Nanjundaswamy and Goodenough1997) and LiMn2O4 (Thackeray et al., Reference Thackeray, de Kock, Rossouw, Liles, Bittihn and Hoge1992). Notably, a number of cathodes adopting a similar layered type R $\overline 3 $m structure are found to alleviate some of the issues with the LiCoO2 cathode. These cathodes include LiNi1/3Co1/3Mn1/3O2 with varying ratios of Li:Ni:Co:Mn and Al-doped Li(NiCo)O2 (Dolotko et al., Reference Dolotko, Senyshyn, Muhlbauer, Nikolowski and Ehrenberg2014). Reduction in the Co content of these cathodes reduces cost and the environmental impact as Co is a toxic element. This is particularly true if similar or superior electrochemical performance can be delivered. Although the starting cathodes have been thoroughly characterized the question remains: what does the inclusion of Ni, Co, Mn, and Al do to the structural evolution as a function of charge/discharge? For example, do the cathodes show continuous expansion/contraction during charge/discharge or do they differ?
A non-destructive method to probe cathode structural evolution in commercial 18650 or alternate-shaped batteries is time-resolved in situ neutron powder diffraction (NPD). Early studies focused on essentially in situ NPD patterns collected over extended periods of time with batteries equilibrated at a particular state of charge (Rodriguez et al., Reference Rodriguez, Ingersoll, Vogel and Williams2004; Senyshyn et al., Reference Senyshyn, Muhlbauer, Nikolowski, Pirling and Ehrenberg2012). Recent work has taken advantage of the improvements in neutron sources and detectors to undertake time-resolved measurements particularly on LiCoO2||graphite batteries, revealing the presence of new phases during charge/discharge, for example spinel LiCoO2 (Sharma et al., Reference Sharma, Peterson, Elcombe, Avdeev, Studer, Blagojevic, Yusoff and Kamarulzaman2010; Sharma and Peterson, Reference Sharma and Peterson2012), evaluating the time-dependent nature of structural evolution (Wang et al., Reference Wang, An, Cai, Feng, Nagler, Daniel, Rhodes, Stoica, Skorpenske, Liang, Zhang, Kim, Qi and Harris2012), and determining the influence of overcharging on the structure and electrochemical properties of the electrodes (Sharma and Peterson, Reference Sharma and Peterson2013b). Thus, time-resolved in situ NPD is a powerful tool to study the evolution of electrodes in commercial lithium-ion batteries.
Recently, an NPD study investigated cation-site mixing in Li(Ni0.5Mn0.3Co0.2)O2 cathodes in 18650 batteries with in situ NPD using collection times of 30 min per pattern and analyzed by single-peak fitting of the cathode 003 and 217 reflections. The structural evolution was analyzed using Rietveld analysis of equilibrated cathodes collected for 4 h at a desired state of charge of the battery. This work, based on data for the cathode equilibrated at a particular state of charge, illustrated a change in the lattice parameter trend during charge. The volume contracts for most of charge and contracts at a faster rate near completion and this was related to the cation mixing in the cathode (Dolotko et al., Reference Dolotko, Senyshyn, Muhlbauer, Nikolowski and Ehrenberg2014). This motivated our work where we focus here on a comparison of the evolution of the 003 reflections of the Li(Ni,Co,Mn)O2 (CGR) and Li(Ni,Co,Al)O2 (NCR) electrodes during a similar charge/discharge cycle to illustrate the anomaly near the charged state. The 003 reflection is the stacking axis of the layered structure and is expected to show the largest change during charge/discharge. By comparing the above-mentioned two commercially available electrodes, this work details the different evolution and provides rationale for their performance.
II. EXPERIMENTAL
Commercial lithium-ion batteries (18 650) were obtained commercially. The batteries were denoted as CGR and NCR, which corresponded to the compositions CGR and NCR, respectively. These batteries are sold at a state of charge ranging from 50 to 60%. In situ NPD data were collected on WOMBAT (Studer et al., Reference Studer, Hagen and Noakes2006), the high-intensity powder diffractometer, at the Open Pool Australian Light-water (OPAL) reactor facility at the Australian Nuclear Science and Technology Organisation (ANSTO), as per our previous work (Sharma et al., Reference Sharma, Peterson, Elcombe, Avdeev, Studer, Blagojevic, Yusoff and Kamarulzaman2010, Reference Sharma, Du, Studer, Guo and Peterson2011a, Reference Sharma, Reddy, Du, Adams, Chowdari, Guo and Peterson2011b, Reference Sharma, Guo, Du, Guo, Wang, Wang and Peterson2012, Reference Sharma, Yu, Zhu, Wu and Peterson2013; Sharma and Peterson, Reference Sharma and Peterson2012, Reference Sharma and Peterson2013a, Reference Sharma and Peterson2013b; Hu et al., Reference Hu, Sharma, Chiang, Su, Peterson, Hsieh, Lin, Chou, Shew and Lee2013; Pang et al., Reference Pang, Sharma, Peterson, Shiu and Wu2014). The batteries were placed in a neutron beam of wavelength 2.4105(3) Å, determined using the Al2O3 NIST SRM 676, and data collected in the range 24° ≤ 2θ ≤ 144. NPD data were acquired every 5 min during charge/discharge cycling. NPD data correction, reduction, and visualization were undertaken using the program LAMP (Richard et al., Reference Richard, Ferrand and Kearley1996). Rietveld analyses were carried out using the GSAS (Larson and Von Dreele, Reference Larson and Von Dreele1994) suite of programs with the EXPGUI (Toby, Reference Toby2001) interface.
During the in situ NPD experiment the electrochemical cell was cycled in galvanostatic–potentiostatic mode as recommended by the manufacturer between 2.5 and 4.2 V using an Autolab potentiostat/galvanostat (PG302N) under ambient conditions, with the external temperature maintained at 22.5 °C. Cycles were performed with varying current from 0.5 to 2 A. Information regarding the battery composition, performance, and details are derived from the information sheet provided by the manufacturer. These batteries are rated to deliver 2.25 Ah (CGR) and 3.1 Ah (NCR) using constant current charging until 4.2 V and holding at 4.2 V using a tapering current (potentiostatic step).
III. RESULTS AND DISCUSSION
The CGR cathode composition is quoted as LiNi1/3Co1/3 Mn1/3O2 in some commercial datasheets but often referred to as CGR, whereas the NCR cathode composition is only given as a mixture of Ni, Co, and Al where the Al dopant is used to optimize performance. The as-collected NPD patterns for the as-obtained batteries are shown in [Figure 1(a)], and we note a significant background contribution from the hydrogen containing components in the battery [see Sharma et al. (Reference Sharma, Du, Studer, Guo and Peterson2011a) for more details]. The striking feature of these patterns is the similarity of the diffraction patterns in terms of peak positions of both batteries. This arises because the batteries are effectively the same construction (in terms of materials and composition) and are at an approximately equivalent state of charge with the only difference being the cathode composition. To model these in situ patterns the LiNi1/3Co1/3Mn1/3O2 model from Dolotko et al. (Reference Dolotko, Senyshyn, Muhlbauer, Nikolowski and Ehrenberg2014) is used, and the refined lattice parameters are a = 2.855(2) and c = 14.28(2) Å for the first dataset of the CGR battery. The same model was used for the NCR battery by adjusting for composition, removing Mn and placing an initial guess of 5% Al on the transition metal (TM) site, resulting in the lattice parameters a = 2.8264(5) and c = 14.367(5) Å. The NCR lattice is slightly larger in the c-stacking axis but smaller in the ab-plane compared with CGR. The fits are shown in [Figures 1(b) and 1(c)]; it should be noted that these are highly constrained Rietveld refinements as the atomic and profile parameters are refined and fixed, and only the lattice parameters continuously refined. The arrow in [Figure 1(a)] shows the cathode 003 reflection, which between the NCR and CGR datasets changes in intensity, while the position remains effectively the same.
Highly constrained Rietveld analyses were performed to identify the remaining battery components, and five components were identified using the starting structural models of the cathode(s), graphite, LiC6, Cu, and Al [Figures 1(b) and 1(c)]. The cathode adopts R $\overline 3 $m symmetry with Li layers and layers of MO6, where M = Ni, Co, Mn, and Al and in some instances the MO6 layers can show some long-range ordering of the cations and/or contain Li+ (Dolotko et al., Reference Dolotko, Senyshyn, Muhlbauer, Nikolowski and Ehrenberg2014). In the case of Li(Ni0.5Mn0.3Co0.2)O2, detailed structural analysis reveals Ni in the Li layers (3a site) and Li in the MO6 layers (3b site) and this interchange is in part facilitated by the similar ionic radii of the Li and Ni cations (Dolotko et al., Reference Dolotko, Senyshyn, Muhlbauer, Nikolowski and Ehrenberg2014). This work shows that lithium is extracted predominantly from the 3a sites and that the TM 3b site contains lithium until at least ~70% state of charge of the battery, after which lithium is no longer present at the TM 3b site. Notably the removal of lithium from the TM 3b site occurs close to a large contraction of the c-lattice parameter during charge (Dolotko et al., Reference Dolotko, Senyshyn, Muhlbauer, Nikolowski and Ehrenberg2014), opposing the trend during charge.
The evolution of the 003 reflection of the cathodes is shown in Figure 2 illustrating changes in the 2θ value during charge/discharge. Multiple charge/discharge cycles are shown in Figure 2, and the 003 reflection over the course of cycling was fitted with a single Lorentzian peak. The CGR 003 and NCR 003 reflection position, integrated intensity, and full-width at half-maximum (FWHM) are shown in Figures 3 and 4, respectively in a comparable full-charge/discharge cycle of these batteries.
If we consider the CGR cathode first, then there is a gradual increase in integrated intensity and decrease in FWHM during charge (Figure 3). Although the reflection position shows a decreasing trend for most of charge and stabilizes near the charged state and remains at this value during the potentiostatic step and the initial stages of discharge. During discharge all three fit parameters show the reverse behavior. The stabilized region during the potentiostatic step does show a slight decrease in the 003 reflection position similar to that reported for a potentiostatic hold step for Li1.2Co0.1Mn0.55Ni0.15O2 (Mohanty et al., Reference Mohanty, Kalnaus, Meisner, Safat, Li, Payzant, Rhodes, Wood and Daniel2013) and in Li(Ni0.5Mn0.3Co0.2)O2 (Dolotko et al., Reference Dolotko, Senyshyn, Muhlbauer, Nikolowski and Ehrenberg2014). However, the response or stabilization in the CGR battery studied here shows a less dramatic or smaller change near the charged state relative to the larger contraction near the charged state in Li(Ni0.5Mn0.3Co0.2)O2 (Dolotko et al., Reference Dolotko, Senyshyn, Muhlbauer, Nikolowski and Ehrenberg2014). This may be related to our work probing more of a kinetic response in the cathode because of the shorter collection times, 5 relative to 30 or 240 min, or differences in cathode composition.
Comparing the NCR cathode with the CGR cathode, the major difference in behavior is found near the charged state, where the 003 reflection position changes from a continuously decreasing trend during charge, reversing in sign and increasing during the potentiostatic step. On initiation of the discharge step the reflection position decreases until it reaches a minimum position and then increases for the reminder of discharge. The behavior of the integrated intensity and FWHM is also different in the NCR relative to CGR cathode, with maximum FWHM and minimum integrated intensity observed at the charged and discharged states.
The 003 reflection is indicative of the changes in the c-lattice parameter, representing the stacking axis of the layered structure. During charge the decrease in the reflection position, corresponding to an increase in the c-lattice parameter, is a consequence of the lithium extraction from the lithium layers and the repulsion of the overall negatively charged TM containing octahedral layers, for example TM 2+O6−4 to TM 4+O6−2 (Sharma et al., Reference Sharma, Peterson, Elcombe, Avdeev, Studer, Blagojevic, Yusoff and Kamarulzaman2010). This accounts for the capacity of the battery during this period. Near the charged state and the potentiostatic step the stabilization for CGR and decrease in c-lattice parameter for NCR batteries suggests an alternative mechanism is occurring to give rise to capacity. This stabilization and/or decrease in the c-lattice parameter are likely to be related to the removal of Li from the TM layer in these cathodes as proposed (Dolotko et al., Reference Dolotko, Senyshyn, Muhlbauer, Nikolowski and Ehrenberg2014). It is interesting to note the differences in the magnitude of change near the charged state, where NCR shows a contraction in the lattice, whereas CGR shows stabilization. The differences in these cathodes relate to the quantity of Ni and Co and therefore to the relative amount of Ni on the Li layers and Li in the TM (Ni) layers, and the presence of Mn or Al. In order for the TM layers to come closer (contract as observed in NCR), the overall negative charge on the TM layers must be counteracted by an attractive component between the layers or a reduction of the overall negative charge. Speculatively this may be because of Li+ in the TM layer exchanging for Ni2+ in the lithium layer, reducing the overall negative charge of the TM layer and leading to a contraction. Although alternate explanations are possible, future and modified in situ neutron diffraction experiments (for example, extending the potentiostatic step) are underway to determine the precise origin of these differences.
IV. CONCLUSION
Here we illustrate how in situ NPD allows comparison of the structural evolution of electrodes in lithium-ion batteries and how different chemistries in the cathode evolve during charge/discharge. The CGR and NCR cathodes adopt similar structures and c-lattice parameter evolution during most of charging, with the gradual expansion experienced ceasing near the charged state for both electrodes. The CGR electrode stabilizes and shows little change for the reminder of charge and during the potentiostatic step, whereas the NCR electrode contracts. This suggests that the extent of the Li/Ni cation mixing, the Ni and Li contents of the electrode, and the presence of Al or Mn influence the cathode lithium extraction mechanism in differing ways near the charged state and subsequent discharge behavior. Decoupling the influence of each aspect may allow the design of better cathodes.
ACKNOWLEDGEMENT
Dr. Sharma acknowledges AINSE Ltd for providing support through the research fellowship scheme.