1. Introduction
Elucidation of ageing mechanisms of lithium ion batteries (LiBs) has become an important issue because of their increasingly demanded applications [1] - [4] . Therefore, the knowledge of ageing reactions leading to either capacity fading or increase of resistance is mandatory to keep a long lifetime of LiBs. However, it is difficult to give an exhaustive picture of all the ageing reactions because of a large variety of LiBs. There are two types of ageing situation, charge/discharge cycling (cycling ageing) and storage (calendar ageing) [5] . The former ageing results in the effects in volume variations and concentration gradients, while the latter ageing results in the reactions of the active electrode materials [3] [6] .
Recently, some studies have been focused on ageing effects on the cathode materials because the materials affect significantly performance parameters and lifetime of LiBs [7] [8] . The changes in the cathode due to the ageing processes are recognized as: (a) ageing of active materials, (b) degradations of binder and conducting agents, (c) corrosion of current collector, (d) oxidation of electrolyte composition and film formation on the surface of active materials, and (e) interaction of ageing products with negative electrode. These effects do not occur separately and therefore cannot be analyzed independently each other. In general, the ageing processes of the cathode materials can originate from changes in structure and chemical decomposition as well as film formation at the interface between active materials and electrolyte [9] [10] .
Electrochemical impedance spectroscopy has been employed as a fast, non-destructive and reliable technique to elucidate ageing behaviors of LiB cells [11] [12] . In particular, it is effective in characterizing reaction pro- cesses occurring in the cells, such as changes of particle-to-particle contacting resistance [13] and charge- transfer resistance [14] [15] in active materials and electrolyte as well as through their interface. It is also sensitive to increase in cell impedance due to various reactions such as oxidation of conductive particles, binder decomposition, loss of contact to conductive particles, micro-cracking, structural disordering in active materials, and film formation on the surface of active materials. However, this technique cannot analyze directly the ageing behaviors of electrode or electrolyte, separately. Moreover, structural and compositional analysis techniques such as x-ray diffraction,
Raman
scattering, IR absorption and TEM observation are used to local characterization of electrodes or separator, but cannot characterize the ageing behaviors of positive or negative electrode as a whole. In order to realize a balance between lifetimes of electrode, electrolyte and separator, it is necessary to provide a technique to separately measure ageing behaviors of these LiB parts.
Since elastic properties of materials depend sensitively on internal friction due to lattice distortion and its thermodynamic behaviors, elastic parameters can be anticipated as effective indicators for characterization of ageing behaviors of the LiB electrode as a whole.
In this study, we measured both resonance frequency and internal friction of positive-electrode reed samples as a function of temperature. The results indicated that the charge/discharge cycling causes decrease in the resonance frequency and increase in the internal friction of the positive electrode. Our results also indicated that mechanical parameter is an effective measure to characterize the ageing behaviors of the LiB electrodes. Finally, we discussed mechanisms of the internal friction on the positive electrode through comparison with the measurement results of the negative electrode.
2. Experimental
Two kinds of LiBs, not filled and filled with electrolyte, having dimensions of 230 × 200 ×
7 mm
3, were obtained from Nissan Motor Co., Ltd. The positive electrode of the un-filled battery was cut to the reed samples having dimensions of 5.0 × 0.19 × l mm3, where l is 27, 29, 31 and
39 mm
. Here, the length l corresponds to resonance frequency of 75.8, 64.7, 53.3 and 38.6 Hz at room temperature, respectively. On the other hand, the filled battery was prepared by charge/discharge for 150 cycles at 20% depth-of-discharge (DOD), and was open- ed in inert gas atmosphere. The positive electrode of the filled battery after the charge/discharge cycling was also cut to the reed samples with the same dimensions.
The positive electrode of the battery is composed of a sandwich structure of the active material film and current collector (aluminum foil) as shown in Figure 1(a). The active material was coated on either side of the
Al
foil at the same thickness of 80 μm where the
Al
foil is 30 μm thick. The active material film is composed of lithium manganese oxide (LiMn2O4) and lithium nickel cobalt aluminum oxide (LiNiCoAlO2). These active materials were coated using polyvinylidene difluoride (PVdF, -CH2CF2-) binder. In order to enhance conductivity of the PVdF binder, carbon black particles (3 - 500 nm in diameter) and graphite nanoplatelets were added into the binder as conducting fillers. Prior to the measurements of elastic parameters, the positive electrodes were characterized by compositional and structural analyses using transmission scanning electron microscope (TEM, JEM ARM
200F
) and electron probe micro analyzer (FE-EPMA, JXA
-8530F
).
The measurement system of the elastic parameters of the positive electrode is shown in Figure 1(b). The reed sample was set in a copper box equipped in a vacuum chamber under the residual gas pressure below 3 × 10−4 Pa. One end of the reed sample was fixed on the copper box to assure an electrical ground lead and to control its temperature. An alternating voltage with variable frequency and amplitude was applied to the free end of the sample to vibrate it at its resonance frequency.
The displacement of the free end of the reed sample during free decay vibration was measured using a laser/CCD camera system with 10 nm accuracy as a function of time. Temperature of the sample set in the copper box was changed from 100 K to 400 K with a rate of 0.2 Kmin−1 and in a stepwise with 5.0 K step.
The amplitude of the free end of the sample during the free decay vibration decreases exponentially with time t, due to an internal friction in the sample. Here, α is the decay constant. Internal friction is determined as where f is the resonance frequency of the reed sample.
3. Results and Discussion
3.1. Experimental Results
Figure 2 shows the element mapping results on the surface of the active materials. The mapping patterns for Co and Ni elements are same, suggesting the Co and Ni elements form a compound. The mapping pattern of Mn appears to be reversed from that of Co or Ni. This result suggests that Mn forms another compound avoiding Co and Ni. Also, the overlap in the mapping patterns of O with that of Mn, Co and Ni suggests the existence of manganese and cobalt/nickel oxides in the active materials. The mapping patterns of C and F elements are different from that of Mn, Co and Ni. F may come from the PVdF binder and C from both the PVdF and the carbon black in the binder.
The results of TEM observation and electron beam diffraction of the active materials of the positive electrode are shown in Figure 3. TEM images in both bright field and dark field mode are shown in Figure 3(a) and Figure 3(b). There are four types of areas in the images, Mn, Co/Ni, PVdF and Al areas. It is confirmed in the TEM observation that the PVdF binder was filled into the space between Mn and Co/Ni particles and Al foil. A large number of hollow voids with large surface area are observed in the PVdF binder area as seen in Figure 3(a) and Figure 3(b). The electron beam diffraction patterns from the Mn and Co/Ni areas are shown in Figure 3(c) and Figure 3(d). The Mn and Co/Ni particles are confirmed to have crystallographic structures of LiMn2O4 and LiNiCoAlO2 based on these electron beam diffraction patterns.
The element distributions on the area in Figure 3, mapped by energy dispersive x-ray spectroscopy (EDX) are shown in Figure 4. The result of element mapping using EDX indicates that the particles of manganese oxide as well as cobalt/nickel oxide are coated by the PVdF binder and are deposited on the surface of the Al foil. The results for the element distribution in the positive electrode are consistent to that measured by EPMA as shown in Figure 2.
We also confirmed the presence of lithium atom in the active material by electron energy loss spectroscopy (EELS) on selected area electron diffraction (SAED) mode, and the result obtained is shown in Figure 5. The lithium atom is detected at the LiMn2O4 area only.
(a) (b)
Figure 1. (a) Schematic diagram of the positive-electrode structure; (b) Elastic parameter measurement system of the positive-electrode reed sample.
Figure 2. Element mappings on the surface of the active materials of the positive electrode.
Figure 3. EM images: (a) in bright field mode, (b) in dark field mode as well as electron beam diffraction patterns, (c) in Mn area, and (d) in Co/Ni area at the active materials/Al foil interface of the positive electrode.
High-resolution transmission electron microscopy (HRTEM) image of the PVdF binder is shown in Figure 6. The carbon black crystals can be observed in the PVdF binder, and a graphite-like crystal particle with spacing of 0.335 nm can be seen around the center area in the figure.
Based on the above experimental results, we can conclude that the active materials of the positive electrodes are composed of LiMn2O4 and LiNiCoAlO2 micro-crystals. These micro-crystals are coated by the PVdF binder containing carbon black which improves electrical conductivity of the PVdF binder.
Figure 4. Element mappings at the active materials/Al foil interface by using EDX spectroscopy.
Figure 5. EELS spectrum on selected area electron diffraction mode in the manganese oxide area at the active materials/Al foil interface of the positive electrode.
Figure 6. HRTEM image of the PVdF binder in the active materials of the positive electrode.
The resonance frequencies of the positive-electrode reed samples with lengths of 27, 29, 31 and
39 mm
are plotted as a function of temperature in Figure 7. The resonance frequency decreases with increasing temperature. A sharp decrease of the frequencies appears at ~150 K and ~240 K for all reed samples. In general, the sharp decrease in the temperature-dependent resonance frequency results in a peak on the temperature-dependent internal friction.
The internal frictions of the positive electrode samples are plotted in Figure 8 as a function of temperature. The internal friction changes strongly with temperature in the range of 100 - 400 K. At high temperature side, the increase in may be related to a α-relaxation process occurring in the PVdF binder at 413 K [16] . Two peaks at low temperature side at ~150 K and ~240 K correspond to sharp decreases in the temperature-dependent resonance frequencies of the samples. The peaks are symmetric and sharp. It may be due to a surface-related relaxation (s-relaxation) process for the peak at ~150 K as well as a β-relaxation process in the PVdF binder for the peak at ~240 K, respectively [17] . These relaxations are thermally activated processes because the internal friction peaks shift to higher temperatures with increasing resonance frequency.
Figure 7. Resonance frequencies of the positive-electrode reed samples with lengths of 27, 29, 31 and
39 mm
as a function of temperature.
Figure 8. Internal frictions of the positive-electrode reed samples with lengths of 27, 29, 31 and
39 mm
as a function of temperature.
To obtain the physical parameters of these thermally activated processes we tried to explain the internal friction by means of the
Debye
model. The contribution of a relaxation process to the internal friction is given by, where φ is a constant corresponding to the relaxation strength that not depends on temperature, the resonance frequency of the reed sample and t the relaxation time of the thermally activated process. Here, the t generally follows an
Arrhenius
law, where is a constant and the activation energy of the thermally activated process. When the resonance frequency of the reed sample is equal to, , through changing temperature, the internal friction becomes maximum. The Arrhenius plots of the relaxation rate, , for two thermally activated processes at ~150 K and ~240 K are shown in Figure 9 as a function of inverse temperature. We obtain two activation energies of 208 meV for the process at ~240 K and 104 meV for the process at ~150 K from slopes of the
Arrhenius
plots in this figure. The results are consistent with the symmetry of two peaks in Figure 8 that these processes result from simple
Debye
relaxation with single and.
The internal friction of the positive electrode would be occurred in the LiMn2O4 and LiNiCoAlO2 microcrystals, the PVdF binder, the carbon black and the
Al
foil. In order to clarify the origins of the internal friction, it is significant to characterize the effects of charge/discharge process on the internal friction. We have measured the internal friction of the positive electrode after the charge/discharge of 150 cycles. The charge/discharge cycling, the voltage profile is shown in Figure 10. The charging was carried out at a constant current (CC) of
3 A
,
2 A
,
1 A
and
0.5 A
, respectively, for a limit cell voltage of 4.15 V and a maximum charging time of 3.5 hr, as marked by “C” ranges in the figure. On the other hand, the discharging was executed through a resistance of 1.1 Ω at room temperature for 20% DOD, corresponding to a minimum cell voltage of 3.84 V, as marked by “D” ranges in the figure.
After the charge/discharge of 150 cycles the battery was opened and its positive electrode was washed using N-methyl-2-pyrrolidone solvent in an inert gas atmosphere in order to make the electrolyte clean. The positive electrode which had been washed was cut to reed samples with lengths of 27, 29, 31 and
39 mm
, respectively. The resonance frequencies of the reed sample with length of
39 mm
before and after the charge/discharge cycling are plotted in Figure 11 as a function of temperature. The resonance frequency decreases with increasing temperature, and drops markedly at temperatures of ~150 K and ~240 K. For example, the resonance frequencies decrease 17% at 150 K and 19% at 240 K after the charge/discharge cycling.
The internal friction of the positive electrode is also sensitive to the charge/discharge process. The internal frictions of the reed sample with length of
39 mm
before and after the charge/discharge of 150 cycles are shown in Figure 12 as a function of temperature. Changes on the internal friction after the charge/discharge cycling, the increase of the value and the shift of the peaks, can be seen in the figure. Intensities of the peaks at 150 K and 240 K increase 40% and 16% after the charge/discharge cycling. The increase in the
Figure 9. Arrhenius plots of the relaxation rate, , for two relaxation processes occurring at ~150 K and ~240 K with activation energies of 104 meV and 208 meV.
Figure 10. The voltage profile of the LiB cell during the charge/ discharge cycling. The “C” range corresponds to the charge process at constant currents of 3, 2, 1 and
0.5 A
, and the “D” range corresponds to the discharge process for decreasing cell voltage from 4.15 V to 3.84 V through a resistance of 1.1 Ω.
Figure 11. Resonance frequencies of the positive-electrode reed samples with length of
39 mm
before and after the charge/discharge of 150 cycles as a function of temperature.
value indicates that stronger
Debye
absorption appears in the sample after the charge/discharge cycling. It suggests a structure change occurred on molecular level of the active materials. It is well known that the active materials absorb the electrolyte at first charge/discharge cycle of the LiB.
Shifts of the peaks suggest a change in activation energies of the thermally activated relaxation processes. The Arrhenius plots of the relaxation rate, , for the processes at ~150 K and ~240 K after the charge/discharge of 150 cycles are shown in Figure 13 as a function of inverse temperature. The activation energy is 901 meV for the process at ~240 K and 289 meV for the process at ~150 K, respectively. These activation energies become large after the charge/discharge cycling.
Figure 12. Internal frictions of the positive-electrode reed samples with length of
39 mm
before and after the charge/discharge of 150 cycles as a function of temperature.
Figure 13.
Arrhenius
plots of the relaxation rate, , for two relaxation processes occurred at ~150 K and ~240 K in the reed samples after the charge/discharge cycling. Activation energies of 289 meV and 901 meV are observed in the processes at ~150 K and ~240 K.
In order to clarify these relaxation processes which may occur in the active materials, the binder or the
Al
foil, the internal friction of the negative electrode of the same cell after the charge/discharge of 150 cycles was also measured. The negative electrode has a sandwich structure of the active material film and current collector (copper foil), similar to that of the positive electrode as shown in Figure 1(a). Their thicknesses were 60μm for the active material films and 20 μm for the Cu foil. The active materials of the negative electrode are mainly composed of graphite nanoplatelets, carbon black and PVdF binder. The internal frictions of both negative and positive electrode reeds with the same length of
31 mm
are plotted in Figure 14 as a function of temperature. Unlike the results of the positive electrode samples, two new peaks at ~190 K and ~370 K are also observed in addition to the peaks at ~150 K and ~240 K. The peak at ~150 K is weak and that at ~240 K is broad. It may be related to a γ-relaxation process for the peak at ~190 K and an α-relaxation process at ~370 K in the PVdF binder.
We are now in the position to discuss the ageing behaviors and the mechanisms of internal friction appeared in the positive electrode on the basis of the above experimental results.
Figure 14. Internal frictions of both positive and negative electrode reeds with length of
31 mm
as a function of temperature.
3.2. Discussion on Internal Frictions
3.2.1
. Internal Friction on PVdF Binder
The PVdF is a semi-crystalline polymer having α, β, γ and δ crystalline phases [18] - [22] . The α crystalline structure contains trans-gauche-trans-gauche chain conformations in a monoclinic lattice, and is obtained by melt crystallization at temperatures below 433 K [23] [24] . The β crystalline phase can be produced through mechanically drawing α phase materials [23] [25] . The γ crystalline phase can be obtained by crystallization from melt at high pressure or by crystallization from certain solutions such as dimethylacetamide (CH3CON(CH3)2) and dimethylsufoxide ((CH3)2SO) [18] [21] [25] . The δ crystalline phase is usually obtained by poling α phase under high electric field [18] [19] .
In internal friction studies of the PVdF polymer, a number of relaxation processes corresponding to the α, β and γ phase transitions have been observed. The α-relaxation is related to thermal movement processes of the PVdF molecule near the crystalline melting point [16] [17] [26] - [32] . The β-relaxation is due to micro-Brownian motions of the linear chain segments close to the glass transition temperature [16] [17] [28] - [32] . Also, the γ-relaxation is due to thermally-activated local molecular oscillations in the amorphous phase of the PVdF polymer [16] [17] [28] .
Low-temperature internal friction on the PVdF polymer has been reported by Callens et al. [16] [17] . They measured the internal friction spectra of the PVdF polymer by using a torsion pendulum technique. Nine peaks were observed on temperature-dependent internal friction spectra of the PVdF polymer at temperatures of ~140, ~190, ~220, ~236, ~270, ~330, ~350, ~386 and ~413 K in the range of 70 - 450 K. The internal friction process at ~140 K corresponds to a surface-related relaxation process because its relaxation rate is several times as large for PVdF fiber sample as for PVdF bulk sample. In this study as observed in Figure 3, there are a large number of hollow voids in the PVdF binder. The surface of the hollow voids and the interface between the active materials and the PVdF binder can be involved to the surface-related relaxation process. The peak at ~190 K corresponds to the γ-relaxation which can be understood in terms of the cranckshaft or local-mode molecular models based upon molecular motions of small, isolated chain segments within amorphous phase in the PVdF material. The peak at ~220 K is due to the β-relaxation, a glass transition corresponding to the amorphous phase, relating to changes in the chain length distribution. The peaks at ~236 and ~270 K are also related to the β-relaxation and can be explained through the hindering of the molecular motion by the crystallites. The β-related relaxations in the temperature range from 220 K to 320 K depend on vibration mode (longitudinal or shear), molecular structures (molecular weight, molecular weight distribution) and crystallinity [26] . The upper glass transitions, corresponding to the β-relaxations in the amorphous-crystalline interphase, appear in the temperature range of 300 - 330 K. Other relaxations above 330 K are related to the α-relaxation processes corresponding to the phase- melting phenomena. The position of the melting temperature of each crystalline phase of the PVdF polymer has been studied [33] . We also must point out that the melting of γ-conformation occurs at temperatures higher than that of the α and β-conformation. Therefore, the PVdF polymer presents several internal friction peaks linked to the presence of several conformations and crystallites of different sizes on the melting.
As shown in Figure 8 and Figure 14, there are different temperature dependences of the internal friction on the PVdF binders of both positive and negative electrodes. These results indicate that there are different molecular structures, the concentration of the amorphous phase as well as the hollow voids in the PVdF binders of the positive and negative electrodes.
3.2.2
. Internal Friction on LiMn2O4 Microcrystal
LiMn2O4 has spinel crystal structure with cubic symmetry at temperatures above 300 K [34] [35] . Below this temperature it becomes orthorhombic. This phase transition at room temperature has been demonstrated by several measurement methods such as differential scanning calorimetry (DSC) [36] , electric resistance [36] , infrared spectroscopy (IR) [37] , and x-ray [38] and neutron [39] diffractions. The inelastic spectroscopy studies on the Young’s modulus and the elastic energy loss function also showed that the cubic/orthorhombic transition of a sintered porous poly-crystalized LiMn2O4 sample, corresponding to a charge (Mn3+ and Mn4+) ordering variation, can be detected in the temperature range of 290 - 305 K [40] . A thermally-activated relaxation peak centered at 100 K has also been observed by means of inelastic spectroscopy [41] . This relaxation process can be ascribed to the stress-induced charge jump from Mn3+ to Mn4+.
Inelastic behaviors of the polycrystalline LiMn2O4 sample synthesized by a solid-state reaction have been characterized using a vibrating-reed technique [42] . A phase transition due to an ordering of Mn3+ and Mn4+ ions were observed at a temperature of 290 K. In general, the elastic behaviors of the LiMn2O4 materials depend strongly on crystal structure, volumes of amorphous phase and defects. Therefore, the internal friction peak is always asymmetric and much broad over a wide temperature range, 100 - 200 K [42] .
The active materials of the positive electrode used in this study are composed of the LiMn2O4 and LiCoNiAlO2, carbon black, graphite nanoplatelets and the PVdF polymer. Hardness of the LiMn2O4 crystal and the PVdF polymer is 11 GPa and 0.15 GPa, respectively [43] [44] . Under the same stress during vibration of the reed sample, the strain appeared in the PVdF polymer is much larger than that in the LiMn2O4 crystal, carbon black and graphite nanoplatelets. Therefore, the internal friction can be observed in the PVDF polymer more easily due to larger strain [45] .
The nature of internal friction revealed in this study are not match to the results reported about the LiMn2O4 crystal, we can conclude that the internal friction peaks at ~150, ~240 and ~410 K are related to the PVdF polymer.
3.2.3
. Internal Friction on Graphite and Diamond-Like Carbon
Temperature dependence of the internal friction of bulk graphite material has been measured in the temperature range of 150 - 680 K [46] . Two internal friction peaks were observed at 385 and 620 K and their backgrounds has small temperature dependence only. The peak at 385 K is proved to originate from the sweeping motion of in-plane dislocations and is a relaxation-type peak. Other peak at 620 K is a transformation peak, resulting from the transformation of asphalt which is used as binder in preparation of bulk graphite.
Temperature dependences of the internal friction of nanocrystalline diamond-like carbon films in the range of 0.4 - 300 K showed that there is a peak at approximately 1.7 K and the internal friction increases monotonically with increasing temperature to 300 K [47] . The internal friction of amorphous diamond-like carbon films has also been measured at temperatures between 0.3 K and 300 K [48] . The internal friction increases with increasing temperature but no any peaks were observed in this temperature range despite the ratio of sp3 to sp2 component in the films was changed in a wide range.
3.2.4
. Internal Friction on Complex of Carbon with PVdF Binder
Internal friction properties of a PVdF-graphite nanoplatelet composite have been reported [49] . The graphite nanoplatelets with average thickness of 50 nm and diameter of
10
m were introduced to the PVdF polymer in various concentrations. The β-relaxation process appeared in the PVdF polymer at ~240 K was observed in the temperature range of 260 - 310 K, and no any other relaxation related to the graphite nanoplatelet was detected. The β-relaxation in the composite is a thermally activated process with activation energy of 2.56 eV.
Nanocomposites of PVdF polymer with multiwalled carbon nanotubes (MWCNTs) have also been studied by measuring mechanical properties in a wide composition range [50] . The results showed that MWCNTs act as nucleation agent during crystallization and slightly increase the crystallinity of PVdF/MWCNT bulk films. In addition to the β-relaxation of the PVdF polymer at ~233 K, the internal friction peaks related to the MWCNTs were not observed at temperatures from 170 K to 300 K. The transition temperature of the β-phase in the nanocomposites does not change with MWCNT concentration.
In Section
3.2.3
, we have discussed the internal friction of carbon-related materials such as graphite, and the nanocrystalline and amorphous diamond-like carbon. Not internal friction peaks on these carbon related materials in the temperature range of 100 - 300 K have been reported. Therefore, we can conclude based on the above results that the internal friction peaks at ~150, ~240 and ~413 K as shown in Figure 8, Figure 12 and Figure 14 are due to relaxation processes occurred in the PVdF binder in the positive electrode.
3.2.5
. Internal Friction on
Al
Metal
and Its Alloys
The internal frictions of pure
Al
metal and its alloys in wide temperature range have been reported by several groups [51] - [58] . Mechanisms of the internal friction in
Al
metal and its alloys are complex, depending of composition and physical condition such as structural deformation and annealing history. In the temperature range of 100 - 400 K, the internal friction of
Al
metal may be mainly due to movement of point defects [54] [56] , the interaction between dislocation with point defect [51] and impurity [55] . Therefore, the internal friction on the
Al
foil of the LiB in this study does not change after the charge/discharge cycling. Also, the internal friction on the
Al
foil is smaller than that from the active materials because the 30 μm
Al
foil is much thinner than that of the active materials, 160 μm. Therefore, we can conclude that the internal friction peaks at ~150 K and ~240 K as shown in Figure 8, Figure 12 and Figure 14 do not origin from the Al current detector of the positive electrode.
3.3. Ageing Behaviors of the Positive Electrode
The results in Figure 11 and Figure 12 show that the resonance frequency decreases 17% and 19% and the value increases 40% and 16% at temperatures of 150 and 240 K after the charge/discharge of 150 cycles. Corresponding to the relaxation processes at ~150 and ~240 K, the activation energy increases 333% for the s-relaxation and 178% for the β-relaxation process, respectively. We have also measured the resistivity of the active materials of the positive electrode before and after the charge/discharge cycling. They are 650 Ωcm and 7.8 × 104 Ωcm before and after the cycling, namely, the resistivity of the active material of the positive electrode increases about 120 times after the cycling. One can notice from the above results that mechanical parameters of the resonance frequency and the internal friction as well as the activation energies of the internal friction relaxation processes are significant as valid parameters for characterizing the ageing behaviors of the positive electrode. The change in the activation energy due to the charge/discharge cycling may be related to a deposition of electrochemical reaction products on the surface of the active materials, which increase the contacting resistance between the active material particles coated by the PVdF binder. The changes in both structure and density of the PVdF polymer as well as the introduction of the impurities from the electrolyte and the active materials during the charge/discharge cycling also make difficult to the crystallization or the phase transition of the PVdF polymer. These effects appeared during the charge/discharge cycling increase the activation energy of the internal friction processes in the positive electrode.
4. Conclusions
Mechanical parameters of both resonance frequency and internal friction of the positive-electrode reed samples of the LiBs were measured in the temperature range of 100 - 400 K. Two thermally-activated relaxation pro- cesses were observed at ~150 K and ~240 K. They were related to the relaxation processes occurring in the PVdF binder of the positive electrode. The internal friction was due to a surface relaxation for the peak at ~150 K and a phase transition of the β crystalline phase in the PVdF binder at ~240 K, respectively. Significant internal friction processes were not observed in the active materials of LiMn2O4 and the current collector of Al foil. The internal frictions observed in the PVdF binder may be due to larger strain in this organic polymer material when the vibration wave passes through it. The experimental results of the positive electrode before and after the charge/discharge of 150 cycles showed that the cycling process leads to decrease in the resonance frequency of the electrode samples and increase in their internal frictions. The activation energies of the internal friction processes increased after the charge/discharge cycling. The resonance frequency, the internal friction and the activation energy of the internal friction processes are expected as valid parameters for characterizing the ageing behaviors of positive electrode of the LiBs.
The mechanical parameters can be anticipated as effective indicators for characterizing ageing behaviors of the LiB electrode as a whole. By using this measurement technique, it becomes possible to enhance the cost-performance of the LiBs by matching each life times of positive and negative electrodes, separator and electrolyte. In addition, we must point out that there is not significant change on the capacity of the LiB after the charge/discharge of 150 cycles. This fact suggests that the increase of the internal fraction does not link directly to the decrease in the capacity of the LiB.
Acknowledgements
We are grateful to
Professor
Akira
Namiki
for fruitful discussions and valuable comments. The authors would also like to thank
Mr.
Jun
Umemoto
,
Mr.
Yusuke
Hattori
,
Mr.
Shyuji
Yasuda
and
Mr.
Shingo
Furuta
, Department of Applied Science for Integrated System Engineering, Kyushu Institute of Technology, for their help to get experimental data. This work is also partially supported by project No. 15-B01, Program of Research for the Promotion of Technological Seeds, Japan Science and Technology Agency (JST), as well as partially by Grant-in-Aid for Exploratory Research No: 23651115, Japan Society for the Promotion of Science (JSPS).
NOTES
*Corresponding author.