{Advances in understanding Li battery mechanisms using impedance spectroscopy - Review}


http://dx.doi.org/10.5599/jese.734   79 

J. Electrochem. Sci. Eng. 10(2) (2020) 79-93; http://dx.doi.org/10.5599/jese.734 

 
Open Access: ISSN 1847-9286 

www.jESE-online.org 
Review 

Advances in understanding Li battery mechanisms using 
impedance spectroscopy 

Jože Moškon1, Sara Drvarič Talian1, Robert Dominko1, Miran Gaberšček1,2, 
1Department of Materials Chemistry, National Institute of Chemistry, Hajdrihova 19, 1000 
Ljubljana, Slovenia 
2Faculty of Chemistry and Chemical Technology University of Ljubljana, Večna pot 113, 1000 
Ljubljana, Slovenia 

Corresponding author: miran.gaberscek@ki.si; Tel.: +386-1-4760-320 

Received: October 7, 2019; Revised: January 8, 2020; Accepted: January 8, 2020 
 

Abstract 
The use of impedance spectroscopy in the field of modern batteries is demonstrated on 
three systems: lithium ion batteries represented by lithium iron phosphate (LFP) and lithium 
cobalt oxide (LCO) electrodes, a porous carbon cathode in contact with polysulfides and a 
metallic lithium anode exhibiting dendritic growth. In all cases, systematic experiments are 
shown where the type and composition of electrochemical cell is varied in order to identify 
the main processes contributing to the impedance response. The experiments are upgraded 
with appropriate models, using mainly the transmission line approach. The approach allows 
establishment of clear correlations between the composition and morphology of electrodes 
on one hand and the measured impedance features on the other. As the transmission line 
models are based on the use of physically well-defined elements, the approach allows a 
quantitative description of the main processes (diffusion, reaction, migration across films 
and contacts) taking place in modern battery electrodes. 

Keywords 
Lithium ion batteries; lithium sulfur batteries; transmission line model; porous electrode 
model; dendrites diffusion; electrochemical reaction. 

 

Introduction 

Lithium batteries have been successfully marketed since 1991 when Sony introduced the first 

rechargeable Li battery based on lithium cobalt oxide as cathode and graphite as anode material. 

Later on, many other materials have been proposed both as a cathode or anode in order to further 

improve the battery performance. Despite the commercial success and continuous improvement of 

Li batteries, the mechanisms occurring in these devices have remained only partially explained. 

Whereas the development of new methodologies (microscopy, various spectroscopies etc.) has 

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provided significant insight into local phenomena in certain electrode materials, evaluation of the 

overall electrochemical performance of given electrode still mainly relies on the use of conventional 

electrochemical methods and approaches. Among those, impedance spectroscopy is known to be 

the most accurate and also most powerful as regards the discrimination of various electrochemical 

steps occurring within the electrochemical cell.  

This short review paper demonstrates how impedance spectroscopy can help to improve the 

understanding of main mechanisms taking place in typical lithium battery cells. For the sake of some 

generality, we present typical results obtained on three significantly different electrode types: (i) 

insertion cathodes, (ii) sulfur cathodes having different morphologies and (iii) a metallic lithium 

anode. Most of the results presented here are related to our own past experiments and modeling, 

occasionally other results are also referred to and commented on.  

Results and discussion 

Insertion electrodes  

Insertion electrodes are still the most popular type of Li battery electrodes [1,2]. They 

predominantly consist of active particles of different shapes with the sizes between ca. 10 nm to 

several micrometers. The active particles are bound together by a polymeric binder so that a porous 

matrix is formed. During the cell manufacture, the pores are filled with electrolyte that contains ions 

of active species. Some carbon black or a similar electronic conductor is also added in order to 

ensure sufficient electronic conductivity of the whole electrode matrix. The electrode composite is 

pressed on a current collector which mainly consists of copper (for anodes) or aluminium (for 

cathodes). The main transport-reaction steps taking place in insertion electrodes are schematically 

shown in Figure 1a (for clarity the binder and conductive additive are not shown). Briefly, during 

discharge the electrons move from the metallic collector (foil) across the conductive paths (mostly 

across conductive additives) to each individual active particle (step A in Figure 1a). Ions are provided 

from the electrolytes side. Both electrons and ions are simultaneously inserted into the active 

particles (step B in Figure 1a). Finally, ions and electrons move simultaneously into the inner of 

active particles (step C). However, this movement of ions and electrons inside active particles might 

proceed in very different ways, depending on the system. For example, in the conventional LiCO2 

(LCO) cathode, this movement can be described as rather simple chemical diffusion process (at least 

in certain potential range of operation). At the other extreme, in LiFePO4 (LFP) electrode, this 

movement involves complicated phase transformations such as spinodal decomposition. 

Furthermore, these reactions may depend on particle size, reaction rate and other parameters. Due 

to these differences we will in continuation include typical results on both extreme insertion 

materials, LCO and LFP.  

First we focus on a typical impedance spectrum of a LFP electrode (Figure 1b). We see two main 

features in this figure: a red high-frequency (HF) arc and a blue low-frequency (LF) line. Additionally, 

we may see that HF arc does not approach the origin of graph (the 0,0 point) but forms a small 

intersection at extrapolated highest frequencies. This part (small intersection) is usually ascribed to 

the resistance of electrolyte. As this resistance is comparatively small, it usually does not represent 

a big contribution to the total impedance of cell. The situation may change under high rates where 

the species from electrolyte may be consumed or formed at very high rates. This case, however, is 

not considered here. Thus it remains to find the origin of the other two features (HF arc, LF line). 

One way to find the meaning of these features and correlate them to the general scheme in Figure 

1a is to look into previous results published by other authors and assume the present case is similar 



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to previous ones. Another approach, which is more consuming but also much more reliable, is to 

make dedicated experiments that will reveal the actual correlation between the scheme in Figure 

1a and the measurement in Figure 1b.  

 
Figure 1. a) Three main steps of transport/reaction mechanism in insertion electrodes; b) typical impedance 

response of lithium iron phosphate (LFP) electrode; c) effect of external loading (mechanical pressure) on 
the HF impedance arc of LFP electrode in pouch cell (soft cell enabling application of external mechanical 
load); d) effect of external loading on cell capacity. The figure presents selected unused results from the 

study published in ref. [3]. 

An example of such dedicated experiment is shown in Figure 1c. The pouch cell containing two 

LFP cathodes was pressed externally and the impedance response measured before and after 

exerting the pressure (for details see ref. [3]). As regard the impedance measurements, they were 

carried out with different equipments, depending on the type of cell and frequency range 

investigated: in the frequency range of 1 MHz to 20 Hz, we used Hewlet Packard 4284A instrument, 

while in the frequency range of 100 kHz to 0.001 Hz we used Solartron SI 1260 coupled with PAR 

EG&G 283 potentiostat/galvanostat. The galvanostatic characterization was performed using VPM3 

Potentistat/Galvanostat at room temperature. We may see that the use of mechanical pressure on 

soft pouch cell decreases considerably the size of HF arc. Making many sets of such experiments and 

varying the pressure in a controlled and repeatable way [3], we assumed that HF arc might 

correspond to some contacting, as a contact resistance is known to be dependent on the pressure 

between contacting phases. However, looking at Figure 1a, one sees two types of contacts in a 

typical battery cell: (i) the one between the current collector (here aluminium foil) and the electrode 

composite, and (ii) the contacts between the individual active particles constituting the electrode 

composite. Thus a further dedicated experiment was required, as exemplified in Figure 2.  

From Figure 2 we can see that if we apply a conductive paste between the current collector and 

the composite electrode, the HF arc more or less disappears – even if no pressure is exerted on the 

Charge, A s 

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pouch cell [3]. This experiment indicates quite convincingly that the HF arc must be due the poor 

contact between the current collector and the electrode composite. After application of Ag the 

contact becomes more or less invisible due to improved electronic conductivity across that contact. 

This assumption was additionally confirmed by several other sets of experiments as discussed in our 

previous paper [3]. 
 

 
Figure 2. Improving (decreasing) the contact resistance between aluminium substrate and electrode 

composite by applying conductive Ag paste to that interface  
(adapted and redrawn based on the results of ref. [3]).  

Based on the results shown and discussed above, one might wonder if the finding about the origin 

of HF arc also holds for other cathode systems, for example the more conventional lithium cobalt 

oxide, LCO. Thus we performed a similar experiment using the variable external pressure also on 

the LCO system (Figure 3a) (for details see ref. [4]). However, already a quick look at the typical 

spectrum, we notice that LCO electrode gives an impedance response that contains two arcs, 

denoted as A and B. At least two obvious questions arise: which of the arcs is due to the contact 

between the collector and electrode composite (if any) and what is the meaning of the other arc? 

The experiment with the variable pressure reveals that only the size of arc A significantly changes 

with pressure whereas the size of arc B is more or less pressure-independent. This strongly indicates 

that the arc A must be due to the contact resistance – similarly as HF arc in the case of LFP. Indeed 

this assumption was confirmed by a more detailed analysis, as shown in our previous work [4]. Still, 

the question remains - what is the meaning of arc B? Based on the peak frequency and the 

associated capacitance we assumed that one explanation could be that the arc B represents the 

resistance of insertion reaction (step B in Figure 1a) coupled with the double layer capacitance of 

the interfacial region between the electrolyte and active particles. However, this assumption 

needed to be confirmed/refuted by some dedicated experiments.  



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Figure 3. a,b) Typical effect of external loading (mechanical pressure) on the impedance response of a 
lithium cobalt oxide (LCO) electrode. Note the absence of effect on arc »B«. c) Effect of changing the 
electrolyte concentration on arc B of LCO electrode. The electrolyte consisted of a LiPF6 salt in EC:DEC 

(ethylene carbonate/diethyl carbonate) (1:1 by volume).  

An example of such experiment is shown in Figure 3c. We prepared several cells that contained 

as similar as possible LCO electrodes but in each cell the concentration of electrolyte was different. 

We found that any decrease in the electrolyte concentration led to a significant (and systematic) 

increase of arc B. Simultaneously, the electrolyte concentration had a significant impact on the peak 

frequency of arc B and thus on the associated capacitance. A more detailed analysis showed that all 

the trends were consistent with the main assumption, namely that arc B was due to insertion 

reaction coupled with double layer capacitance [4]. 

Based on some additional dedicated experiments and analyses shown in previous works [5-7], 

we could construct a transmission line (Figure 4) that could describe quite accurately all of the 

measured impedance spectra of insertion electrodes.  

The physical meaning of individual transmission line elements is described in Figure 4. Based on 

this description we can say that in both materials, LFP and LCO, the HF arc is due to the coupling 

between elements r0 and c0, i.e. the resistance and capacitance due to the contact between current 

collector and electrode composite. Furthermore, one can conclude that arc B in the case of LCO is 

due to the sum of discretized elements r2,i and c1,i,  i.e. the resistance due to insertion reaction 

coupled with the capacitance due to the double layer between the electrolyte and the active 

particles. As mentioned before, resistance due electrolyte, r4,i, appears as the high-frequency 

intersection.  

What has not been resolved, however, is the meaning of the low-frequency line observed 

especially clearly in the case of LFP (Figure 1b, blue line). If we look closer to that part of impedance 

response, we in fact see a sort of hump at the beginning of line. Also, we can see that the line is 

quite inclined, i.e. it is not vertical. If it was vertical and without a hump we could assume that it 

must be due to some big capacity in system, such as the chemical capacity of insertion material 

itself. If the inclination was close to 45 degrees, we could ascribe it more or less directly to a Warburg 

impedance, possibly due to the chemical diffusion in the solid active particles, as indeed indicated 

in the proposed transmission line, i.e. the element Zw,i in Figure 4.  

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Figure 4. Top: a scheme of a typical porous insertion electrode indicating resistive and capacitive 

contributions to impedance response: c0 – capacitance due to contact between current collector and 
electrode composite; r0 – resistance due to contact between current collector and electrode composite;  

r1,i – electronic resistance of carbon coating; c1,i – capacitance due to electrolyte/active particle interface;  
r2,i – resistance due to insertion reaction; r3,i –resistance due to contact between active particles;  

r4,i –resistance due electrolyte; Zw,i – Warburg impedance due to diffusion of active species inside active 
particles; rel – electrolyte resistance.  

Bottom: a transmission line model corresponding to the proposed scheme.   

Again, to get further insight into the meaning of this LF line we performed additional systematic 

experiments. For example, Figure 5a shows that the inclination of the LF line changes with state of 

charge of the cathode whereby it approaches the expected 45-degree case as the SoC increases 

towards the medium values (half of total charge). An analysis based on the proposed transmission 

line showed that such a behavior could mean that during charging the averaged diffusion coefficient 

inside active particles is changed [4]. 

 
Figure 5. Measured (a) and simulated (b) impedance spectra of LFP electrode at two different states of 
charge (corresponding to two different potentials). Note the decreasing angle as the SoC increases. The 

effect is reproducible and reversible which indicates a unique correlation between the angle and SoC.  
The figure presents selected unused results from the study published in ref. [4] 

Indeed such variation of diffusion coefficient was earlier shown by other authors for different 

insertion systems [5-7] and is generally attributed to the formation of non-ideal mixtures (occupied 



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vs non-occupied sites with Li during insertion or de-insertion of lithium). However, a more 

mechanistic explanation that would correlate this variation with SoC is still missing so further model 

experiments are needed to fully understand this phenomenon.   

As a whole, the information collected so far enables one to make several conclusions as regards 

the meaning of measured impedance features in insertion electrodes. Figure 6 summarizes such 

conclusions by connecting the regions in an insertion electrode where a given process occurs with 

the corresponding impedance features. The latter are, in turn, also uniquely connected to the 

elements of transmission line model. Such a scheme might represent a good starting point for 

studying any insertion material. However, similarly as shown above, at least some model 

experiments (systematic/dedicated experiments) need to be performed to confirm the validity of 

the scheme and, possibly, identify specific feature(s) for given system.  
 

 
Figure 6. Left: Schematic and SEM image of a typical insertion electrode; Right: transmission 
line model and general simulated impedance response of insertion electrode. The correlations 

between the image, transmission line and impedance response are clearly indicated.  

Litium sulfur system: sulfur electrode (porous carbon in contact with polysulfides) 

Li-S battery is a highly promising candidate to replace the current lithium ion systems [8-10]. 

However, there are still several open questions regarding the very basic operation of this complex 

system. Impedance spectroscopy could help answer some of them. As mentioned before, significant 

progress can only be expected if many sets of dedicated experiments are carried out and the results 

are combined with the findings obtained using other methods. Here we show how it is possible to 

get additional insight into selected cathode mechanisms by using different electrode morphologies 

such as a flat electrode or a porous electrode with well-defined morphology.  

The cathode of Li-S system is usually composed of sulfur that is embedded into the pores of a 

highly porous conductive substrate such as a porous carbon. During cell operation the initial solid 

sulfur gradually electrochemically reduces into soluble polysulfides with progressively shorter 

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chains. Thus, most of the capacity obtained represents the electrochemical reduction of polysulfide 

species. As many of these species are soluble, they can move away from the carbon surface. If so, 

they can later be reduced only if they diffuse back to the surface. This complicates the charge-

discharge mechanism which is also reflected in the corresponding impedance spectra. Figure 7 

shows a typical development of impedance spectra during discharge of a conventional Li-S cell. The 

development during charging (not shown) is similar, only going to backward direction, as expected 

for a reversible reaction. In any case, what we can see in Figure 7b is that most of the measured 

impedance responses are dominated by the low frequency response consisting of tail (a curved line) 

with progressively higher impedances. An analysis of this response appears to be rather difficult and 

ambiguous. The development during charging (not shown) is similar, only going to backward 

direction, as expected for a reversible reaction. In any case, what we can see in Figure 7b is that 

most of the measured impedance responses are dominated by the low frequency response 

consisting of tail (a curved line) with progressively higher impedances. An analysis of this response 

appears to be rather difficult and ambiguous. 
   

 
Figure 7. a) Typical charge-discharge curve of Li-S cell. The spikes represent the points where the cell 

operation was stopped and impedance spectra measured (after stabilization). The corresponding spectra 
obtained during the discharge are shown in panel b). The ENSACO 350G carbon (Imerys) and a 

corresponding sulfur composite (ENSACO 350G/S) were prepared in a C:S=1:2 mass ratio. The composite 
was mixed with a Printex (Degussa) conductive additive and a PVdF binder (8:1:1) in (NMP N-methyl-2-pyr-

rodione). Sulfur loading was approx. 1 mg/cm2. The electrolyte was 1 M LiTFSI (lithium bis(trifluorome-
thanesulfonyl)imide) in TEGDME (triethylene glycol methyl ether):DOL(dioxolane) 1:1 (v:v). The separator 

was Celgard 2400. The figure presents selected unused results from the study published in ref. [11] 

We have thus proposed to simplify the conventional Li-S cell in three ways [11,12]: (i) we replaced 

the porous cathode with a flat glassy carbon, (ii) we removed the lithium anode and used another 

glassy carbon to form a symmetrical carbon-carbon cell, (iii) instead of using sulfur we used different 

polysulfides to study the various stages of charge-discharge process. Typical results and a basic 

analysis are shown in Figure 8.  

A comparison between the impedance spectrum shown in Figure 8c and the spectra displayed in 

Figure 7b shows several pronounced differences. Firstly, the impedance spectrum in Figure 8c 

consists of a much bigger high-frequency arc (several thousands ) as opposed to the much smaller 

(50-100 ) arc in conventional cell.    



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Figure 8. a) Schematic presentation of the flat symmetrical cell used to study the basic reaction-diffusion 

properties of various polysulfides; b) A typical reaction-diffusion scheme that could be studied in proposed 
cell (e.g. reduction of S42- to S22-); c) measured impedance spectrum (red open circles) of reaction under (b) 
and the corresponding fit (blue circles) using the Randles circuit shown in panel (d). Impedance spectra of 

the symmetrical glassy carbon cells were measured at OCV with the same voltage amplitude (10 mV, rms). 
The low-frequency limit was varied and extended down to 0.1 mHz. Adapted partial results from ref. [11] 

Secondly, at low frequencies the spectrum in Figure 8c consists of rather small arc that extends 

to poorly defined shape at lowest frequencies. Analysis [11] showed that the latter feature was an 

artefact – most likely due to tendency of polysulfides to disproportionate. By contrast, the other 

features (big and small arc) could very well be fitted with the conventional Randles circuit as 

demonstrated by the good match between blue and red circles. Making many such experiments 

involving different polysulfides, we could determine quite accurately the main reaction (exchange 

current density, i0) and transport (chemical diffusion coefficient, Dchem) parameters, as shown in 

detail in our previous paper [11,12].  

Once the basic intrinsic reaction and transport parameters of different polysulfides were known, 

we could move back to more complex electrode configuration. Specifically, we retained the 

symmetrical cell configuration but replaced the flat electrodes with porous ones. We used porosity 

of different degrees in order to decouple the effect of porosity itself from the other electrode 

parameters. In this brief overview we only show selected results on unconventional porous 

electrodes consisting of a carbon felt with intermediate level of specific surface area (15 m2 g-1) 

(Figure 9). Room temperature impedance spectra of the cells were measured on VMP3 

potentiostat/galvanostat (Bio-Logic) at OCV in the range from 1 MHz to 0.1 mHz (or 20 µHz) with 10 

(5) points per decade and an amplitude of 10 mV (rms). 

The general impedance response of porous electrodes involving surface reaction and diffusion in 

pores (corresponding well to the situation in the present carbon-polysulfide system) has been 

derived analytically [13,14]. Two typical impedance spectra predicted using the analytical expression 

are displayed in Figure 9b. 

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Figure 9. a) Schematic of a carbon-carbon cell where porous carbon felt (15 m2 g-1) was used as a model 

porous electrode; b) Theoretical impedance response of a porous battery electrode (with surface reaction) 
as predicted by the analytical model in ref. [14]; c) measured impedance response of symmetrical carbon-
carbon cell with polysulfides as active substance – low frequencies; d) measured impedance response of 

symmetrical carbon-carbon cell with polysulfides as active substance – high frequencies (adapted from ref. 
[15]); attempts to fit the spectra using ordinary Voigt circuit (colored parts) were not entirely successful 

It can be seen that impedance spectra consist of a high frequency arc with more or less expressed 

45-degree feature at the highest frequencies. At low frequencies there is an additional arc but 

typically with a smaller size. Also, we can see that the size of both arcs depends on the electrode 

thickness: the size of HF arc decreases with thickness, while the size LF arc increases. Comparing the 

theoretical predictions to the actual measurements we can see that HF arc follows quite well the 

predicted trends. However, there is a large mismatch between the prediction and the measured 

behavior of LF arc: firstly, it is much bigger (about 2 orders of magnitude) than the predicted arc and 

secondly, its size does not increase with electrode thickness. Further analysis in which we 

systematically changed the concentration of catholyte solution, the type and thickness of separator 

etc. [15] revealed that in fact, the theoretically predicted low-frequency arc was masked by the 

response of catholyte-soaked separator. In other words, the diffusional processes occurring in the 

separator prevailed over those occurring in the porous cathode itself. As we could not find any 

model for this particular situation, we built-up our own model (Figure 10) based on the well-known 

transmission line approach developed for porous electrochemical systems [16].  

The validity of model was first checked for the case where the response of separator was 

neglected (set to zero). We found a complete correspondence between the model shown in Figure 

10 and the recent analytical solution [14]. Then the response of separator was plugged in, and the 

predictions of the whole model compared to the actual measurements. Typical simulations are 

displayed in Figure 11. 



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Figure 10. General transmission line scheme that takes into account diffusion in separator (right part, as 
denoted), diffusion in porous cathode (elements Z1, Z2, Z3) and reaction in porous cathode (elements ZL). 

Electronic conductivity of carbon matrix (elements ZE) is set to zero for simplicity (however, in principle could 
be of any value). More detailed meaning of all the elements can be found in our previous article [15]. 

 

Figure 11. Low (top) and high (bottom) 
frequency response of porous cathode in 
contact with separator as predicted by the 
model in Figure 10. 

 

We can see that now the low-frequency response is very similar to the measurements (cf. 

Figure 9 c,d) while, as expected, the good prediction of HF arc from the analytical solution is also 

retained. In fact, a more detailed analysis shows that the chemical capacity of LF arc (related to its 

peak frequency) is a sum of the values for the porous cathode and porous separator. This theoretical 

prediction was fully confirmed in all measurements on different cells carried out in this study.  

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Metallic lithium anode 

Unlike the sulfur cathode of the Li-S system, the metallic lithium anode has been subject of 

intense investigation for more than 40 years [17,18]. In organic electrolytes, lithium gets 

spontaneously passivated by a surface layer that conducts Li ions but is more or less non-conductive 

for electrons and hence its widely accepted name »Solid Electrolyte Interface« (SEI) [17-20]. 

However, the nature of SEI as well as the surface of Li anode in general is significantly modified 

during repetitive cycling [21,22]. Various proposed mechanisms exist that describe Li morphology 

obtained after certain number of cycling. Here we assume and treat only the most general features 

that are common to many investigations: (i) continuous dissolution and re-deposition of lithium 

leads to a porous morphology of superficial lithium (called dendrites) as the dissolution-deposition 

process does not proceed uniformly across the surface; (ii) the porous Li structures (dendrites) are 

passivated on their surface with SEI-like film; (iii) there are at least two types of dendrites, the so-

called »live dendrites« and »dead dendrites«; the former still contain a significant amount of 

metallic lithium, whereas the latter contain a small amount of electrically disconnected lithium or 

even no lithium but only SEI-like products.  

Due to the complex surface morphology of cycled lithium anode, it is not surprising that impedance 

spectra are also quite complex such as demonstrated in Figure 12. In that experiment, a symmetrical 

Li-Li cell was cycled as indicated on the left part of the figure. The cells for this experiment were made 

according to the pouch technology using two lithium electrodes and Celgard 2320 separator. 
 

 
Figure 12. Development of impedance spectra with the number of cycles (shown on top left) on symmetrical 

Li-Li cell. For clarity only selected cycle numbers are displayed. See development of unusual shapes at low 
frequencies representing the development of dendrites. The figure presents selected unused and/or adapted 

results from the study published in ref. [23] 

The electrolyte used was 20 µL of 1 M LiTFSI in TEGDME:DOL 1:1 (v:v). The electrochemical 

experiments on the cells were done with a combination of impedance spectroscopy measurements 

and stripping and deposition cycles on Li||Li symmetrical cells. The cells were connected to a VMP3 

Biologic potentiostat/galvanostat within 10 minutes of cell assembly. They were left to stabilize for 

24 hours, during which impedance spectra were measured. After this initial period, Li||Li cell 



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underwent stripping and deposition at a constant current rate for 2 hours.  The current for the 

discharge/charge cycles was either 0.2 mA (“low current cells”) or 1.0 mA (“high current cells”). 

After stripping and deposition of lithium, the cells were left to relax for 15 minutes, after which 

impedance spectra were measured. All of impedance spectroscopy measurements were done in the 

range of 1 MHz to 1 mHz with an amplitude voltage of 10 mV (rms). 

As seen from Figure 12, during cycling the impedance response of the cell changes significantly. 

HF arc is gradually decreasing whereas LF arc transforms into an extended shape typical for cases 

where several processes closely overlap. In order to check the validity of such measurements (that 

potentially include some uncompensated dynamics and additionally is carried out to very low 

frequencies), we carried out a couple of standard testings such as (i) measurements at different 

values of excitation signal (testing the linearity of response), (ii) repetition of measurements at given 

steady state conditions (checking the time invariance of the system) and (iii) Kramers-Kronig analysis 

(for details see ref. [23]).  

Based on the assumptions i-iii stated above we constructed a transmission line that captures the 

main known morphological features of Li-Li cell (Figure 13).  
 

   
Figure 13. Top: Transmission line model proposed for lithium anode containing dendrites. Live and dead 

dendrites are considered separately as they have different basic properties (see main text). Bottom: 
Simulations using the proposed transmission line; different level of coupling between live dendrites, dead 

dendrites and separator are displayed; most measurements show a close coupling corresponding either to 
the dashed or solid graphs (compare with the shapes seen in Figure 12). 

Briefly, the main feature that generates the first and the second dotted arc are the porous live 

dendrites. It is quite remarkable that in fact a porous live lithium filled with electrolyte is 

conceptually almost identical to a porous carbon electrode containing polysulfides. This is due to 

the fact that in both cases the reaction proceeds on a conductive porous surface whereas at low 

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frequencies, diffusion of active species inside the pores (the second arc) is the predominating 

process in both cases. However, the main difference is that the cycled lithium electrode also 

contains some dead dendrites where no surface reaction can take place so only diffusion across the 

pores is seen (see second compartment of scheme in Figure 13). This part contributes to another, 

third arc which however is quite strongly coupled to the second one (because in both cases the main 

diffusional processes are similar). Finally, at lowest frequencies (the third compartment in Figure 

13) the arc due to diffusion in separator occurs. As the thickness and porosity of the separator are 

similar as in live or dead lithium, this arc is also strongly coupled to both dendritic features. As a 

whole, this strong coupling gives an extended shape as indeed observed in the actual measurements 

(compare the simulations in Figure 13 with some of the measured shapes in Figure 12, especially 

the ones after 20th, 30th and 40th cycle where dendrites have already fully evolved).    

Conclusions 

In this brief review we showed how impedance spectroscopy can be used for systematic 
investigation of selected mechanisms occurring in modern batteries. In the first part we focused on 
explanation of the main impedance features observed in well-known Li ion insertion systems such 
as lithium iron phosphate (LFP) and lithium cobalt oxide (LCO). Then we demonstrated the use of 
impedance spectroscopy on a post lithium ion system, specifically lithium-sulfur battery. We 
showed that the complex response of the sulfur cathode can be better understood if the usual 
porous electrode morphology is replaced with a flat electrode and a symmetrical cell instead of 
asymmetrical is used. Once the main transport-reaction mechanism has been identified, the flat 
electrode can be replaced by a porous in order to take into account the effect of porosity. There, 
one of the main issues is how to connect (couple) the response of a porous electrode with that of 
porous separator. We have managed to carry out this coupling by proposing an appropriate 
transmission line model. The latter can describe all the measured features of a porous carbon 
electrode in contact with polysulfides. Finally, we extended the same basic concept of transmission 
line for porous electrodes to a cycled lithium electrode. Namely, it appears that the dendrites 
formed during charge-discharge represent a conceptually similar framework for transmission line 
modeling as the porous carbon electrode with surface reactions (such as in the case of polysulfides). 
The proposed transmission line is able, for the first time, to quantitatively – and with physically 
sound elements - reproduce the response of dendritic lithium. 

Acknowledgements: This work was financially support by Slovene Research Agency and through Helis project 
(European Union's Horizon 2020 research and innovation program under Grant Agreement No. 666221). 

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