{Internal resistance and temperature change during over-discharge of lead-acid battery}


 

doi:10.5599/jese.469  129 

J. Electrochem. Sci. Eng. 8(2) (2018) 129-139; DOI: http://dx.doi.org/10.5599/jese.469  

 
Open Access : : ISSN 1847-9286 

www.jESE-online.org 
Original scientific paper 

Internal resistance and temperature change during over-
discharge of lead-acid battery 

Balázs Broda, György Inzelt 

Institute of Chemistry, Laboratory of Electrochemistry and Electroanalytical Chemistry,  
Eötvös Loránd University, Pázmány P. s. 1/A, H-1117 Budapest, Hungary 

Corresponding authorsE-mail: balazsbroda@gmail.com  

Received: October 26, 2017; Revised: January 29, 2018; Accepted: January 29, 2018 
 

Abstract 
In recent decades, more and more electronic systems (start-stop, drive-by-wire, brake-
by-wire) have been developed in the automotive industry therefore reliable power 
sources are necessary. It is essential to understand thoroughly the detailed behaviour of 
the battery to increase its efficiency, stability and monitorability which is the most 
popular field nowadays. Over-discharge plays an important role in aging because it 
increases the probability of initiation of grid corrosion, sulfation and loss of active mass. 
In this work, the effects of over-discharge of lead-acid battery have been investigated via 
internal resistance increase and temperature change separately for both the negative 
and the positive electrode. Most of the measurements were carried out in a prepared 
test cell (which contained a negative and a positive plate, an Ag│Ag2SO4 reference 
electrode, a shunt for measuring current accurately) connected to a dummy battery and 
an electronic load. 

Keywords 
Energy storage; Deep discharge; Aging; Battery sensor 

 

Introduction 

Despite of the fact that the lead-acid battery is a 150-year-old system, its over-discharge 

characteristic is a less investigated area. During this process, different reactions can occur which 

lead to the aging of the battery (for example sulfation, loss of active mass or loss of water) [1-4]. In 

the 21st century, lead-acid batteries are still used in most of cars for starting the gasoline or diesel 

engine and for the operation of the electronic system (drive-by-wire, brake-by wire, start-stop 

systems) too. In this case, reliable and well-monitorable power sources are necessary. For this 

purpose, better understanding of over-discharge is still necessary. 

At the end of the 20th century, Garche et al. [5] estimated the basic reactions during over-

discharge. The cell voltage, the potential of the positive and the negative electrode, the intensity 

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J. Electrochem. Sci. Eng. 8(2) (2018) 129-139 OVER-DISCHARGE OF LEAD-ACID BATTERY 

130  

of gas evolution and the density of sulfuric acid at the top of the cell were measured. It was stated 

that the basic reaction during discharge proceeded to a lesser extent and was replaced by other 

reactions (for example increased gas evolution). In case of positive electrode, the capacity loss is 

mainly caused by mechanical stress, because of different molar volumes of the reactants 

(Vlead-dioxide:Vlead-sulfate:Vlead=1.4:2.7:1.0). In case of negative electrode, the main reason of the aging 

is the irreversible oxidation of the expanders.  

This capacity loss was investigated by Blank et al. [6] setting depth of discharge (DOD) from 

100 % to 130 %. It was stated that significant part of the initial capacity was lost because of over-

discharge just after a few cycles. The amount of decreasing was closely related to DOD level, at 

higher DOD, the loss of capacity was also larger. It is also stated by the authors that the area of 

deep discharge has so far been mostly neglected in published research apart from fundamental 

material investigations [7]. 

In this paper, we present the effects of over-discharge on the internal resistance of the negative 

and the positive electrode and the whole cell and on the temperature of the electrolyte at 

different places of the cell (in the vicinity of the negative and the positive electrode and in the bulk 

solution). 

Experimental  

Two types of batteries were investigated. We used a Furukawa HiDash battery (type: flooded, 

voltage: 12 V, capacity: 48 Ah) for the internal resistance measurements and a test cell which 

contains a negative and a positive plate of a dry Unibat battery (type: flooded, voltage: 12 V, 

capacity: 9 Ah) and 650 ml 37 m/m% sulfuric acid for temperature experiment. 

Internal resistance measurement 

The potential of the positive and the negative electrode against Ag│Ag2SO4 reference electrode 

and another cell voltage were measured by using labjack data acquisition device. We apply 4.8 A 

current [which is the C/10 current for a battery which capacity (C) is 48 Ah] until it reduced to the 

10 % of its initial value. During this procedure, we measured the impedance of the battery every 

10 minutes at 1 kHz excitation frequency which is good approximation to the battery's internal 

resistance (Figure 1). The 1 kHz-resistance R1kHz is defined as the real part of the battery 

impedance at 1 kHz frequency. This is a practical definition, since it is quickly measurable with an 

active excitation device. The standard handheld battery testers usually measure this value. [8] 
 

 
Figure 1. Measured impedance spectrum of the examined cell during discharge (Nyquist plot)  



B. Broda and G. Inzelt J. Electrochem. Sci. Eng. 8(2) (2018) 129-139 

doi:10.5599/jese.459 131 

Temperature experiment 

An Ag│Ag2SO4│saturated aqueous K2SO4 solution (0.69 V vs. SHE) reference electrode and 

J-type thermocouples were used. The schematic representation of the experimental system is 

shown in Figure 2. 

Four thermocouples were used to measure the temperature at different places in the cell, their 

positions are presented in Figure 3. We used a heat chamber to hold the external temperature 

constant (25 °C). 

 

 
Figure 2. Experimental system 

 
Figure 3. Temperature measurement 

 

The procedure is summarized in Table 1. 

Table 1. Procedure of the measurements 

  Operation (details) Circumstances (T = 25 °C) 

1 
Preparation 

Cell preparation – 

2 Immersion Ucell > 2.1 V 

3 

Pretreatment 

Charge Ilim = 0.16 A; Ulim = 2.4 V; t = 2 h 

4 Discharge I = 0.16 A; t = 1 h 

5 Charge Ilim = 0.16 A; Ulim = 2.4 V; t = 2 h 

6 Discharge I = 0.16 A; t = 1 h 

7 Charge Ilim = 0.16 A; Ulim = 2.4 V; t = 2 h 

8 Discharge I = 0.16 A; t = 1 h 

9 
Achieving full charge 

Charge Ilim = 0.16 A; Ulim = 2.4 V; I  < 0.016 A 

10 Delay – 

11 Capacity measurement Discharge I = 0.16 A; Ucell < 1.75 V 

12 „Over-discharge” 
Setting DOD (100·x%) 

Discharge I = 0.16 A; t = tcapacity measurement · (x-1) 

13 Delay t = 1 h 

14 
„Recharge” 

Charge Ilim = 0.16 A; Ulim = 2.4 V; t = 16 h 

15 Delay – 



J. Electrochem. Sci. Eng. 8(2) (2018) 129-139 OVER-DISCHARGE OF LEAD-ACID BATTERY 

132  

In step 12, x can be 1.0, 1.1 and 1.2, which means that the DOD level is 100 %, 110 % and 

120 %. The duration of step 12 is the product of the duration of step 11 (tcapacity measurement) and x-1. 

Results and discussion 

Internal resistance measurement 

Negative electrode 

In Figure 4 (regarding to the end of step 11, step 12 and 13 and the beginning of step 14 of 

Table 1), it can be seen that during the over-discharge (between ca. 3-8 h) the negative electrode’s 

internal resistance changed to nearly 100 times of its initial 2-3 mΩ value when a large change in 

the potential of the negative electrode occurred. When the potential has become practically 

constant (there is only a small decrease because of the uncertainty of potential measurement), 

the electrode's internal resistance has begun to decrease at a similar rate to the previous one and 

reached about 2 times of its initial value. The internal resistance of the negative electrode hasn’t 

changed until the end of discharge, but when the current has become zero (between ca. 8-9 h) a 

significant increase could be observed. This process lasted until the charging has been started. 

During recharging (between ca. 9-16 h), the internal resistance highly decreased and returned to 

its initial value after several minutes. 

 
Figure 4. Change of the potential of the negative electrode (multiplied by minus 1) and internal 

resistance during a discharge-charge cycle 
 

During discharge (between ca. 0-3 h), porous metallic lead is converted to lead sulfate at the 

negative electrode (Reaction 1). 

Pb + HSO4− → PbSO4 + H+ + 2 e− (Reaction 1) 

The specific volume of PbSO4 is approximately 3 times higher than the specific volume of Pb 

and its conductivity is lower by orders of magnitude [9]. Thus, the porosity decreases during this 

process as well as the pores become clogged (so the diffusion coefficient of the different species in 

the electrolyte decreases). At the same time, sulfuric acid reacts with lead, that’s why its 

concentration becomes smaller and the amount of acid required for the reaction isn’t available on 

the surface of the active material. As the result of these two processes, the potential of the 

negative electrode and the internal resistance highly increase. 



B. Broda and G. Inzelt J. Electrochem. Sci. Eng. 8(2) (2018) 129-139 

doi:10.5599/jese.459 133 

The Nernst equation provides an approximate calculation of the potential of the negative 

electrode. Although the system is not in equilibrium during discharge, this relationship can be used 

to interpret the direction of the processes. 

+
4

4 4

4

PbSO H
PbSO /Pb PbSO /Pb

Pb HSO

ln
2

o
a aRT

E E
F a a −

= +  (1) 

Where EPbSO4/Pb  is the potential of the negative electrode,  E
o

PbSO4/Pb is the standard electrode 

potential of the PbSO4/Pb system (-0.356 V vs. SHE), R is the gas constant, T is the temperature of 
the system, F is the Faraday constant and aPbSO4, aPb, aH+, aHSO4- are the activities of the given 

species. 

Based on Equation 1, if the lead ion or the sulfate ion activity changes on the electrochemically 

active surface of the electrode, the potential of the negative electrode will change too. The 

concentration (also the activity) of the sulfuric acid decreases continuously during discharge, due 

to this, the potential also gradually increases. The reason of the high change at the end of 

discharge is the decrease of both species’ activity. 

At more positive potential, other reactions can take place. The most significant reactions are 

the following: 

PbSO4 + 2 H2O → PbO2 + HSO4− + 3 H+ + 2 e− (Reaction 2) 

2 H2O → 4 H+ + O2 + 4 e− (Reaction 3) 

In Reaction 2 lead sulfate with high resistance and specific volume is converted to lead dioxide. 

Due to this reaction, the electrode's internal resistance is decreased and the average size of the 

pores is increased. In Reaction 3 (which is significant when the polarity reversal of the negative 

electrode takes place), oxygen gas evolves, which phenomena was observed by Garche et al. [5]. 

On the one hand, these gas bubbles mix the electrolyte, so the inhomogeneities can be 

eliminated. On the other hand, a non-conductive layer of gas is formed on the active surface 

resulting in increased internal resistance. If all electrochemically active lead reacted due to the 

Reaction 1, the potential changes (even the potential of the positive electrode can be reached) 

and the Reactions 2 and 3 take place. Based on this, the over-discharge of the negative electrode 

is very similar to the charge/over-charge of the positive electrode. During this process, the internal 

resistance of the electrode doesn’t change significantly until the end of over-discharge. 

After over-discharge, the system is left alone for 2 hours and synproportionation can occur 

(Reaction 4), in which the remaining lead content of the active mass reacts with lead-dioxide 

generated during over-discharge (Reaction 2). 

Pb + PbO2 + 2 HSO4− + 2 H+ → 2 PbSO4 + 2 H2O (Reaction 4) 

In this case, the concentration of sulfuric acid decreases, lead and lead dioxide with lower 

resistance and specific volume converted to lead sulfate with high resistance and specific volume. 

Based on these phenomena, pores can become clogged and the internal resistance can 

significantly increase. 

During the recharge, both lead sulfate and lead dioxide can be converted into lead with better 

conductivity and lower specific volume. Although the transformation of the whole amount of lead 

sulfate requires a long time, the internal resistance significantly decreases during ca. 10 minutes. 

This phenomenon can be explained with the opening of pores and higher sulfuric acid 

concentration inside them which resulted in low resistivity connectors to the grid. Several hours 

later, the internal resistance reaches to its initial value. 



J. Electrochem. Sci. Eng. 8(2) (2018) 129-139 OVER-DISCHARGE OF LEAD-ACID BATTERY 

134  

Positive electrode 

The observed phenomena during discharge of the positive electrode (Figure 5) were similar to 

the previously mentioned ones. In Figure 5, the end of step 11, step 12 and 13 and the beginning 

of step 14 of Table 1 are shown. The internal resistance increased continuously as the cell lost its 

capacity (“normal” discharge between ca. 0-3 h) and when high decrease of the potential 

occurred, it increased by approximately two orders of magnitude compared to the initial value. 

During over-discharge (between ca. 3-8 h), it approached its initial value, and after that, when 

discharge was over (between ca. 8-9 h), we experienced some increase again. After starting the 

recharge (between ca. 9-16 h), it reached its initial value in about half an hour. 

 

 
Figure 5. Change of positive electrode’s potential and internal resistance during a discharge-

charge cycle 

In this case, the potential of the positive electrode can also be estimated from the Nernst 

equation. 

+
2 4

2 4 2 4

4 2

3

PbO H HSO

PbO /PbSO PbO /PbSO 2
PbSO H O

ln
2

o
a a aRT

E E
F a a

−

= +  (2) 

where EPbO2/PbSO4 is the potential of the positive electrode, E
o

PbO2/PbSO4 is the standard electrode 

potential of the PbO2/PbSO4 system (+1.685 V vs. SHE), R is the gas constant, T is the temperature 
of the system, F is the Faraday constant and aPbO2, aPbSO4, aH2O, aH+, aHSO4- are the activities of the 

given species. 

This case is a little bit more complex than the case of negative electrode. Although, the reason 

of the potential’s monotone decrease is the sulfuric acid consumption, but the fall of potential can 

be caused by several processes: the decrease of activity of lead-dioxide (in extreme case when the 

battery is “fully” discharged, almost the whole surface of the active material is covered by lead-

sulfate, so the activity of the lead-dioxide must be less than one) or sulfuric acid or the increase of 

activity of water next to the electrochemically active surface (the activity of the water in such a 

concentrated electrolyte is less than one [10]). It can be stated that the potential doesn’t change 

dramatically when the over-discharge of the positive electrode completed. There may be two 



B. Broda and G. Inzelt J. Electrochem. Sci. Eng. 8(2) (2018) 129-139 

doi:10.5599/jese.459 135 

different explanations: Reaction 4 isn’t significant during over-discharge at all or it becomes 

significantly important before the process is over. It can be distinguished betweem the two 

possibilities by analyzing the results of the resistance measurement. 

Looking at the change in internal resistance of the positive electrode, the phenomenon is 

similar to the case of the negative electrode. The initial increase is caused by clogged pores and 

high resistivity lead sulfate. The interpretation of sudden decrease in the potential is practically 

the same as mentioned before, but there is an important difference in the further part of over-

discharge, the internal resistance begins to increase before the process is over. Based on this, it is 

concluded that the Reaction 4 becomes significant before over-discharge is over. 

Cell 

In Figure 6, the voltage of a whole cell is shown (regarding to the end of step 11, step 12 and 13 

and the beginning of step 14 of Table 1). Besides the previously mentioned phenomena, 

interesting behavior could be observed after the cell reversal (between ca. 5-8 h) and after the 

over-discharge was finished (between ca. 8-10 h). The internal resistance of the cell didn’t 

decrease during the over-discharge period as much as shown in the previous sections. This 

phenomenon can be justified by the worse structural properties of the active material. If the pores 

inside the electrodes and the electrochemically active surface of them are smaller, the effects of 

the same processes can be much larger as it can be seen until the beginning of recharge (between 

ca. 5-10 h). After the end of discharge, the internal resistance increased just as in the case of the 

negative and positive electrode, but the rate was much higher than it can be expected, which also 

refers to the poor structural properties of the electrode. But after this region, the resistance 

decreased (between ca. 8-10 h). If we consider that the impedance measurement has an impact 

on the system, it can be explained by the discharge current which was applied in every 10 minutes 

for a short time resulting in a decrease of internal resistance (the pulsating curve also suggests this 

phenomenon). 

 
Figure 6. Change of cell’s voltage and internal resistance during a discharge-charge cycle 

Based on this, it can be said that during the measurements when current flowed through the 

system, this phenomenon hadn’t caused an error, because the current was applied for a short 

time. It was only significant when neither discharge nor charge was executed. In the experiments 



J. Electrochem. Sci. Eng. 8(2) (2018) 129-139 OVER-DISCHARGE OF LEAD-ACID BATTERY 

136  

shown in Figure 4 and Figure 5, this phenomenon was negligible because the system was not in a 

labile state contrast to the measurement shown in Figure 6. 

Temperature measurement 

Over-discharge  

In Figure 7, it is shown that during the negative electrode polarity reversal, at first the value of 

that thermocouple changes (Tnegative) which is located in the direct vicinity of the negative 

electrode and the other ones follow later. The temperature near the positive electrode (Tpositive) 

and in the bulk electrolyte (Telectrolyte) starts to increase 15 minutes after the negative electrode 

polarity reversal. According to our expectations, Tnegative changed the biggest (0.4 °C), Tpositive and 

Telectrolyte increased by 0.3 °C. The phenomenon regarding to the positive electrode polarity 

reversal was essentially the same. 
 

 
Figure 7. Temperature change due to over-discharge (potential of negative and positive 
electrode, temperature in the vicinity of the negative and the positive electrode, in the 

electrolyte and in the heat chamber) 

These changes may not seem very significant at first sight, but if they are converted for the 

original cell, the effects are much higher. In Table 2, the most important differences between the 

test cell and the original cell are summarized. 

Table 2. Parameters of the cells. 

 Test cell Original cell 

Amount of electrolyte, ml 650 75 

Number of negative electrodes 1 5 

Number of positive electrodes 1 4 

Measured capacity, Ah ca. 3 ca. 8 

 

Based on the measured values by the thermocouple placed in the electrolyte, it can be 

assumed that the temperature of the whole cell has increased by more than 0.3 °C. During over-

discharge if the same processes take place, the original cell generates about 3 times as much heat 



B. Broda and G. Inzelt J. Electrochem. Sci. Eng. 8(2) (2018) 129-139 

doi:10.5599/jese.459 137 

as the test cell based on the capacity differences. The cell voltages are practically the same in 

these cases, but approximately 3 times higher charge goes through the original cell than the test 

cell. The generated heat can be calculated as the product of voltage and charge based on 

Equation 5. 

We need to estimate the heat capacity of the electrodes. For this calculation, we used the 

following molar heat capacity values: 2 J/(mol·°C) for lead, 103 J/(mol·°C) for lead sulfate and 

61 J/(mol·°C) for lead dioxide. The weight of the negative electrode is approximately 40 g of which 

the lead grid is 12 g and the active mass is the remaining 30 g (we suppose that it contains mostly 

lead at the beginning of the measurement). The positive electrode’s weight is approximately 50 g, 

of which the lead grid is 12 g and the active mass is 38 g (we suppose that it is mostly lead dioxide 

at the beginning). By the time the cell was discharged, approximately 3 Ah of charge was passed 

through it. According to the Faraday law, it is possible to calculate how much active mass was 

converted during discharge procedure (Table 3, Table 4). 

Table 3. Transformation of active material and sulfuric acid in the test cell during discharge 

 Negative electrode Positive electrode Electrolyte 

Compound Lead 
Lead 

sulfate 
Lead 

dioxide 
Lead 

sulfate 
Sulfuric acid Water 

mbeg / g 28 0 38 0 308 524 

mtrans / g -12 +17 -13 +17 -11 +2 

mend /g 16 17 25 17 297 526 

 

We used the following data for the calculation: ρ (37 m/m% sulfuric acid) = 1.28 g/cm3; 

M(Pb) = 207.2 g/mol; M(PbSO4) = 303.3 g/mol; M(PbO2) = 239.2 g/mol; M(H2SO4) = 98.1 g/mol; 

M(H2O) = 18.0 g/mol; F = 96500 C/mol. 

Table 4. Transformation of active material and sulfuric acid in the original cell during discharge. 

 Negative electrode Positive electrode Electrolyte 

Compound Lead 
Lead 

sulfate 
Lead 

dioxide 
Compound Lead 

Lead 
sulfate 

mbeg / g 140 0 152 0 36 61 

mtrans / g -31 +45 -36 +45 -29 +5 

mend /g 109 45 116 45 6 66 

 

Based on the measured capacity of the original cell, it is stated that approximately 8 Ah charges 

could pass through the cell until reaching the fully discharged state. At that time, the mass fraction 

of the sulfuric acid in the test cell was 36 m/m% [heat capacity=2.9 J/(g·°C)] and it was 9 m/m% in 

the original cell [heat capacity=3.9 J/g·°C). [11] 

Based on Table 3, Table 4 and the above-mentioned data, the heat capacity of the cells can be 

calculated (active mass+grid+electrolyte): Ctest cell=2410 J/°C, Coriginal cell=374 J/°C. 

We can make a calculation to estimate the generated heat (Qtest cell) in the test cell: 

Qtest cell = Ctest cell Ttest cell = 2410 J / oC × 0.3oC = 723 J  Qoriginal cell/3 (3) 

where ΔTtest cell is the temperature change during the negative electrode polarity reversal, Qorginal cell 

is the generated heat in the original cell due to the previously mentioned effect. 



J. Electrochem. Sci. Eng. 8(2) (2018) 129-139 OVER-DISCHARGE OF LEAD-ACID BATTERY 

138  

Based on this, we can roughly calculate how many degrees of Celsius the original cell will warm 

with the same current density and process: 

o
original cell original cell

o

732 J 3
5.8 C

J
364

C

T Q


 =  =  (4) 

The temperature in the original cell would increase by about 6 °C due to the electrode polarity 

reversal. However, it is important to note that this will be the average value in the whole cell, so 

inside the electrode, the temperature can rise significantly higher which has a very significant role 

in aging processes. [12] 

It can be assumed that not the different reactions cause the temperature rise, because the 

system cools down later and it approaches its initial state in the vicinity of the electrodes’ surface, 

although the reactions don’t change significantly at that time. However, the high resistance 

increase can cause this phenomenon. 

The initial resistance of the cell was 0.02 Ω, the current (I) during the whole procedure was 

0.16 A, the duration (t) of the temperature rise (also the duration of the high resistance increasing) 

was approximately 1 hour. The generated heat (Q) can be estimated from Equation 5. 

Q = P t = Ucell I t = R I2 t (5) 

where P is the electrical power, Ucell is the cell voltage and R is the resultant resistance. 

We can calculate the resultant resistance from Equation 6. 

2 2

723 J
8

(0.16 A) 3600

Q
R

I t s
= =  


 (6) 

Although the calculation contains many approximations and estimates, it shows that the 

resultant resistance, as in the previous section, increased by more than two orders of magnitude 

during over-discharge process (when the potential of the electrode and the temperature greatly 

changed at the same time).  

“Recharge” 

The recharging of an over-discharged cell is shown in Figure 8. 

 
Figure 8. Temperature change due to “recharge” (potential of negative and positive electrode, temperature 

in the vicinity of the negative and the positive electrode, in the electrolyte and in the heat chamber)  



B. Broda and G. Inzelt J. Electrochem. Sci. Eng. 8(2) (2018) 129-139 

doi:10.5599/jese.459 139 

During the recharging, temperature rise was also experienced which was similar to the 

previously described one (during over-discharge) and the heat capacity of the cell was practically 

the same. Based on these results, we can state that the internal resistance of the examined cell 

increased by several orders of magnitude compared to its initial value during the recharging. 

Conclusions 

By investigating a lead-acid test cell, it was proved that the internal resistance highly increased 

during the cell reversal. This process and the increasing gas evolution caused significant 

temperature to rise inside the electrode undergoing the reversal and consequently in the whole 

cell. This is a very reproducible phenomenon which has a serious influence on aging specifically on 

the loss of capacity because there is high temperature increase and gas flow at the same time. 

Acknowledgements: Financial and spiritual support from the Bolyai Collage is gratefully 
acknowledged. 

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