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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 47, 2016 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Angelo Chianese, Luca Di Palma, Elisabetta Petrucci, Marco Stoller
Copyright © 2016, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-38-9; ISSN 2283-9216 

Nanostructured Anode Material for Li-Ion Battery Obtained by 
Galvanic Process 

Cristina Cocchiara*, Rosalinda Inguanta, Salvatore Piazza and Carmelo Sunseri 

a
Laboratorio di Chimica Fisica Applicata, Dipartimento di Ingegneria Chimica Gestionale Informatica Meccanica, Università 

di Palermo, Viale delle Scienze, 90128 Palermo (Italy) 
cocchiara.cristina@gmail.com 

This work focused on the synthesis and characterization of nanostructured lead hydroxide chloride (PbOHCl) 
that is an innovative anode material for lithium-ion batteries (LIBs). In particular, we have obtained 
nanostructures of mixed PbOHCl and lead metal, directly into the pores of a commercially available alumina 
membrane, acting as template. The process was based on galvanic displacement reaction that was carried 
out in a two-compartment electrochemical cell without the use of an external power supply. This simple and 
cheap procedure gives regular array of Pb/PbOHCl composite nanowires. 
To obtain nanostructured electrodes is a significant result because, it’s well known that nanostructures have a 
variety of exceptional properties for Li-ion batteries applications such as high surface area, low diffusion path 
and good dimensional stability. This last property is fundamental because the active material of Li-ion battery 
are subject to very high strains due to volume change that occurs during charge/discharge cycles. In addition, 
the presence of lead creates a conductive network that reduces the resistivity of PbOHCl electrode.  

1. Introduction 
Electrochemical energy storage plays a fundamental role for efficient management of electrical energy. 
Among the different storage systems, lithium-ion batteries are considered the most challenging. Although their 
large commercial diffusion, they are still matter of hard research efforts, in order to improve costs, safety and 
energy density, that is low in comparison with fossil fuels (Scrosati, 2011). In this context, prevailing research 
efforts are directed toward finding alternatives to the current electrode materials, in order to extend the use of 
these batteries to applications of interest for the future.  
Shu et al. (2013) early proposed the use of PbOHCl as anode for lithium-ion batteries, in order to improve the 
performance of lead-based anodes. In fact, although this material has shown clear advantages in terms of 
capacity and cost, it suffers severe limitations due to low cyclability. The high charge capacity is attributed to 
the formation of Li-Pb alloys with high content of lithium. The low lifetime is due to the fast degradation of the 
electrode due to its high expansion/contraction coupled to lithium alloying/de-alloying reactions (Martos et al., 
2003; Ng et al., 2006; Pan et al., 2009). 
The results by Shu et al. (2013) showed that performances of lead-based electrodes could be improved by a 
combined insertion of chloride and hydroxyl functional groups. By this way, it is possible to achieve a 
theoretical capacity of about 661 Ah/kg. The supposed reaction mechanism, involves initial conversion of 
PbOHCl into Pb, LiCl and LiOH. Then, the alloying reaction of Pb with Li can take place. According to this 
mechanism, the active material during repeated cycles undergoes pulverization and breakdown phenomena. 
Starting from the results by Shu et al., (2013), we have investigated the synthesis and characterization of 
nanostructured PbOHCl. This is a key issue because nanostructures guarantee a high surface area enhancing 
the battery specific energy. In addition, they can limit active material pulverization because are able to better 
absorb mechanical stresses due to volume changes during charge/discharge cycles. The use of 
nanostructures also increases the penetration of Li alloying/de-alloying due to less diffusion path (Goriparti et 
al., 2014; Cheng et al., 2008). Consequently, nanostructured electrodes can sustain high charge/discharge 
rate favoring the possible use of these electrodes in batteries dedicated to applications requiring performances 
that only nanostructured materials can give. 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1647013

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Cocchiara C., Inguanta R., Piazza S., Sunseri C., 2016, Nanostructured anode material for li-ion battery obtained by 
galvanic process, Chemical Engineering Transactions, 47, 73-78  DOI: 10.3303/CET1647013

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In this work, we present the preliminary results of an innovative fabrication procedure that permit to obtain 
PbOHCl/Pb directly into the channels of a nanoporous template by a galvanic process (Inguanta et al., 2008, 
2009a; Battaglia et al., 2013).  

2. Experimental 

For the fabrication of nanostructures, commercial anodic alumina membranes (Whatman, Anodisc 13), having 
a nominal pore diameter of about 200 nm, nominal thickness of 60 µm, porosity of 25-30% and pore surface 
density of 1012-1013 pores/m2, were used as template. Prior to deposition, a thin gold layer was sputtered on 
one side of alumina membrane to make this surface electrically conductive (Inguanta et al., 2009b). A scheme 
of the experimental apparatus used for the fabrication of the nanostructures is showed in Figure 1. The 
fabrication process is based on galvanic contact between the gold layer at the base of membrane pores and a 
less noble metal, to create a potential difference. The galvanic couple was immersed in two different solutions 
contained into two separate cells ionically linked by a salt bridge. An adhesive copper tape at the bottom of 
membrane guaranteed the electrical continuity with the external circuit. 

 

Figure 1: Scheme of the arrangement used for the fabrication of nanowires. 

Working electrode consisted in gold covered anodic alumina membrane (AAM), with a surface area of the 
order of 0.785 cm

2, that was immersed in the cathodic compartment containing 0.033 M PbCl2 aqueous 
solution. In the anodic compartment, a sacrificial aluminium, with a surface area of 3 cm2, was immersed in 1 
M KCl solution. Deposition was conducted at room temperature for 24 hours.  

The crystallographic structure of the nanowires was investigated by X-ray diffraction analysis (XRD), (Rigaku, 
D-MAX 25600 HK). All X-ray analyses were conducted in the 2ϑ range from 5° to 80° with a step of 0.0263° 
using the Cu Kα radiation (λ=1.54 Å). Diffraction patterns were analyzed by comparison with ICDD database 
(ICDD, 2007). Nanowires morphology was investigated using a scanning electron microscopy (SEM, FEI 
mod.: QUANTA 200 FEG) equipped with an X-ray energy dispersive spectrometer (EDS). This analysis was 
carried out before the dissolution of AAM template to avoid deposit damage. Prior to SEM examination, 
samples were sputtered with a thin layer of gold in order to form a conductive film. Raman spectra were 
obtained at room temperature using a Renishaw (inVia model) micro-Raman spectrometer equipped with an 
Nd-Yang (λ=532 nm) laser giving a spot size of 2 µm. Prior to Raman analysis, the system was calibrated by 
polycrystalline Si (520 cm-1).  

3.  Results and Discussion 

The scheme of the apparatus for the deposition is shown in Figure 1. The key feature is the galvanic contact 
between cathode (gold film covering the AAM bottom pores) and aluminum, acting as sacrificial anode. When 
the electrodes were immersed in the respective solutions, oxidation of aluminum occurred, with consequent 
electron flow through the external circuit from anodic area to the cathodic one, where the following reactions 
occurred: 

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Pb2+  +  2e-                 Pb                       (E0= -0.13 V/NHE)    (1) 

2H+  +  2e-                             H2                                 (E= 0 - 0.059 pH  V/NHE)    (2) 

4H+ + O2 + 4e
-            2H2O                  (E=1.23 - 0.059 pH  V/NHE)    (3) 

The pH increase due to reactions Eq(2) and Eq(3) led to chemical precipitation of PbOHCl into the template 
channels, according to the reaction: 

Pb2+ + H2O + Cl
-             PbOHCl + H+   (4) 

According to these reactions, the almost simultaneous occurrence of galvanic deposition Eq(1), and chemical 
precipitation Eq(4) likely should have to fill up pore template with Pb/PbOHCl composite compound.  

      

 

      
 

Figure 2: (a) SEM image of the template cross section view after galvanic deposition; (b), (c), and (d) high 
magnification images of bottom, central and top section, respectively. 

This hypothesis was confirmed by the results of different analyses of the deposit. Initially, morphological 
analysis was carried out. Figure 2a shows the SEM image of alumina template cross section view after 
galvanic deposition. In this image, it is still possible to distinguish the vertical and parallel channels featuring 
the AAM template morphology. Porous nanostructures uniformly fill up for about 20 µm the template bottom in 
contact with the gold film (top of the Figure 2a). At higher magnification, this morphology is shown in Figure 
2b. Figure 2a shows also that a tubular shape deposit covers the channel walls, at the middle section. This 

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morphology is better visible at the higher magnification shown in Figure 2c. Besides, Figure 2a shows that 
very compact nanostructures fill up top of the template, for about 5 µm in length. This morphology is better 
evidenced in Figure 2d. An abundant deposit covering the template surface is shown at the bottom of Figure 
2a.  
The chemical composition of the nanostructures was identified by EDS analysis carried out in different 
sections of the template. Elemental analysis revealed the only presence of the expected elements according 
to reactions Eq(1) and Eq(4): Pb, Cl, O. In addition, Al due to alumina membrane was also revealed. The Cl 
atomic fraction (Cl/(Cl+Pb)) was 30% at bottom and middle section of the template, while reached about 48% 
at top. Since Cl atomic fraction in PbOHCl is 50%, we can conclude that an excess of metallic lead was 
deposited at the bottom and middle height of the template pores. Instead, the deposit at the top of the 
channels and on the external surface was practically pure PbOHCl. These findings give a first confirm about 
formation of PbOHCl with the excess of Pb present in metallic form. Thus, a mixture of Pb/PbOHCl at about 
43% of PbOHCl was approximately estimated at the bottom of the membrane.  
A further confirm of the above assumption was found by XRD and Raman analysis. X-ray diffraction showed 
only PbOHCl which crystallizes in orthorhombic phase. As shown in Figure 3, the peaks of PbOHCl found in 
the ICDD database (ICDD card 31-680) exactly coincide with that ones of our sample. Instead, lead (ICDD 
card 4-686) is difficult to identify, because its main peak is located at 31.3°, among the two peaks of PbOHCl 
at 31.138° and 31.475°. 

 

Figure 3: Diffraction patterns of the sample of Figure 2. For comparison, the peaks of Pb and PbOHCl of the 
ICDD cards are also reported. 

In Figure 4, the Raman spectrum of the same sample is reported. For comparison, PbOHCl powder 
(hydrothermally prepared) and lead foil spectra were also acquired, in order to better identify the peaks in the 
spectrum of our samples. By comparing the spectrum of our sample with that one of PbOHCl powder, it can 
be observed that they are coincident except for the mode at about 139 cm

-1, which is present only in the 
spectrum of sample. This mode can be probably associated at the presence of lead in mixture with PbOHCl, 
because it is almost coincident with the main Raman mode present in the spectrum of lead foil, that is located 
at about 141 cm-1. The Raman shift of about 2 cm-1 is within the instrument detection limits. Thus, Raman 
spectroscopy confirms the results of EDS and XRD analyses supporting the formation of Pb/PbOHCl 
composite nanowires by galvanic deposition. This is a significant finding, because indicates the possibility of 
synthesizing a compound of high applicative interest by a cheap and facile procedure. 

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Figure 4:  Raman spectra of the sample of Figure 2. For comparison, also the spectrum of the PbOHCl 
powder and of pure lead foil were reported. 

In the light of these findings, we can shortly summarize the global process leading to the formation of 
Pb/PbOHCl. Initially, the hydrogen evolution reaction Eq(2), localized at the pore bottom, leads to a porous 
morphology. As pH increases inside the channels, precipitation of Pb/PbOHCl is occurring with progressive 
increase of the ohmic drops due to the high electric resistance of the precipitated phase, even if the presence 
of metallic lead guarantees the electrical continuity with gold film. Consequently, the base generation reaction 
continues inside the pores but at lower rate, because it takes place on Pb/PbOHCl. Being insulating, the 
reactions proceed at a lower rate than the initial one, determining a reduction of the quantity of Pb and 
PbOHCl deposited at the middle section. Besides, in this zone, the low rate of Pb/PbOHCl precipitation 
competes with the detachment rate of the hydrogen bubbles, which accumulate inside the pore forcing the 
deposit to assume a tubular shape, as demonstrated by other studies (Battaglia et al., 2013; Inguanta et al., 
2011). Close to the pore inlet, solution is oxygen richer than interior because the mass transport is easier in 
this zone. Therefore, reaction Eq(3) contribution to base generation is enhanced with consequent fast and 
abundant precipitation of PbOHCl alone.  

4. Conclusions 

A new method to obtain Pb/PbOHCl nanostructures without supplying external electrical energy was 
developed. The nanostructures were grown directly inside the channels of anodic alumina membrane used as 
template. For this purpose, a specific experimental arrangement based on galvanic contact between two 
differently noble metals was used. By this way, PbOHCl mixed with Pb metal was obtained. The presence of 
Pb metal is a key aspect for the application of these nanostructures as active anode material for Li-ion battery, 
because it creates a conductive network that reduces the PbOHCl resistivity. Morphology of the deposit was 
studied by SEM analysis that showed a uniform array of nanowire grown for a length of 20 µm at the bottom of 
membrane in contact with gold. Close to the top and on the surface exposed to the solution, a pure PbOHCl 
deposit was obtained. EDS, X-Ray diffraction and Raman spectroscopy, confirmed these results. XRD 
analyses revealed also that the deposit was crystalline. Further work will be conducted for exploring the 
application of this deposit. 

Reference  

Battaglia M., Piazza S., Sunseri C., Inguanta R., 2013, Amorphous silicon nanotubes via galvanic 
displacement deposition, Electrochem. Commun. 34, 134-137 

Cheng F., Tao Z., Liang J., Chen J., 2008, Template-directed materials for rechargeable lithium-ion batteries, 
Chem. Mater. 20, 667-681 

Goriparti S., Miele E., De Angelis F., Di Fabrizio E., Zaccaria R. P., Capiglia C., 2014, Rewiew on recent 
progress of nanostructured anode materials for Li-ion batteries, Journal of Power Sources 257, 421-443 

Inguanta R., Ferrara G., Piazza S., Sunseri C., 2009b, Nanostructures Fabrication by Template Deposition in 
Anodic Alumina Membranes, Chem. Eng. Trans. 17, 957-962 

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Inguanta R., Ferrara G., Piazza S., Sunseri C., 2011, Fabrication and characterization of metal and metal 
oxide nanostructures grown by metal displacement deposition into anodic alumina membranes, Chem. 
Eng. Trans. 24, 199-204 

Inguanta R., Ferrara G., Piazza S., Sunseri C., 2012, A new route to grow oxide nanostructures based on 
metal displacement deposition. Lanthanides oxy/hydroxides growth, Electrochimica Acta 76, 77-87 

Inguanta R., Piazza S., Sunseri C, 2009a, Synyhesis of self-standing Pd nanowires via galvanic displacement 
deposition, Electrochem. Commun. 11, 1385-1388 

Inguanta R., Piazza S., Sunseri C., 2008, Novel procedure for the template synthesis of metal nanostructures, 
Electrochem. Commun. 10, 506-509 

International Centre for Diffraction Data, 2007, Power Diffraction File, Philadelphia, PA (card n. 4-686 for 
Martos M., Morales J., Sanchez L., Lead-based systems as suitable anode materials for Li-ion batteries, 2003, 

Electrochimica Acta 48, 615-621 
Ng S.H, Wang J., Konstantinov K., Wexler D., Chen. J, Liua H.K, 2006, Spray pyrolyzed PbO-Carbon 

nanocomposites as anode for Lithium-Ion batteries, J. Electrochem. Soc.153, A787-A793 
Pan Q., Wang Z., Liu J., Yin G., Gu M., 2009, PbO-C core-shell nanocomposites as an anode material of 

lithium-ion batteries, Electrochem. Commun. 11, 917-920 
Pb,31-680 for PbOHCl) 

Scrosati B., 2011, Review History of lithium batteries, J. Solid State Electrochem., DOI: 10.1007/s10008-011-
1386-8 

Shu J., Ma R., Shao L., Shui M., Wang D., Wu K., Long N., Ren Y., 2013, Hydrothermal fabrication of lead 
hydroxide chloride as a novel anode material for lithium-ion batteries, Electrochimica Acta 102, 381-387  

 

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