{A comparative study of chemical and physical properties of copper and copper alloys affected by acidic, alkaline and saline environments}


http://dx.doi.org/10.5599/jese.877       373 

J. Electrochem. Sci. Eng. 10(4) (2020) 373-384; http://dx.doi.org/10.5599/jese.877  

 
Open Access: ISSN 1847-9286 

www.jESE-online.org 
Original scientific paper 

A comparative study of chemical and physical properties of 
copper and copper alloys affected by acidic, alkaline and saline 
environments 

Samiul Kaiser1 and Mohammad Salim Kaiser2, 
1Department of Civil Engineering, Bangladesh University of Engineering and Technology, Dhaka-
1000, Bangladesh 
2Directorate of Advisory, Extension and Research Services, Bangladesh University of Engineering 
and Technology, Dhaka-1000, Bangladesh 

Corresponding author: mskaiser@iat.buet.ac.bd; Tel.: +88-02-9663129; Fax: +88-02-9665622 

Received: June 11, 2020; Revised: June 29, 2020; Accepted: July 1, 2020 
 

Abstract 
Chemical and physical behavior including corrosion performance, thermal conductivity and 
visual color change of the copper-based alloys brass and bronze have been studied prior and 
after corrosion in acidic, alkaline and saline media. The concentrations of 0.5 M H2SO4, 0.5 
M NaOH and 0.5 M NaCl were used in which copper and copper-alloy samples were 
immersed and left to corrode at room temperature for 28 days. The experiments were 
performed prior and after corrosion, using conventional gravimetric measurements ac-
companied with measurements of thermal conductivity, microstructure and optical pro-
perties. The color change of different samples was also studied through tristimulus color 
parameter (L*, a* and b*) values. It is concluded that the corrosion rate of copper and 
copper alloys is greater in acidic than in salt and alkaline media. This is due to the extent of 
disruption of the passive film formed on the surfaces. In the cases of alkaline and salt media, 
the passive films on the surface remain stable to a large extent. Small increase of thermal 
conductivity takes place due to formation of a very thin film of oxide and hydroxide bonded 
to the surface. The environment also affects the color of copper and copper alloys by 
chemical changes like oxidation and formation of different intermetallics on the surfaces. A 
microstructural study of experimental materials confirms that corrosion after 28 days 
results in formation of pores on the surfaces in acidic environment, and passive film that 
grows thicker on the surfaces in alkaline and saline environments. Aluminum oxide that is 
more stable than zinc oxide causes better anti-corrosion performance and minimal color 
variation of bronze compared to brass, especially in acidic environment. 
 

Keywords 
Copper-alloys; corrosion; oxidation; thermal conductivity; color; microstructure 

http://dx.doi.org/10.5599/jese.877
http://dx.doi.org/10.5599/jese.877
http://www.jese-online.org/
mailto:mskaiser@iat.buet.ac.bd


J. Electrochem. Sci. Eng. 10(4) (2020) 373-384 PROPERTIES OF COPPER AND COPPER ALLOYS 

374  

 

Introduction 

Pure metals like aluminum, copper, iron, etc. are found quite soft in texture. The strength of these 

materials is gained by adding other elements to the pure metals. In this way alloys are formed [1-3]. 

Several properties of metals like strength, hardness, corrosion resistance, electrical and thermal 

conductivity, resistance, change in color, etc. can be increased or reduced through alloying [4-6].  

In the case of copper, zinc, tin, aluminum, nickel, manganese, and silicon are usually used in an 

approximate order of increasing effectiveness to form copper alloys. Brasses and bronzes are 

considered to be the most renowned families of copper-based alloys which are used frequently in 

daily works. Brass consists of copper and zinc, while bronze is an alloy of copper combined mostly 

with tin, but also with other metals like aluminum, phosphorus, manganese, and silicon. Brass and 

bronze are used in various works, based on their properties. These alloys are used extensively in 

production of heavy load bearing machine, high-speed operation of shaft sliding sleeves and bush 

bearings, automobiles, ships, metallurgy, machinery and other industrial fields. At the same time, 

the application of those alloys is also found in ornamental and building construction industries. 

Varying amounts and proportions of alloying elements are found in those alloys. Thus, a wide range 

of properties and variation in color are seen due to the variation of mixtures [7,8].  

Brass and bronze are used frequently in different environments and for various purposes as they 

show outstanding corrosion behavior. Corrosion defines the degradation of metallic materials which 

is due to various electrochemical and chemical reactions. Corrosion may result into component 

failure in different industrial environments and it is affected by various environment and metal 

related factors [9,10]. 

It is well established in the literature that addition of a substance to improve one property may 

result by unintended effects on other properties.  Although a lot of information can be found about 

the effects of various alloying elements on the mechanical properties of Cu-based alloys, there is no 

systematic information on simultaneous changes of other properties [11-13]. Therefore, the present 

study is focused on evaluating the environmental impact on the physico-mechanical properties of 

Cu and Cu alloys, brass and bronze. This investigation aims to study the effects of ten weight percent 

(10 wt%) of alloying elements Al and Zn, before and after corrosion in 0.5 M acidic, alkaline and 

saline solutions.  

Experimental  

The present study involves copper, brass and bronze samples which were prepared through 

casting of commercially pure copper, zinc and aluminum. A clay-graphite crucible in a natural gas 

fired pit furnace was used for melting these experimental alloys. Full chemical compositions of the 

experimental samples of copper, brass (10.3 wt% Zn) and bronze (9.6 wt% Al), showing contents of 

Al, Zn, Pb, Sn, Fe, Ni, Mn, Si, Cr, Sb and Cu elements, are given elsewhere [10,14].  

The oxide layers from the surface of the cast samples were removed and pieces of 15 x 20 x 150 

mm were cut using a shaper machine. Cold rolling of the cast alloys was carried out with a laboratory 

scale rolling mill of 10HP capacity at 50 % of reduction. In every pass, about 1 mm of deformation 

was given and as a result thickness of the samples was reduced to 7.5 from 15 mm. From the cold 

rolled samples 5 x 20 x 20 mm coupons were obtained and sanded mechanically with emery papers 

of rough and finish grade of 1500 grits. The ageing treatment was conducted in an electrical 

resistance furnace at different temperatures for one hour. Microhardness measurements were 

carried out on the differently aged samples using a Micro Vickers hardness tester where a load of 1 



S. Kaiser and M. S. Kaiser. J. Electrochem. Sci. Eng. 10(4) (2020) 373-384 

http://dx.doi.org/10.5599/jese.877 375 

kg and dwell time of 10 seconds were used. A total of seven readings from different locations were 

taken for every aged sample and average value was calculated.  

Corrosion behavior was tested for 50 % cold rolled cast samples of 3 x 3042 mm size that were 

artificially aged for 60 min at 300 °C. Prior to use, the samples were sanded with emery paper and 

cleaned with ethanol. Afterwards, the samples were dried in forced air, weighted (initial weight, 

Wint) and exposed to different solutions for periods up to 28 days. Stagnant solutions of 0.5 M H2SO4, 

0.5 M NaOH, and 0.5 M NaCl were used as aggressive media. After the designated exposure in the 

solution medium, the samples were removed from the test solution, thoroughly washed with a 

distilled water, dried well in forced air and weighted again (final weight, Wfin). The weight loss, ΔW, 

was calculated in accordance with [15]: 

−
= int finΔ
(W W )

W
A

 (1) 

where ΔW = weight loss (mg/cm2), Wint = initial weight prior to the immersion (mg), Wfin = final 

weight after exposure (mg) and A = area (cm2). 

The corrosion rate, Kcorr (mm/year), was evaluated on the basis of 

=
corr

ΔK W
K

TD
  (2) 

where K = unit conversion constant (87.6 for mm/year unit), T = time of exposure (h) and D = density 

of metal (g/cm3). 

An electric conductivity meter, type 979 was used for measuring the electrical conductivity of the 

alloys after different immersion conditions. Thermal conductivity was calculated through the 

Wiedemann–Franz law from measured electrical conductivity data [16]. The images of the corroded 

samples were taken with a digital single-lens reflex (DSLR) camera to examine the visual changes. 

The sample images were analyzed through MATLAB software for determining the tristimulus color 

parameter (L*, a* and b*) values. The changes of these values with respect to the immersion time 

in different environments were shown graphically. The washed and dried samples were observed 

by OPTIKA microscope and some selected photomicrographs were taken.     

Results and discussion 

Gravimetric analysis of corrosion effect 

The change of corrosion rate with immersion time for copper, brass and bronze samples, 

previously aged at 300 °C for one hour, were calculated using Eq. (1) and Eq. (2). The values of 

corrosion rate in 0.5 M solutions forming acidic, alkaline and saline environments are plotted in 

Figure 1(a), 1(b) and Fig. 1(c), respectively.  

The corrosion rate Kcorr for all experimental material samples is the highest in 0.5 M H2SO4. The 

results observed in H2SO4 media are ascribed to the high aggressive attack of sulphide ions, leading 

to the disruption of passive films formed on the metal surfaces. However, the corrosion rate is 

slightly lower than that observed at the earlier stage of immersion, suggesting that the passive films 

formed on the surface of the experimental samples are stable [17,18]. In the case of alkaline 

solution, the higher corrosion rate at the initial stage could be due to the segregation of copper 

oxide formed in the matrix. The lower corrosion rate is ascribed to the protective nature of copper 

hydroxide film formed on the metal surface [19]. After initial time period, corrosion rates start to 

decrease with time and attain a roughly constant value for all samples.   

 

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J. Electrochem. Sci. Eng. 10(4) (2020) 373-384 PROPERTIES OF COPPER AND COPPER ALLOYS 

376  

 a b 

 
c 

 
Figure 1. Variation of corrosion rate of copper, brass and bronze with immersion time in (a) 

acidic, (b) alkaline and (c) saline environment for 28 days 

In the case of salt solution, lower corrosion rates are observed for all three materials. In the early 

stages of corrosion in 0.5 M NaCl solution, an oxide film grows on the surfaces. The result in the salt 

solution seems neutral, i.e., neither weight gain nor weight loss was observed. The lower corrosion 

rate is accredited to the formation of passive films on the surface of the samples, which lead to the 

temporary seizure of the corrosion attack, while the higher corrosion rate is due to the gradual 

breakdown of the passive films by the corrosion attack within several days [20,21]. Pure copper in 

acidic solution form Cu2O and CuSO4, while brass and bronze form additional ZnO and ZnSO4, and 

Al2O3 and Al2(SO4)3, respectively. Dissolution of CuSO4 and ZnSO4 in acidic solution is higher than 

Al2(SO4)3, what caused lower corrosion rate of bronze metal. In addition, Al2O3 film inhibits the 

dissolution of the bronze metal. In alkaline and saline media, pure copper forms CuO, while brass 

and bronze form additional ZnO and Al2O3 layers on the surfaces. These layers are very much 

protective, providing enhanced corrosion resistance [22,23].  

Thermal conductivity  

Time changes of thermal conductivity of copper, brass and bronze samples previously immersed in 

acidic, alkaline and saline media are plotted in Figure 2(a), 2(b) and Fig. 2(c), respectively. In each case, 

the thermal conductivity of the sample increased initially due to the formation of oxide layer on the 

surface which caused higher conductivity. After prolonged exposure, the thermal conductivity of the 

0 5 10 15 20 25 30
-0.05

0.00

0.05

0.10

0.15

0.20

0.25
C

o
rr

o
s
io

n
 r

a
te

 K
c
o

rr
, 

m
m

/y
e
a

r 

Immersion time, days

 Copper

 Brass

 Bronze

0 5 10 15 20 25 30
-0.05

0.00

0.05

0.10

0.15

0.20

0.25

C
o

rr
o

s
io

n
 r

a
te

 K
c
o

rr
, 

m
m

/y
e
a

r

Immersion time, days

 Copper

 Brass

 Bronze

0 5 10 15 20 25 30
-0.05

0.00

0.05

0.10

0.15

0.20

0.25

C
o

rr
o

s
io

n
 r

a
te

, 
K

c
o

rr
, 

m
m

/y
e
a

r

Immersion time, days

 Copper

 Brass

 Bronze

K
co

rr
 /

 m
m

 y
e

a
r-

1
 

K
co

rr
 /

 m
m

 y
e

a
r-

1
 

K
co

rr
 /

 m
m

 y
e

a
r-

1
 

https://www.sciencedirect.com/topics/engineering/corrosion-resistance


S. Kaiser and M. S. Kaiser. J. Electrochem. Sci. Eng. 10(4) (2020) 373-384 

http://dx.doi.org/10.5599/jese.877 377 

experimental materials in acid solution slightly decreased due to the diffusion of aggressive ions 

leading to porosity of the surface. In NaOH solution, thermal conductivity decreased because of the 

formation of black corrosion product layer that becomes thicker with increase of immersion time. A 

trend of initial conductivity increase, followed by a decrease is observed also in the saline solution 

within 28 days. Copper forms a very thin film of copper oxide and hydroxide bonded to its surface, 

increasing the thermal conductivity. The corrosion attack is restored after some days due to the 

gradual disruption of the passive films which caused conductivity decrease [21,24]. Brass and bronze 

form additional zinc oxide and aluminum oxide, respectively that together with copper oxide caused 

small effects on thermal conductivity.  
 

 a b 

 
c 

 
Figure 2. Variation of thermal conductivity of copper, brass and bronze with immersion time in 

(a) acidic, (b) alkaline and (c) saline environment for 28 days   

Optical observations  

DSLR camera optical images of the experimental samples of copper, brass and bronze aged at 

300 °C for one hour before and after corrosion in acidic, alkaline and salt media, were taken at 

different immersion times and recorded in Figure 3. The images show that polished copper is of a 

reddish-brown color, the color of brass moves from red to gold, while the color of aluminium bronze 

is dull gold depending on the levels of zinc and aluminium added to alloy. The surface colors of 

samples obviously change with increase of immersion time, what points toward the formation of 

films on the surfaces in different environments. 

0 5 10 15 20 25 30
50

100

150

300

350

400

T
h

e
rm

a
l 
c
o

n
d

u
c
ti
v
it
y
, 

W
/m

.k

Immersion time, days

 Copper

 Brass

 Bronze

0 5 10 15 20 25 30
50

100

150

300

350

400

T
h

e
rm

a
l 
c
o

n
d

u
c
ti
v
it
y
, 

W
/m

.k

Immersion time, days

 Copper

 Brass

 Bronze

0 5 10 15 20 25 30
50

100

150

300

350

400

T
h

e
rm

a
l 
c
o

n
d

u
c
ti
v
it
y
, 

W
/m

.k

Immersion time, days

 Copper

 Brass

 Bronze

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J. Electrochem. Sci. Eng. 10(4) (2020) 373-384 PROPERTIES OF COPPER AND COPPER ALLOYS 

378  

 
Figure 3. DSLR camera images following color changes of polished copper, brass and bronze 
samples prior and after corrosion in acidic, alkaline and saline environment for 1 and 28 days  

Figure 3 shows that the change of surface color before and after corrosion is more noticeable in 

the alkaline solution than other environments. In the acidic solution, a mixed film composed of 

copper oxide and copper sulphate is formed. However, in the presence of the aggressive sulphate 

ions, the passive film may breakdown continuously and so, the change in color is minimal. After 

prolonged immersion time, the passive films might be stable, causing higher color variation. After 

corrosion for either 1 or 28 days in NaOH solution, the surface colors of all samples have changed 



S. Kaiser and M. S. Kaiser. J. Electrochem. Sci. Eng. 10(4) (2020) 373-384 

http://dx.doi.org/10.5599/jese.877 379 

drastically because of thick black corrosion product layers formed on all surfaces. In the saline 

environment, copper forms a thin layer of copper oxide and hydroxide which is bonded to its 

surface. At higher immersion time, the corrosion attack is restored after some days, causing the 

gradual disruption of the passive film [25,26]. For this reason, the color change is minimal in the 

saline environment. Brass and bronze form zinc oxide and aluminum oxide, respectively, with 

copper oxide formed in all environments. Aluminum oxide is more protective and so, small 

variations of bronze color are seen, especially in acidic solution. In alkaline and saline environments, 

these additional oxides accelerate the color variation. The color change of all three alloys in alkaline 

solution after 1 day is very strong, but after 28 days the variation is almost indifferentiable due to 

formation of thick layer of corrosion products at the surfaces.  

The color change of all samples is examined by tristimulus color parameter, L*, a* and b* values. 

L* represents the lightness, where darkest black is at L* = 0, and brightest white at L  = 100, while 

a* represents the green–red component of the color, with green and red in the negative and 

positive direction, respectively. Analogously, b* represents the blue–yellow component of the color, 

with blue and yellow in the positive and negative direction, respectively. The graphical 

representations of change of these values with immersion time are shown in Figures 4-6. The 

variations of L* value with the immersion time in acidic, alkaline and saline solution are shown in 

Figure 4(a), 4(b) and Fig. 4(c), respectively.   
 

 a b 

 
c 

 
Figure 4. Change of tristimulus color parameter L* (0 = black; 100 = white) of copper, brass and bronze 

samples with immersion time in (a) acidic, (b) alkaline and (c) saline environment for 28 days  

0 5 10 15 20 25 30
0

10

20

30

40

50

60

L
* 

fr
o

m
 b

la
c
k
 (

0
) 

to
 w

h
it
e

 (
1

0
0

),
 A

U

Immersion time, days

 Copper

 Brass

 Bronze

0 5 10 15 20 25 30
0

10

20

30

40

50

60

L
* 

fr
o

m
 b

la
c
k
 (

0
) 

to
 w

h
it
e

 (
1

0
0

),
 A

U

Immersion time, days

 Copper

 Brass

 Bronze

0 5 10 15 20 25 30
0

10

20

30

40

50

60

L
* 

fr
o

m
 b

la
c
k
 (

0
) 

to
 w

h
it
e

 (
1

0
0

),
 A

U

Immersion time, days

 Copper

 Brass

 Bronze

L*
 /

 a
. 

u
. 

L*
 /

 a
. 

u
. 

L*
 /

 a
. 

u
. 

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J. Electrochem. Sci. Eng. 10(4) (2020) 373-384 PROPERTIES OF COPPER AND COPPER ALLOYS 

380  

From the graphs shown in Figure 4, it is clear that L* value is higher in acidic solution and lower 

in alkaline solution, while L* value in saline solution is higher than alkaline solution but lower than 

acidic solution. In acidic solution, the thicker blue layer of hydrated copper sulphate salt 

(CuSO4×H2O) film is formed by a chemical reaction at the surface, what caused decreased L* value. 

Its intensity is lower because this kind of the oxide film is dissolved more quickly in the acidic solution 

[27,28]. In the case of alkaline solution, copper forms Cu2O and light blue precipitate of Cu(OH)2 

which are deposited on the surface of the oxide as reported previously [19,29]. These layers 

drastically change L* value of the experimental materials. Similarly, in the saline solution, one has 

to consider formation of brownish corrosion film consisted of CuO, Cu2O and greenish particles, 

dicopper chloride trihydroxide Cu2(OH)3Cl [20,30]. Additional ZnO and Al2O3 are formed with CuO 

for brass and bronze respectively as discussed earlier. These oxides protect from corrosion, and 

protect the color of the experimental materials surfaces. 
 

 a b 

 
c 

 
Figure 5. Change of tristimulus color parameter a* (from green (-) to red (+)) of copper, brass and bronze 

with immersion time in (a) acidic, (b) alkaline and (c) saline environment for 28 days  

The a* and b* values vs. immersion time graphs for different environments are presented in 

Figure 5 and Figure 6, respectively. The graphical scenario shows greater values of a* and b* for 

acidic and saline solutions, but lower values in the alkaline solution. Quick dissolvement of oxide 

film in the solution results by less variation of the sample from the original in case of acidic solution. 

Thus, for all three materials, red and yellow components are more dominant and so a* and b* values 

are higher for acidic solution. Similarly, the values are higher in the saline condition because of less 

0 5 10 15 20 25 30
-5

0

5

10

15

20

25

30

35

a
* 

fr
o

m
 g

re
e

n
 (

-)
 t

o
 r

e
d

 (
+

),
 A

U

Immersion time, days

 Copper

 Brass

 Bronze

0 5 10 15 20 25 30
-5

0

5

10

15

20

25

30

35

a
* 

fr
o

m
 g

re
e

n
 (

-)
 t

o
 r

e
d

 (
+

),
 A

U

Immersion time, days

 Copper

 Brass

 Bronze

0 5 10 15 20 25 30
-5

0

5

10

15

20

25

30

35

a
* 

fr
o

m
 g

re
e

n
 (

-)
 t

o
 r

e
d

 (
+

),
 A

U

Immersion time, days

 Copper

 Brass

 Bronze

a
*

 /
 a

. 
u

. 

a
*

 /
 a

. 
u

. 

a
*

 /
 a

. 
u

. 



S. Kaiser and M. S. Kaiser. J. Electrochem. Sci. Eng. 10(4) (2020) 373-384 

http://dx.doi.org/10.5599/jese.877 381 

deviation from original colors. But in alkaline condition, deposition of copper oxides provides darker 

layers on the surface where the green and blue components are dominant. This is the reason of 

lower values of a* and b* in alkaline condition for all three materials. 

In the case of acidic conditions, a* values of brass and bronze are lower than copper because of 

the presence of ZnO for brass and Al2O3 for bronze, which both increase green component of the 

color. For the same reason, b* value is higher for these two alloys rather than pure copper as yellow 

component is increased. In alkaline environment all three materials have almost same type of a* 

and b* values as all the oxide layers sustain over the materials. In salt solution all three materials 

retain almost their original colors. 
 

 a b 

 
c 

 
Figure 6. Change of tristimulus color parameter b* (from blue (-) to yellow (+)) of copper, brass and bronze 

with immersion time in (a) acidic, (b) alkaline and (c) saline environment for 28 days 

Optical microscopy 

The worn surfaces of aged copper, brass and bronze samples before and after immersion 

in different corrosive environments are presented in Figure 7.  
Before corrosion test, all polished materials showed some scratches on the surfaces which may 

be formed by the sandpaper during surface preparation. It is known that addition of alloying 
elements changes the grain structure of all alloys. This change in microstructure can be character-
rized by the increased dark tone or lighter tone in the micrograph of the experimental materials. 
Immersed in 0.5 M of acidic, alkaline and saline solution for 1 day, some defects like pits are 
generally formed in the conversion layers of the experimental materials, but the quantity of the pits 
per area is relatively low. 

0 5 10 15 20 25 30
-5

0

5

10

15

20

25

b
* 

fr
o

m
 b

lu
e

 (
-)

 t
o

 y
e
ll
o

w
 (

+
),

 A
U

Immersion time, days

 Copper

 Brass

 Bronze

0 5 10 15 20 25 30
-5

0

5

10

15

20

25

b
* 

fr
o

m
 b

lu
e

 (
-)

 t
o

 y
e
a

ll
o

w
 (

+
),

 A
U

Immersion time, days

 Copper

 Brass

 Bronze

0 5 10 15 20 25 30
-5

0

5

10

15

20

25

b
* 

fr
o

m
 b

lu
e

 (
-)

 t
o

 y
e
ll
o

w
 (

+
),

 A
U

Immersion time, days

 Copper

 Brass

 Bronze

b
*

 /
 a

. 
u

. 

b
*

 /
 a

. 
u

. 

b
*

 /
 a

. 
u

. 

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J. Electrochem. Sci. Eng. 10(4) (2020) 373-384 PROPERTIES OF COPPER AND COPPER ALLOYS 

382  

 
Figure 7. Optical micrographs of the polished copper, brass and bronze prior and after corrosion in acidic, 

alkaline and saline environment for 1 and 28 days.  

The images of the alloys studied after 28 days of exposure in 0.5 M H2SO4 solution clearly show 

presence of pores due to the uniform degradation of the alloys [31]. The aggressive attack of the 

sulphide ions disrupts the passive film formed on the surface of the alloys. The images referring to 

100 m 



S. Kaiser and M. S. Kaiser. J. Electrochem. Sci. Eng. 10(4) (2020) 373-384 

http://dx.doi.org/10.5599/jese.877 383 

NaOH solution shows a black corrosion product layers on the alloys surfaces which grow thicker with 

the corrosion proceeding. It is worth noting that the corrosion layer formed in the alkaline solution 

seems more compact and homogenous [32]. Also, this layer is not porous. The images obtained in 

NaCl solution show presence of passive films on the alloys surface. Only some spots are observed 

due to the gradual disruption of the passive film [33]. Some variation is observed in cases of brass 

and bronze. In acidic solution, bronze forms Al2O3 and Al2(SO4)3 which dissolution rate is lower than 

Cu2O, and CuSO4 formed by pure copper, and ZnO and ZnSO4 formed by brass. As a consequence, 

the minimum pores are formed on the bronze surfaces. Brass and bronze form additional ZnO and 

Al2O3 layer, respectively, with CuO on the surfaces in alkaline and saline media. Due to this protective 

layer, brass and bronze surfaces show the extra mark of corroded products [23]. 

Conclusions 

Copper and copper-based alloys brass and bronze samples showed higher corrosion rate in acid 

solution compared to alkaline and saline environments, what is due to gradual disruption of passive 

films and segregation of the copper oxide film in the matrix. It seems that Al2O3 layer is especially 

protective in acidic environment, causing the lower corrosion rate of bronze. The thermal 

conductivity of all three experimental materials increased slightly after corrosion in acid, basic and 

saline environments due to the formation of oxide layers which decreased surface roughness.  

The tristimulus color parameter L*, a* and b* values increase in acidic solution due to formation 

of blue layer of hydrated copper sulfate (CuSO4×H2O) salt film that is dissolved quickly from the 

surface. The additional production of ZnO in brass and Al2O3 in bronze is also responsible for 

deviations of L*, a* and b* values from pure copper. In alkaline solution, light blue precipitate of 

copper hydroxide Cu(OH)2 is deposited on the surfaces, what decreases the tristimulus color 

parameter. Similarly, in the saline solution there is formation of greenish particles, di-copper 

chloride trihydroxide Cu2(OH)3Cl, but the gradual breakdown of the passive films brought about by 

the corrosion attack within several days causes a lower variation in color than in alkaline media. 

Evidence of formation of crystallographic pitting is found in NaCl solution for exposure times up to 

28 days, while an intensive pit formation is observed in the acidic medium. Aluminum forms a thick 

film of oxide in alkaline. 

Acknowledgements: This experimental work is assisted by DAERS office and the authors would like to thanks 
to the Department of Chemical Engineering of Bangladesh University of Engineering and Technology, Dhaka-
1000 for giving the laboratory facilities. 

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[2] J. A. Rogers, Powder Metallurgy 20(4) (1997) 212-220. 
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