Research to Prevent Discoloration of Silver Traditional Handicrafts
Wonsub Chung
1
and Byunghyun Shin
2
1
Cultural Heritage Preservation Research Institute, Pusan National University, Busan (Korea)
2
Development of Material Science and Engineering, Pusan National University, Busan (Korea)
Keywords: prevent discoloration of silver, 1.5v battery, aluminum anode.
Abstract: Why does silver (Ag), which are classified as precious metals such as gold (Au), platinum (Pt), and palladium
(Pd), easily discolor in the atmosphere? The reason is that gold, platinum, and palladium do not react well
with the discoloration atmosphere to the extent that they exist as metals in nature. However, although silver
exists as natural silver, the amount is not large. Most of them exist in nature as silver oxide, silver chloride
and silver sulfide. For people to use it, it is much more effective to reduce it to pure metallic silver than silver
oxide, silver chloride, and silver sulfide (gloss, electrical and thermal conductivity, workability, etc.), so it is
unstable by using reducing agents such as carbon monoxide or hydrogen gas. It is made of metal and used.In
this study, as a result of conducting research to prevent discoloration of silver, the following results were
obtained.1) If the power of about 1.5v 2nd battery was connected in the air, the discoloration of silver could
be prevented by supply of electrons.2) It was possible to prevent discoloration of silver by promoting the
electrochemical reaction by contacting aluminum anode, which is a more active metal than silver.
1 INTRODUCTION
The silver (Ag) metal classified as a noble metal such
as gold (Au), platinum (Pt), and palladium (Pd), but
it well discolored in the atmosphere. This is because
gold, platinum, and palladium are not well reacted
with the discoloration atmosphere to the extent that
they exist in nature as a metal. But silver is a
compound rather than a silver pure metal. Mostly
silver oxide, silver chloride and silver sulfide exist in
nature. In order to smelt pure metallic silver, it must
be reduced by supplying energy from the outside. In
this case, the produced metal is easily discolored due
to internal energy non-uniformity and impurities
(copper, tin, etc.). The silver metal is also supplied
with energy from the outside when the external
energy required for the reduction of silver is added
and when it is made into chains or plates. Moving in
the direction of reducing this energy is more stable,
so it tends to discolor and decrease in intensity. For
these reason, the metal is in an unstable state, so the
metal itself is trying to return to stable oxides, sulfides
and chlorides, which is why the color of the metal
changes.
In particular, the discoloration is severe as shown
in the following Fig. 1.
Figure 1: The causes of discoloration of silver are as
follows. Silver metal is stable to water and oxygen but
reacts with ozone (O3) to form silver oxide (Ag2O) and
easily reacts with sulfur (S) or sulfur compounds (such as
hydrogen sulfide, H2S) In this case, the color is discolored.
This is because silver is blackened if it is used for a long
time.
Chung, W. and Shin, B.
Research to Prevent Discoloration of Silver Traditional Handicrafts.
DOI: 10.5220/0010304700003051
In Proceedings of the International Conference on Culture Heritage, Education, Sustainable Tourism, and Innovation Technologies (CESIT 2020), pages 135-138
ISBN: 978-989-758-501-2
Copyright
c
2022 by SCITEPRESS – Science and Technology Publications, Lda. All rights reser ved
135
4 Ag + O2 + 2 H2S → 2 Ag2S + 2 H2O
High temperature: Ag+(1/2)O2 =>AgO
Low temperature: Sulfide reaction (Ag+(1/2)S2
=>Ag2S)
Discoloration (Yellow->Brown -> Black)
Included in domestic household bathing agent
(containing sulfur such as sodium sulfate and lactate),
onion, gasoline burning (sulfur dioxide gas
generation), shampoo, kitchen detergent (including
surfactant), rubber product (rubber band etc.),
household bleach The silver metal is discolored by
the sulfur component.
At present, such discoloration problem cannot be
solved and organic coating is applied to prevent
contact with gas such as sulfur gas or chlorine gas.
And alloy technology is used by adjusting the
discoloration and strength by alloying the second
element or the third element as shown in the
following table. And silver plating and precious
metals such as palladium and rhodium are
electroplated on the silver surface to prevent
discoloration, but the complete method has not been
found yet.
For this reason, research is needed to prevent
discoloration of silver metal products.
In this study, an experiment to prevent
discoloration of silver products is conducted with an
electrochemical idea.
2 EXPERIMENTAL METHOD
Ag alloy used in this study is to prevent oxidation by
applying NaOH to Ag, Cu, and Nd in a graphite
crucible with a size of 40x 40 x 25mm as shown in
Table 1. It is melted at 1000°C and naturally stirred
for 30 minutes. An alloy was produced by air cooling.
The x-ray diffractometer (XRD, Rigaku Ultima
IV).The structure was observed using a field emission
scanning electron microscope (SEM, Hitachi S 4800),
and the elements were mapped using an energy
dispersive X-ray spectroscope (EDS), and the
corrosion potential and current of each specimen were
measured through a potentiometer (Versastat 4.0).In
order to measure, a coincidence polarization test was
performed. It was measured after grinding the
specimen with #600 SiC Paper before measurement.
The measurement range was from -0.4VSCE to
1.2VSCE, and a three-electrode cell was used. A
saturation sensation electrode (SCE) was used as the
reference electrode and a Pt network was used as the
counter electrode, and the experiment was conducted
using a 3.5 wt.% NaCl electrolyte.
The rate of discoloration between the 1.5V battery
contacted with the silver metal product to form an
electrochemical circuit and the battery not contacted
was measured visually. In addition, the same
experiment was performed for the presence or
absence of contact of the sacrificial aluminum anode.
Table 1: Composition of silver alloy.
92.5 wt % Ag
-75 wt. % Cu
92.5 wt % Ag
-75 wt.% Cu
-0.5 wt. % Nd
Ag (g) 37 37
Cu (g) 3 2.8
Nd (g) 0 0.2
Total (g) 40 40
Figure 2: Schematic diagram of the experiment of ICCP
device.
Fig. 2 shows the schematic diagram of the
I.C.C.P(Impressed Current Cathodic Protection)
experimental apparatus. It is a device that measures
the discoloration of silver metal depending on
whether electrons are supplied from the outside into
the electrolyte, which is a corrosive atmosphere.
3 RESULTS AND DISCUSSION
The structure of the specimen to which 0.5wt% of Nd
was added was observed through SEM, and the
results are shown in Fig. 3. No secondary phase
produced by the addition of Nd was found. In the
sterling silver composition, which is an alloy of Ag
and Cu, copper does not form a secondary phase of
CESIT 2020 - International Conference on Culture Heritage, Education, Sustainable Tourism, and Innovation Technologies
136
the alloy and is known to be dispersed in one size, and
no other secondary phase was found even after the
addition of Nd. According to the previously studied
literature, it was confirmed that other phases do not
exist in the composition used in the present study
through the Ag-Cu-Nd ternary phase diagram.
Figure 3: Microstructure of siver alloy added 0.5wt% Nd.
Figure 4: SEM Image with EDS Mapping of silver alloy
added 0.5 wt. % Nd.
Table 2: Elemets and wt. % of each elements in silver alloy
added 0.5 wt. % Nd.
Element Wt%
Ok 01.90
Cul 06.73
Ndl 00.61
Agl 92.77
EDS analysis was performed to confirm the
addition of Nd. Table 2 shows the quantitative results
of the mapping shape in Figure 4. Mapping of the Nd
element was performed through EDS to confirm the
dispersion of Nd. As a result, Nd was homogeneously
distributed and oxidation occurred at high
temperature during casting, and oxygen was present,
and the same composition as the composition of the
synthesized alloy was detected. Based on this, it was
confirmed that the alloying was properly performed.
Figure 5: Potentiodynamic polarization curve of silver alloy
Ag925 and silver alloy added 0.5 wt% Nd.
Through the electrokinetic polarization
experiment, the corrosion resistance of the specimens
with Nd and without Nd was compared. In the
coincidence polarization test, the corrosion potential
represents the potential at the time when corrosion
occurs, and through this, it can be confirmed that the
corrosion resistance is improved. The results of the
comparison are shown in Fig. 5. It was confirmed that
the corrosion potential value was improved when
0.5% Nd was added compared to the alloy without the
addition of 16mV E(Corr) Nd. Through this, it was
confirmed that when Nd was added, Nd improved the
corrosion resistance under the atmosphere of Cl ion.
Figure 6: XRD peak after potentiodynamic polarization test
of 0.5 wt.% Nd.
Research to Prevent Discoloration of Silver Traditional Handicrafts
137
Table 3: Phase name and formula for after potentiodynamic
polarization test.
Phase name Formula
Neodymium Oxide Nd0
2
Chlorargyrite AgCI
Tolbachite CuCI
2
Neodymium Chloratte Nd(CIO
4
)
3
Corrosion products generated after electrokinetic
polarization were analyzed through XRD, and the
results are shown in Figure 6. The results of the XRD
analysis of the corrosion products of the specimen to
which Nd was added are shown in Table 3. It was
confirmed that AgCl, CuCl, NdO2, and Nd(ClO4)3
were generated after the electrokinetic polarization
experiment.
0 500 1000 1500 2000
0.6
0.8
1.0
1.2
1.4
Potential (V)
Time (sec)
Di water
1 wt. % H2SO4
1 wt.% NaCl
1 wt. % H2SO4 + 1 wt. % NaCl
2 wt. % H2SO4
Figure 7: Open circuit potential.
Figure 7 Represents Open circuit potential of each
electrolyte. Each electrolyte H2SO4, NaCl,
mixture(H2SO4 + NaCl) shows + potentials.
4 CONCLUSIONS
The corrosion resistance and corrosion properties of
the conventional silver alloy and the alloy containing
Nd added to the silver were compared under Cl
atmosphere. To prevent the corrosion of silver, ICCP
was connected to evaluate the anticorrosive ability
according to voltage, and the electrochemical
characteristics according to the electrolyte solution
were analyzed, and the following conclusions were
drawn.
1) It was confirmed that when 0.5wt% Nd was
added, it did not form another secondary phase
by bonding with Ag and Cu.
2) As a result of evaluating the polarization
potential, the corrosion resistance was
improved in the 3.5 wt% NaCl ion atmosphere
as Nd was added.
3) When Nd is added, when corrosion occurs in a Cl
ion atmosphere, NdO2 is formed on the
surface, and it is judged to improve corrosion
resistance by first reacting with Cl.
4) ICCP can prevent corrosion of silver by sulfuric
acid, and NaCl 1 cm2 with 1.5 voltage.
5) To prevent corrosion of silver, it is necessary to
adjust the voltage according to the environment
according to the solution.
6) Corrosion of silver can be prevented with ICCP,
and contact pressure control according to the
environment is required.
REFERENCES
Graedel, T. E. "Corrosion mechanisms for silver exposed to
the atmosphere." Journal of the Electrochemical
Society 139.7 (1992): 1963-1970.
Wiesinger, R. et al. "Influence of relative humidity and
ozone on atmospheric silver corrosion." Corrosion
Science 77 (2013): 69-76.
Lin, Huang, G. S. Frankel, and W. H. Abbott. "Analysis of
Ag corrosion products." Journal of the Electrochemical
Society 160.8 (2013): C345-C355.
Wan, Y., E. N. Macha, and R. G. Kelly. "Modification of
ASTM B117 salt spray corrosion test and its correlation
to field measurements of silver corrosion." Corrosion,
The Journal of Science and Engineering 68.3 (2012):
036001-1.
Bazzi, R., et al. "Optical properties of neodymium oxides at
the nanometer scale." Journal of luminescence 113.1-2
(2005): 161-167.
Kanghou, Zhang, He Chunxiao, and Chen Lili. "500° C
Isothermal section of the Ag Cu Nd (0–34 at.%
neodymium) phase diagram." Journal of alloys and
compounds 189.1 (1992): L31-L33.
Ferro, R., et al. "Phase equilibria in the silver-neodymium
system." Journal of the Less Common Metals 35.1
(1974): 39-44.
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