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Corrosion, atmospheric
and biologic (Barnacles)
Corrosion is
deterioration of useful properties
in a material due to reactions
with its environment. Weakening of
steel due to oxidation of the iron
atoms is a well-known example of
electrochemical corrosion.
This type of damage usually
affects metallic materials, and
typically produces
oxide(s) and/or
salt(s) of the original metal.
Corrosion also includes the
dissolution of
ceramic materials and can
refer to discolouration and
weakening of
polymers by the
sun's
ultraviolet light.
Most structural alloys corrode
merely from exposure to moisture
in the air, but the process can be
strongly affected by exposure to
acids, bases, salts and organic
chemicals. It can be concentrated
locally to form a
pit or crack, or it can extend
across a wide area to produce
general deterioration; efforts to
reduce corrosion sometimes merely
redirect the damage into less
visible, less predictable forms.
Corrosion in nonmetals
Most ceramic materials are
almost entirely immune to
corrosion. The strong ionic and/or
covalent bonds that hold them
together leave very little free
chemical energy in the structure;
they can be thought of as already
corroded. When corrosion does
occur, it is almost always a
simple dissolution of the material
or chemical reaction, rather than
an electrochemical process. A
common example of corrosion
protection in ceramics is the
lime added to soda-lime
glass to reduce its solubility
in water; though it is not nearly
as soluble as pure
sodium silicate, normal glass
does form sub-microscopic flaws
when exposed to moisture. Due to
its
brittleness, such flaws cause
a dramatic reduction in the
strength of a glass object during
its first few hours at room
temperature.
The degradation of polymeric
materials is due to a wide array
of complex and often
poorly-understood physiochemical
processes. These are strikingly
different from the other processes
discussed here, and so the term
"corrosion" is only applied to
them in a loose sense of the word.
Because of their large molecular
weight, very little
entropy can be gained by
mixing a given mass of polymer
with another substance, making
them generally quite difficult to
dissolve. While dissolution is a
problem in some polymer
applications, it is relatively
simple to design against. A more
common and related problem is
swelling, where small
molecules infiltrate the
structure, reducing strength and
stiffness and causing a volume
change. Conversely, many polymers
(notably flexible
vinyl) are intentionally
swelled with
plasticizers, which can be
leached out of the structure,
causing brittleness or other
undesirable changes. The most
common form of degradation,
however, is a decrease in polymer
chain length. Mechanisms which
break polymer chains are familiar
to biologists because of their
effect on
DNA:
ionizing radiation (most
commonly
ultraviolet light),
free radicals, and
oxidizers such as
oxygen,
ozone, and
chlorine.
Additives can slow these
process very effectively, and can
be as simple as a UV-absorbing
pigment (i.e.,
titanium dioxide or
carbon black).
Plastic shopping bags often do
not include these additives so
that they break down more easily
as
litter.
The remainder of this article
is about electrochemical
corrosion.
Electrochemical theory
- Main article:
Electrochemistry
One way to understand the
structure of metals on the basis
of particles is to imagine an
array of positively-charged
ions sitting in a
negatively-charged "gas"
of free
electrons.
Coulombic attraction holds
these oppositely-charged particles
together, but there are other
sorts of negative charge which are
also attracted to the metal ions,
such as the negative ions (anions)
in an
electrolyte. For a given ion
at the surface of a metal, there
is a certain amount of energy to
be gained or lost by dissolving
into the electrolyte or becoming a
part of the metal, which reflects
an atom-scale tug-of-war between
the electron gas and dissolved
anions. The quantity of energy
then strongly depends on a host of
variables, including the types of
ions in a solution and their
concentrations, and the number of
electrons present at the metal's
surface. In turn, corrosion
processes cause electrochemical
changes, meaning that they
strongly affect all of these
variables. The overall interaction
between electrons and ions tends
to produce a state of
local thermodynamic equilibrium
that can often be described using
basic chemistry and a knowledge of
initial conditions.
Galvanic series
- Main article:
Galvanic series
In a given environment (one
standard medium is aerated,
room-temperature
seawater), one metal will be
either more
noble or more active
than the next, based on how
strongly its ions are bound to the
surface. Two metals in electrical
contact share the same electron
gas, so that the tug-of-war at
each surface is translated into a
competition for free electrons
between the two materials. The
noble metal will tend to take
electrons from the active one,
while the electrolyte hosts a flow
of ions in the same direction. The
resulting mass flow or electrical
current can be measured to
establish a hierarchy of materials
in the medium of interest. This
hierarchy is called a
Galvanic series, and can
be a very useful design guideline
when choosing materials.
Resistance to corrosion
Some metals are more
intrinsically resistant to
corrosion than others, either due
to the fundamental nature of the
electrochemical processes involved
or due to the details of how
reaction products form. Otherwise,
many techniques can be used during
an item's manufacture and use to
protect its materials from damage.
Intrinsic chemistry
Gold nuggets do not
corrode, even on a
geological time scale.
The materials most resistant to
corrosion are those for which
corrosion is
thermodynamically unfavorable.
Any corrosion products of
gold or
platinum tend to decompose
spontaneously into pure metal,
which is why these elements can be
found in metallic form on Earth,
and is a large part of their
intrinsic value. More common
"base" metals can only be
protected by more temporary means.
Some metals have naturally slow
reaction
kinetics, even though their
corrosion is thermodynamically
favorable. These include such
metals as
zinc,
magnesium, and
cadmium. While corrosion of
these metals is continuous and
ongoing, it happens at an
acceptably slow rate. An extreme
example is
graphite, which releases large
amounts of energy upon
oxidation, but has such slow
kinetics that it is effectively
immune to electrochemical
corrosion under normal conditions.
Passivation
- Main article:
Passivation
Given the right conditions, a
thin film of corrosion products
can form on a metal's surface
spontaneously, acting as a barrier
to further oxidation. When this
layer stops growing at less than a
micrometre thick under the
conditions that a material will be
used in, the phenomenon is known
as
passivation (rust, for
example, usually grows to be much
thicker, and so is not considered
passivation, and the oxide layer
is not protective anyway). While
this effect is in some sense a
property of the material, it
serves as an indirect kinetic
barrier: the reaction is often
quite rapid unless and until an
impermiable layer forms.
Passivation in air and water at
moderate
pH is seen in such materials
as
aluminium,
stainless steel,
titanium, and
silicon.
These conditions required for
passivation are specific to the
material. The effect of pH is
recorded using
Pourbaix diagrams, but many
other factors are influential.
Some conditions that inhibit
passivation include: high
pH for aluminum, low pH or the
presence of
chloride ions for stainless
steel, high temperature for
titanium (in which case the oxide
dissolves into the metal, rather
than the electrolyte) and
fluoride ions for silicon. On
the other hand, sometimes unusual
conditions can bring on
passivation in materials that are
normally unprotected, as the
alkaline environment of
concrete does for
steel
rebar. Exposure to a liquid
metal such as
mercury or hot
solder can often circumvent
passivation mechanisms.
Surface treatments
Applied coatings
- Main article:
Galvanization
Plating,
painting, and the application
of
enamel are the most common
anti-corrosion treatments. They
work by providing a barrier of
corrosion-resistant material
between the damaging environment
and the (often cheaper, tougher,
and/or easier-to-process)
structural material. Aside from
cosmetic and manufacturing issues,
there are tradeoffs in mechanical
flexibility versus resistance to
abrasion and high temperature.
Platings usually fail only in
small sections, and if the plating
is more noble than the substrate
(i.e.,
chromium on steel), a galvanic
couple will cause any exposed area
to corrode much more rapidly than
an unplated surface would. For
this reason, it is often wise to
plate with a more active metal
such as zinc or cadmium.
Reactive coatings
If the environment is
controlled (especially in
recirculating systems),
corrosion inhibitors can often
be added to it. These form an
electrically insulating and/or
chemically impermeable coating on
exposed metal surfaces, to
suppress electrochemical
reactions. Such methods obviously
make the system less sensitive to
scratches or defects in the
coating, since extra inhibitors
can be made available wherever
metal becomes exposed. Chemicals
that inhibit corrosion include
some of the salts in
hard water (Roman water
systems are famous for their
mineral deposits),
chromates,
phosphates, and a wide range
of specially-designed chemicals
that resemble
surfactants (i.e. long-chain
organic molecules with ionic end
groups).
This figure-8 descender
is annodized with a yellow
finish.
Climbing equipment is
available in a wide range of
colors.
Anodization
- Main article:
Anodising
Aluminium alloys often undergo
a surface treatment known as
anodization in a chemical bath
near the end of their manufacture.
Electrochemical conditions in the
bath are carefully adjusted so
that uniform pores several
nanometers wide appear in the
metal's oxide film. These pores
allow the oxide to grow much
thicker than passivating
conditions would allow. At the end
of the treatment, the pores are
allowed to close, forming a
harder-than-usual (and therefore
more protective) surface layer. If
this coating is scratched, normal
passivation processes take over to
protect the damaged area.
Cathodic protection
- Main article:
Cathodic protection
Cathodic protection (CP) is a
technique to control the
corrosion of a metal
surface by making that surface the
cathode of an
electrochemical cell.
It is a method used to protect
metal structures from corrosion.
Cathodic protection systems are
most commonly used to protect
steel, water, and fuel
pipelines and tanks; steel
pier
piles, ships, and
offshore
oil platforms.
For effective CP, the potential
of the steel surface is polarized
(pushed) more negative until the
metal surface has a uniform
potential. With a uniform
potential, the driving force for
the corrosion reaction is halted.
For galvanic CP systems, the anode
material corrodes under the
influence of the steel, and
eventually it must be replaced.
The polarization is caused by the
current flow from the anode to the
cathode, driven by the difference
in electrochemical potential
between the anode and the cathode.
For larger structures, galvanic
anodes cannot economically deliver
enough current to provide complete
protection.
Impressed Current Cathodic
Protection (ICCP) systems use
anodes connected to a
DC power source (a
cathodic protection rectifier).
Anodes for ICCP systems are
tubular and solid rod shapes of
various specialized materials.
These include high
silicon
cast iron,
graphite, mixed
metal
oxide,
platinum and
niobium coated wire and
others.
Corrosion in passivated
materials
Passivation is extremely
useful in alleviating corrosion
damage, but care must be taken not
to trust it too thoroughly. Even a
high-quality alloy will corrode if
its ability to form a passivating
film is compromised. Because the
resulting modes of corrosion are
more exotic and their immediate
results are less visible than
rust and other bulk corrosion,
they often escape notice and cause
problems among those who are not
familiar with them.
Pitting corrosion
- Main article:
Pitting corrosion
Certain conditions, such as low
availability of oxygen or high
concentrations of species such as
chloride which compete as
anions, can interfere with a
given alloy's ability to re-form a
passivating film. In the worst
case, almost all of the surface
will remain protected, but tiny
local fluctuations will degrade
the oxide film in a few critical
points. Corrosion at these points
will be greatly amplified, and can
cause corrosion pits of
several types, depending upon
conditions. While the corrosion
pits only
nucleate under fairly extreme
circumstances, they can continue
to grow even when conditions
return to normal, since the
interior of a pit is naturally
deprived of oxygen. In extreme
cases, the sharp tips of extremely
long and narrow pits can cause
stress concentration to the
point that otherwise tough alloys
can shatter, or a thin film
pierced by an invisibly small hole
can hide a thumb sized pit from
view. These problems are
especially dangerous because they
are difficult to detect before a
part or structure
fails. Pitting remains among
the most common and damaging forms
of corrosion in passivated alloys,
but it can be prevented by control
of the alloy's environment, which
often includes ensuring that the
material is exposed to oxygen
uniformly (i.e., eliminating
crevices).
Fretting
Many useful passivating oxides
are also effective abrasives,
particularly
TiO2 and
Al2O3.
Fretting corrosion occurs
when particles of corrosion
product continuously abrade away
the passivating film as two metal
surfaces are rubbed together.
While this process does often
damage the
frets of musical instruments,
they were named separately.
Weld decay and knifeline
attack
Stainless steel can pose
special corrosion challenges,
since its passivating behavior
relies on the presence of a minor
alloying component (Chromium,
typically only 18%). Due to the
elevated temperatures of
welding or during improper
heat treatment, chromium
carbides can form in the
grain boundaries of stainless
alloys. This chemical reaction
robs the material of chromium in
the zone near the grain boundary,
making those areas much less
resistant to corrosion. This
creates a
galvanic couple with the
well-protected alloy nearby, which
leads to weld decay
(corrosion of the grain boundaries
near
welds) in highly corrosive
environments. Special alloys,
either with low carbon content or
with added carbon "getters"
such as
titanium and
niobium (in types 321 and 347,
respectively), can prevent this
effect, but the latter require
special heat treatment after
welding to prevent the similar
phenomenon of knifeline attack.
As its name applies, this is
limited to a small zone, often
only a few micrometres across,
which causes it to proceed more
rapidly. This zone is very near
the weld, making it even less
noticeable1.
Economic impact
The US
Federal Highway Administration
released a study, entitled
Corrosion Costs and Preventive
Strategies in the United States,
in 2002 on the direct costs
associated with metallic corrosion
in nearly every U.S. industry
sector. The study showed that for
1998 the total annual
estimated direct cost of corrosion
in the U.S. was approximately $276
billion (approximately 3.1% of the
US
gross domestic product). FHWA
Report Number:FHWA-RD-01-156. The
NACE International
website has a
summary slideshow of the
report findings. Jones1
writes that electrochemical
corrosion causes between $8
billion and $128 billion in
economic damage per year in the
United States alone, degrading
structures, machines, and
containers.
References
