- 1.Soap & Detergent ChemistryTo understand what is needed to
achieve effective cleaning, it is helpful to have a basic knowledge
of soap and detergent chemistry.As you know water comprises
approximately 95-99% of cleaning and sanitizing solutions.Water
functions to: carry the detergent or the sanitizer to the surface
carry soils or contamination from the surface. Water has a property
called surface tension. In the body of the water, each molecule is
surrounded and attracted by other water molecules. However, at the
surface, those molecules are surrounded by other water molecules
only on the water side. A tension is created as the water molecules
at the surface are pulled into the body of the water. This tension
causes water to bead up on surfaces, which slows wetting of the
surface and inhibits the cleaning process. Molecules inside a water
drop are attracted in all directions. Drops on the surface are
attracted to the sides and inwards. After raining you can see
surface tension a drop of water onto a branch. The drop will hold
its shape and will not spread. 10
2. In the cleaning process, surface tension must be reduced so
water can spread and wet surfaces. Chemicals that are able to do
this effectively are called surface active agents, or surfactants.
They are said to make water "wetter."Consider a liquid droplet at
rest on a flat, solid surface. The angle formed by the solid
surface and the tangent line to the upper surface at the end point
is called the contact angle(). The contact angle is a result of the
interface/surface tensions (surface free energies) between liquid
and solid surrounded by vapor.Measurement of the contact angle of a
water droplet is a quick and simple way to evaluate cleanliness of
a solid surface as below: From the contact angle, physical
properties of interaction between solid and liquid like
wettability, affinity, adhesiveness and repellency can be studied.
Typical evaluations are as shown below: Different wetting states of
a droplet 11 3. SOAPSSoaps are produced during the chemical
reaction known as saponification which is the reaction between a
fat or oil and a base (strong alkali), producing glycerol and a
salt (soap)fat or oil + base -----> glycerol + salt (soap)Soaps
are usually sodium or potassium salts of long-chain fatty
acids.Soaps are detergents in the sense that they help clean oily
and greasy dirt from fabrics, metals, our skin and hair. We
restrict the term soap to the sodium salts of long-chain carboxylic
acids. A carboxylic acid is marked by the presence of a carboxyl
group, -CO2H. With the anion of the carboxyl group balanced by a
sodium cation and tied by a covalent bond to a long chain of -CH2-
groups that terminate in a CH3- group, we have a soap molecule. We
can generalize the molecular structure of a soap molecule asCH3 -
(CH2)n - CO2 - Na+CH3 - (CH2)n - resembles quite closely the long
chains of the hydrocarbon molecules. Like the molecules of gasoline
and mineral oil, this part of the soap molecule tends to dissolve
readily in materials that are or that resemble hydrocarbons, but
not in water. All these long chains of -CH2- groups of soaps and of
hydrocarbons and hydrocarbon-like materials intermingle easily, but
they don't mix readily with the H2O molecules of water. The other
end of the molecule, though is ionic: O|| -C - O - Na+Like sodium
chloride and other ionic compounds, that ionic end tends to
dissolve in water, but not in hydrocarbon solvents. As a result,
one molecule has two opposite and contradictory tendencies. A
hydrophilic structure is attracted towards water molecules but shun
hydrocarbons and other oily and greasy substances. A hydrophobic
structure shuns water but mixes easily with those very oily, greasy
substances that repel the hydrophilic, or charged, part.Fats and
Oils The fats and oils used in soapmaking come from animal or
plantsources. Each fat or oil is made up of a distinctive mixture
of severaldifferent triglycerides. 12 4. In a triglyceride
molecule, three fatty acid molecules are attached to one molecule
of glycerine. There are many types of triglycerides; each type
consists of its own particular combination of fatty acids.Fatty
acids are the components of fats and oils that are used in making
soap. They are weak acids composed of two parts:A carboxylic acid
group consisting of one hydrogen (H) atom, two oxygen (O) atoms,
and one carbon (C) atom, plus a hydrocarbon chain attached to the
carboxylic acid group. Generally, it is made up of a long straight
chain of carbon (C) atoms each carrying two hydrogen (H) atoms.
Alkali (Base)An alkali is a soluble salt of an alkali metal like
sodium or potassium. Originally, the alkalis used in soapmaking
were obtained from the ashes of plants, but they are now made
commercially The common alkalis used in soapmaking are sodium
hydroxide (NaOH), also called caustic soda; and potassium hydroxide
(KOH), also called caustic potash.How Soaps are MadeSaponification
of fats and oils is the most widely used soapmaking process. This
method involves heating fats and oils and reacting them with a
liquid alkali to produce soap and water (neat soap) plus glycerine.
13 5. When the alkali is sodium hydroxide, a sodium soap is formed.
Sodium soaps are "hard" soaps. When the alkali is potassium
hydroxide, a potassium soap is formed. Potassium soaps are softer
and are found in some liquid hand soaps and shaving creams.The
carboxylate end of the soap molecule is attracted to water. It is
called the hydrophilic (water-loving) end. The hydrocarbon chain is
attracted to oil and grease and repelled by water. It is known as
the hydrophobic (water-hating) end. Cleaning Action of SoapsStep 1
Decreases the water's surface tension, making it a better wetting
agent.Soap first lowers suface tension so that the water carrying
the micelles, clusters of soap molecules in which the hydrocarbon
chains are attracted to each other by Van der Waals forces
(dispersion forces, London forces, weak intermolecular forces), can
get to the dirt. When the soap micelles reach the embedded dirt,
the soap molecules that form these micelles once again find
themselves at a surface. Step 2 Converts greasy and oily dirt into
micelles that become dispersed in the soapy waterNow, as the
hydrophilic heads of the soap molecules remain surrounded by water
molecules, the soap micelles break up and the hydrophobic
hydrocarbon tails, which had remained in the interior of the
spherical micelles, become embedded in the grease. With this greasy
dirt providing as compatible a chemical environment for the
hydrophobic tails as the water provides for the hydrophilic heads,
the tails are just as much at home in the grease as the heads are
in the water.14 6. Step 3 Keeps the grease micelles in suspension,
thereby preventing them from coalescing back to large globules of
grease that could be redeposited on a clean surface.Agitation now
breaks the grease into micelles whose surfaces are covered by the
negatively charged carboxylate groups, the hydrophilic -CO2- groups
of the embedded soap molecules. The grease droplets repel each
other and remain suspended in the wash water instead of coalescing
and redepositing on the material being cleaned. In the end, the
suspended droplets go down the drain with the wash water. (While
all this is going on the sodium ions move about freely and
independently in the wash water.) As a cleaning agent, soap suffers
from two main drawbacks:1. It does not function well in acidic
solutions because of the formation of insoluble fattyacid.
CH3(CH2)16COO-Na+(aq)+HCl(aq) CH3(CH2)16COOH(s)+Na+(aq)+Cl-(aq)2.
It forms insoluble precipitates with Ca2+and Mg2+ ions present in
hard water, forming ascum . 2CH3(CH2)16COO-Na+(aq)+Ca2+(aq)
[CH3(CH2)16COO-]2Ca2+(s)+2Na+(aq)Additives such as sodium carbonate
and phosphates can help offset these effects.How Water Hardness
Affects Cleaning ActionAlthough soap is a good cleaning agent, its
effectiveness is reduced when used in hard water. Hardness in water
is caused by the presence of mineral salts - mostly those of
calcium (Ca) and magnesium (Mg), but sometimes also iron (Fe) and
manganese (Mn). The mineral salts 15 7. react with soap to form an
insoluble precipitate known as soap film or scum.Soap film does not
rinse away easily. It tends to remain behind and produces visible
deposits on clothing and makes fabrics feel stiff. It also attaches
to the insides of bathtubs, sinks and washing machines.Some soap is
used up by reacting with hard water minerals to form the film. This
reduces the amount of soap available for cleaning. Even when
clothes are washed in soft water, some hardness minerals are
introduced by the soil on clothes. Soap molecules are not very
versatile and cannot be adapted to today's variety of fibers,
washingtemperatures and water conditions.Synthetic detergents are
increasingly being used instead of soaps because they do not suffer
from these disadvantages to the same extent.16
