Soap – Characteristics And Uses

Soaps are excellent cleansing agents and have good biodegradability. A serious drawback which reduces their general use, is the tendency for the carboxylate ion to react with Ca+ and Mg+ ions in hard water. The result is a water insoluble salt which can be deposited on clothes and other surfaces. These hard water plaques whiten fabric colors and also create rings found in sinks and bath tubs. Another problem with using soaps is their ineffectiveness under acidic conditions. In these cases, soap salts do not dissociate into their component ions, and this renders them ineffective as cleansing agents.

Although primarily used for their cleansing ability, soaps are also effective as mild antiseptics and ingestible antidotes for mineral acid or heavy Metal poisoning. Special metallic soaps, made from soap and heavier metals, are used as additives in polishes, inks, paints, and lubricating oils.

Detergent Physical Characteristics

The concentration at which micelles begin to form is the critical micelle concentration (CMC). The CMC is the maximum monomer concentration and constitutes a measure of the free energy of micelle formation. The lower the CMC, the more stable the micelle and the more slowly Molecules are incorporated into or removed from the micelle. The structure of the hydrophobic region of the detergent can affect the micelle structure. An increase in the length of the hydrophobic hydrocarbon chain of ionic detergents results in an increased micelle size and a lower CMC, as fewer molecules are needed to construct a micelle.

The Average number of monomers in a micelle is the aggregation number. The CMC and aggregation number values are highly dependent on factors such as temperature, pH, ionic strength, and detergent homogeneity and purity. Slight discrepancies in reported values for CMC and aggregation number may be the result of variations in the analytical methods used to determine the values. Aggregation number values are also shifted by concentration, since the number of detergent molecules per micelle may increase if the concentration is above the CMC.

Ease of removal or exchange is an important factor in the selection of a detergent. Some of the more common detergent removal methods include:

• Dialysis
• Gel filtration chromatography
• Hydrophobic adsorption chromatography
• Protein Precipitation

The CMC value associated with the detergent is a useful guide to hydrophobic binding strength. Detergents with higher CMC values have weaker binding and are subsequently easier to remove by dialysis or displacement methods. Detergents with low CMC values require less detergent in order to form micelles and solubilize proteins or lipids.

Another useful parameter when evaluating detergents for downstream removal is the micelle molecular weight, which indicates relative micelle size. Smaller micelles are more easily removed and are usually desirable when protein-detergent complexes are to be separated based on the molecular size of the protein. The micelle molecular weight may be calculated by multiplying the aggregation number by the monomer molecular weight.

The cloud point is the temperature at which the detergent solution near or above its CMC separates into two phases. The micelles aggregate, typically forming a cloudy phase with high detergent concentration, while the balance of the solution becomes detergent-depleted. The resulting two-phase solution can be separated, with the extracted protein being located in the detergent-rich phase. Detergents with low cloud point temperatures, such as TRITON^® X-114 (cloud point ~23 °C) are recommended for use with proteins since high cloud point temperatures may denature solubilized proteins. The cloud point can be affected by changes in detergent concentration, temperature, and the addition of salt or polymers such as dextran and polyethylene glycol. Note that the detergent-rich phase is also contingent on the specific detergent(s) and salt concentration; under some conditions the phase may be clear rather than cloudy and be located as either the upper or lower phase of the solution. In non-ionic detergents, this behavior has been applied in the phase separation and purification of membrane proteins.²

Detergent Types and Selection

When selecting a detergent, the first consideration is usually the form of the hydrophilic group:

• Anionic
• Cationic
• Non-ionic
• Zwitterionic (ampholytic)

Anionic and cationic detergents are considered biologically “harsh” detergents because they typically modify protein structure to a greater extent than neutrally charged detergents. The degree of denaturation varies with the individual protein and the particular detergent and concentration. Ionic detergents are more sensitive to pH, ionic strength, and the nature of the counter ion, and can interfere with downstream charge-based analytical methods.

Non-ionic detergents are considered to be “mild” detergents because they are less likely than ionic detergents to denature proteins. By not separating protein-protein Bonds, non-ionic detergents allow the protein to retain its native structure and functionality, although detergents with shorter hydrophobic chain lengths are more likely to cause protein deactivation. Many nonionic detergents can be classified into three structure types:

• Poly(oxyethylene) ethers and related polymers
• Bile salts
• Glycosidic detergents

Poly(oxyethylene) ethers and related detergents have a neutral, polar head and hydrophobic tails that are oxyethylene polymers (e.g. Brij^® and TWEEN^®) or ethyleneglycoether polymers (e.g. TRITON^®). The tert-octylphenol poly(ethyleneglycoether) series of detergents, which includes TRITON X-100 and IGEPAL^® CA-630, have an aromatic head that interferes with downstream UV analysis techniques.

Bile salts have a steroid core structure with a polar and apolar orientation, rather than the more obvious nonpolar tail structure of other detergents. Bile salts may be less denaturing than linear chain detergents with the same polar head group.

Glycosidic detergents have a carbohydrate, typically glucose or maltose, as the polar head and an alkyl chain length of 7-14 carbons as the polar tail.

Zwitterionic detergents have characteristics of both ionic and non-ionic detergent types. Zwitterionic detergents are less denaturing than ionic detergents and have a net neutral charge, similar to non-ionic detergents. They are more efficient than non-ionic detergents at disrupting protein-protein bonds and reducing aggregation. These properties have been used for chromatography, mass spectrometry, and electrophoresis methods, and solubilization of organelles and inclusion bodies.

Non-detergent sulfobetaines (NDSB), although not detergents, possess hydrophilic groups similar to those of zwitterionic detergents but with shorter hydrophobic chains. Sulfobetaines do not form micelles. They have been reported to improve the yield of membrane proteins when used with detergents and prevent aggregation of denatured proteins.

Uses for Detergent

Powder and liquid detergent can be used for other purposes besides cleaning clothes or dishes. This can save you Money from having to buy multiple cleaning products.

All-Purpose Cleaner

Either form of detergent can be used to clean tiles, floors, counters, tubs and toilets. Mix 3/4 of a cup of bleach, 1 cup of detergent and 1 gallon of hot water together and pour it into spray bottles for a supply of all-purpose cleaner.

Moss Killer

Sprinkle powdered detergent on moss that is growing in the cracks of your steps, sidewalk or driveway. Give it a few days to turn brown, then brush it from the cracks with a broom.

Oil Spills

Powdered detergent can absorb oil that’s spilled on a garage floor or on the street.

Carpet Cleaning

Both types of cleaner can be added to carpet steam cleaners to make the carpet smell fresher and boost the appliance’s cleaning power.

Drains

Instead of buying Drano to clean out a drain, put 1/4 cup of liquid detergent into the drain, then pour in a boiling pot of water after a minute to flush out to blockage.

Bubbles

If kids like to make bubbles with wants or play with bubble-making guns, one can make the bubble solution oneself by mixing liquid detergent with water.

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Soap and detergents are essential for cleaning. They are effective at removing dirt and other substances from the skin and other surfaces. Soap and detergents are made from natural or synthetic ingredients. They are used for a variety of purposes, including cleaning the skin, clothes, dishes, and other surfaces. Soap and detergents can have a negative impact on the Environment, but this can be reduced by using them sparingly and disposing of them properly.

Structure of soap

Soap is made up of molecules that have two very different ends. One end of the molecule is attracted to water, while the other end is attracted to oil and grease. This is why soap is able to clean: the water-loving ends of the soap molecules attach to the water, while the oil-loving ends of the soap molecules attach to the dirt and oil. This helps to loosen the dirt and oil from the surface being cleaned, so that it can be rinsed away with water.

Cleansing action of soap

The cleansing action of soap is due to its ability to form micelles. Micelles are tiny, spherical structures that are made up of soap molecules. The water-loving ends of the soap molecules are on the outside of the micelle, while the oil-loving ends of the soap molecules are on the inside of the micelle. This allows the micelles to surround and trap dirt and oil, so that they can be rinsed away with water.

Types of soap

There are many different types of soap, each with its own unique properties. Some common types of soap include bar soap, liquid soap, and hand soap. Bar soap is the most common type of soap. It is made from a mixture of fats or oils and an alkali, such as sodium hydroxide or potassium hydroxide. Bar soap is typically solid and is used by rubbing it on the skin and then rinsing it off with water. Liquid soap is a type of soap that is made from a mixture of fats or oils, an alkali, and water. Liquid soap is typically clear or white and is dispensed from a pump or bottle. Hand soap is a type of soap that is designed to be used on the hands. It is typically clear or white and is dispensed from a pump or bottle.

Detergents

Detergents are similar to soap in that they are made up of molecules that have both water-loving and oil-loving ends. However, detergents are not made from fats or oils. Instead, they are made from synthetic chemicals. Detergents are often used in laundry detergents, dishwashing detergents, and other cleaning products.

Comparison of soap and detergents

Soap and detergents are both effective at cleaning. However, there are some key differences between the two. Soap is made from natural ingredients, while detergents are made from synthetic chemicals. Soap is also more biodegradable than detergents. This means that soap is less likely to harm the environment.

Applications of soap and detergents

Soap and detergents are used for a variety of purposes. They are used to clean the skin, clothes, dishes, and other surfaces. Soap and detergents are also used in industrial applications, such as in the manufacture of paper and textiles.

Environmental impact of soap and detergents

Soap and detergents can have a negative impact on the environment. When soap and detergents are washed down the drain, they can pollute waterways. Soap and detergents can also harm aquatic life. To reduce the environmental impact of soap and detergents, it is important to use them sparingly and to dispose of them properly.

Conclusion

Soap and detergents are essential for cleaning. They are effective at removing dirt and other substances from the skin and other surfaces. Soap and detergents are made from natural or synthetic ingredients. They are used for a variety of purposes, including cleaning the skin, clothes, dishes, and other surfaces. Soap and detergents can have a negative impact on the environment, but this can be reduced by using them sparingly and disposing of them properly.

What is soap?

Soap is a chemical compound made from fats or oils and an alkali. It is used to clean by reducing the Surface Tension of water, which allows it to more easily wet and penetrate dirt and grime. Soap also helps to suspend dirt and oil in water so that it can be rinsed away.

What are detergents?

Detergents are similar to soap, but they are made from synthetic chemicals instead of fats or oils. Detergents are often more effective than soap at cleaning in hard water, which contains Minerals that can interfere with the cleaning action of soap.

How do soap and detergents work?

Soap and detergents work by reducing the surface tension of water. This allows water to more easily wet and penetrate dirt and grime. Soap and detergents also help to suspend dirt and oil in water so that it can be rinsed away.

What are the benefits of using soap and detergents?

Soap and detergents are effective at cleaning dirt, oil, and other contaminants from surfaces. They are also relatively inexpensive and easy to use.

What are the risks of using soap and detergents?

Soap and detergents can be irritating to the skin, especially if they are used in high concentrations. They can also be harmful to the environment if they are not disposed of properly.

How can I use soap and detergents safely?

To use soap and detergents safely, follow these tips:

• Use only the amount of soap or detergent that is necessary to clean the surface.
• Rinse soap and detergent off of surfaces thoroughly.
• Do not use soap or detergent on surfaces that are sensitive to chemicals, such as wood or marble.
• Dispose of soap and detergent properly, according to the product label.

What are some alternatives to soap and detergents?

Some alternatives to soap and detergents include:

• Natural soaps made from plant-based oils
• Detergents made from plant-based ingredients
• Borax
• Vinegar
• Baking soda

What are the benefits of using alternatives to soap and detergents?

Alternatives to soap and detergents can be less irritating to the skin and the environment. They can also be less expensive.

What are the risks of using alternatives to soap and detergents?

Alternatives to soap and detergents may not be as effective at cleaning dirt, oil, and other contaminants from surfaces. They may also be more difficult to use.

How can I use alternatives to soap and detergents safely?

To use alternatives to soap and detergents safely, follow these tips:

• test the alternative on a small area of the surface to make sure it does not damage the surface.
• Use the alternative according to the product label.
• Rinse the alternative off of surfaces thoroughly.
• Do not use the alternative on surfaces that are sensitive to chemicals, such as wood or marble.

1. Soap is made from:
   (a) Fats and oils
   (b) Sodium hydroxide
   (c) Both (a) and (b)

2. Detergents are made from:
   (a) Surfactants
   (b) Phosphates
   (c) Both (a) and (b)

3. The cleansing action of soap and detergents is due to:
   (a) Their ability to form micelles
   (b) Their ability to lower the surface tension of water
   (c) Both (a) and (b)

4. Micelles are:
   (a) Small, spherical aggregates of soap or detergent molecules
   (b) Surrounded by water molecules on the outside and hydrophobic tails on the inside
   (c) Both (a) and (b)

5. The hydrophobic tails of micelles are attracted to:
   (a) Water
   (b) Oil and grease
   (c) Both (a) and (b)

6. When soap or detergent is added to water, it:
   (a) Lowers the surface tension of water
   (b) Makes water more wetting
   (c) Both (a) and (b)

7. Lowered surface tension allows water to:
   (a) Wet surfaces more easily
   (b) Penetrate surfaces more easily
   (c) Both (a) and (b)

8. When soap or detergent is added to water, it also:
   (a) Surrounds oil and grease molecules
   (b) Forms micelles with the oil and grease molecules
   (c) Both (a) and (b)

9. The micelles with the oil and grease molecules are then:
   (a) Washed away with water
   (b) Carried away by the water flow
   (c) Both (a) and (b)

10. Soap and detergents are effective in removing dirt and oil because:
    (a) They lower the surface tension of water
    (b) They surround oil and grease molecules
    (c) They both lower the surface tension of water and surround oil and grease molecules