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Daily Maverick
18-05-2025
- Science
- Daily Maverick
The science of soap — a chemist explains how it works to keep you clean and smelling fresh
There's a science behind soap that ensures you can get rid of all types of dirt when you wash up, regardless of whether it's muddy or oily. How does soap clean our bodies? – Charlie H (8), Stamford, Connecticut Thousands of years ago, our ancestors discovered something that would clean their bodies and clothes. As the story goes, fat from someone's meal fell into the leftover ashes of a fire. They were astonished to discover that the blending of fat and ashes formed a material that cleaned things. At the time, it must have seemed like magic. That's the legend, anyway. However it happened, the discovery of soap dates back about 5,000 years to the ancient city of Babylon in what was southern Mesopotamia – today, the country of Iraq. As the centuries passed, people around the world began to use soap to clean the things that got dirty. During the 1600s, soap was a common item in the American colonies, often made at home. In 1791, Nicholas Leblanc, a French chemist, patented the first soapmaking process. Today, the world spends about $50-billion every year on bath, kitchen and laundry soap. But although billions of people use soap every day, most of us don't know how it works. As a professor of chemistry, I can explain the science of soap – and why you should listen to your mom when she tells you to wash up. The chemistry of clean Water (scientific name: dihydrogen monoxide) is composed of two hydrogen atoms and one oxygen atom. This molecule is required for all life on our planet. Chemists categorise other molecules that are attracted to water as hydrophilic, which means water-loving. Hydrophilic molecules can dissolve in water, so if you wash your hands under a running tap without using soap, you'd probably get rid of lots of whatever hydrophilic bits are stuck to your skin. But there is another category of molecules that chemists call hydrophobic, which means water-fearing. Hydrophobic molecules do not dissolve in water. Oil is an example of something that's hydrophobic. You probably know from experience that oil and water just don't mix. Picture shaking a jar of vinaigrette salad dressing – the oil and the other watery ingredients never stay mixed. So just swishing your hands through water isn't going to get rid of water-fearing molecules such as oil or grease. Here's where soap comes in to save the day. Soap, a complex molecule, is both water-loving and water-fearing. Shaped like a tadpole, the soap molecule has a round head and long tail; the head is hydrophilic and the tail is hydrophobic. This quality is one of the reasons soap is slippery. It's also what gives soap its cleaning superpower. A microscopic view To see what happens when you wash your hands with soap and water, let's zoom all the gunk you touch during the day that builds up on your skin to make your hands dirty. Maybe there are smears of food, mud from outside, or even sweat and oils from your own skin. All that material is either water-loving or water-fearing on the molecular level. Dirt is a jumbled mess of both. Dust and dead skin cells are hydrophilic, naturally occurring oils are hydrophobic, and environmental debris can be either. If you use only water to clean your hands, plenty will be left behind because you'd only remove the water-loving bits that dissolve in water. But when you add a bit of soap, it's a different story, thanks to its simultaneously water-loving and water-fearing properties. Soap molecules come together and surround the grime on your hands, forming what's known as a micelle structure. On a molecular level, it looks almost like a bubble encasing the hydrophobic bit of debris. The water-loving heads of the soap molecules are on the surface, with the water-fearing tails inside the micelle. This structure traps the dirt, and running water washes it all away. To get the full effect, wash your hands at the sink for at least 20 seconds. Rubbing your hands together helps force the soap molecules into whatever dirt there is to break it up and envelope it. It's not just dirt Along with dirt, your body is covered by micro-organisms – bacteria, viruses and fungi. Most are harmless and some even protect you from getting sick. But some micro-organisms, known as pathogens, can cause illness and disease. They can also cause you to smell if you haven't taken a bath in a while. These bacteria break down organic molecules and release stinky fumes. Although micro-organisms are protected by a barrier – it's called a membrane – soap and water can disrupt the membrane, causing the microorganism to burst open. The water then washes the remains of the micro-organism away, along with the stink. To say that soap changed the course of civilisation is an understatement. For thousands of years it's helped to keep billions of people healthy. Think of that the next time mom or dad asks you to wash up – which is likely to be sometime soon. DM First published by The Conversation. Paul E Richardson is a professor of biochemistry at Coastal Carolina University in South Carolina. This story first appeared in our weekly Daily Maverick 168 newspaper, which is available countrywide for R35.
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First Post
04-05-2025
- Science
- First Post
Soap's secret superpower: How did this ancient discovery revolutionise cleanliness?
From ancient Babylon to modern bathrooms, soap has shaped human hygiene for over 5,000 years. But how does it really work? Chemistry reveals that soap's unique molecular structure allows it to break down both water-loving and water-fearing grime. More than just cleaning dirt, it also disrupts harmful microbes — explaining why your mom was right all along read more The discovery of soap dates back approximately 5,000 years, to the ancient city of Babylon in what was southern Mesopotamia – today, the country of Iraq. Representational Image/AI-generated by Firstpost Thousands of years ago, our ancestors discovered something that would clean their bodies and clothes. As the story goes, fat from someone's meal fell into the leftover ashes of a fire. They were astonished to discover that the blending of fat and ashes formed a material that cleaned things. At the time, it must have seemed like magic. That's the legend, anyway. However it happened, the discovery of soap dates back approximately 5,000 years, to the ancient city of Babylon in what was southern Mesopotamia – today, the country of Iraq. STORY CONTINUES BELOW THIS AD As the centuries passed, people around the world began to use soap to clean the things that got dirty. During the 1600s, soap was a common item in the American colonies, often made at home. In 1791, Nicholas Leblanc, a French chemist, patented the first soapmaking process. Today, the world spends about US$50 billion every year on bath, kitchen and laundry soap. But although billions of people use soap every day, most of us don't know how it works. As a professor of chemistry, I can explain the science of soap – and why you should listen to your mom when she tells you to wash up. The chemistry of clean Water – scientific name: dihydrogen monoxide – is composed of two hydrogen atoms and one oxygen atom. That molecule is required for all life on our planet. Chemists categorise other molecules that are attracted to water as hydrophilic, which means water-loving. Hydrophilic molecules can dissolve in water. So if you were to wash your hands under a running faucet without using soap, you'd probably get rid of lots of whatever hydrophilic bits are stuck to your skin. But there is another category of molecules that chemists call hydrophobic, which means water-fearing. Hydrophobic molecules do not dissolve in water. Oil is an example of something that's hydrophobic. You probably know from experience that oil and water just don't mix. Picture shaking up a jar of vinaigrette salad dressing – the oil and the other watery ingredients never stay mixed. STORY CONTINUES BELOW THIS AD So just swishing your hands through water isn't going to get rid of water-fearing molecules such as oil or grease. Here's where soap comes in to save the day. Soap, a complex molecule, is both water-loving and water-fearing. Shaped like a tadpole, the soap molecule has a round head and long tail; the head is hydrophilic, and the tail is hydrophobic. This quality is one of the reasons soap is slippery. It's also what gives soap its cleaning superpower. A microscopic view To see what happens when you wash your hands with soap and water, let's zoom in. Picture all the gunk that you touch during the day and that builds up on your skin to make your hands dirty. Maybe there are smears of food, mud from outside, or even sweat and oils from your own skin. All of that material is either water-loving or water-fearing on the molecular level. Dirt is a jumbled mess of both. Dust and dead skin cells are hydrophilic; naturally occurring oils are hydrophobic; and environmental debris can be either. If you use only water to clean your hands, plenty will be left behind because you'd only remove the water-loving bits that dissolve in water. STORY CONTINUES BELOW THIS AD But when you add a bit of soap, it's a different story, thanks to its simultaneously water-loving and water-fearing properties. Soap molecules come together and surround the grime on your hands, forming what's known as a micelle structure. On a molecular level, it looks almost like a bubble encasing the hydrophobic bit of debris. The water-loving heads of the soap molecules are on the surface, with the water-fearing tails inside the micelle. This structure traps the dirt, and running water washes it all away. To get the full effect, wash your hands at the sink for at least 20 seconds. Rubbing your hands together helps force the soap molecules into whatever dirt is there to break it up and envelope it. It's not just dirt Along with dirt, your body is covered by microorganisms – bacteria, viruses and fungi. Most are harmless and some even protect you from getting sick. But some microorganisms, known as pathogens, can cause illness and disease. They can also cause you to smell if you haven't taken a bath in a while. These bacteria break down organic molecules and release stinky fumes. Although microorganisms are protected by a barrier – it's called a membrane – soap and water can disrupt the membrane, causing the microorganism to burst open. The water then washes the remains of the microorganism away, along with the stink. STORY CONTINUES BELOW THIS AD To say that soap changed the course of civilisation is an understatement. For thousands of years, it's helped keep billions of people healthy. Think of that the next time Mom or Dad asks you to wash up – which will likely be sometime soon. Paul E. Richardson, Professor of Biochemistry, Coastal Carolina University This article is republished from The Conversation under a Creative Commons license. Read the original article here.
