What is easier to separate, a mixture or a compound? why?

Separating Mixtures

One of the most important things that chemists do is separate mixtures. For example, when I was working in a chemistry lab and I would go out for lunch, it was of vital interest to me that I effectively separate the pickles from the rest of the hamburger, lest I become sick later in the day. Other chemists I know have also found the ability to separate mixtures to be important when eating trail mix or scraping mud from their shoes. Generally, I've found it's easier to separate the components in a heterogeneous mixture (e.g., the pickles from hamburgers) than the components in a homogeneous mixture (e.g., the rum from a Pia Colada) because it's easier to pick things apart when you can see the different components.

Índice Show

Separating Mixtures
Distillation
Chromatography
Comparison chart
Constituents of Compounds and Mixtures
Separating the components
What is easier to separate into elements a compound or a mixture?
Why is a mixture easier to separate?
What is easier to separate a mixture or a compound quizlet?
Can compound be separated easily?

It's good that chemists get so much practice separating mixtures like these in their everyday lives because mixture separation is important for other purposes as well. Let's take a look.

Filtration

One of the simplest methods used to separate mixtures is filtration. If one of the components is a liquid and the other is a solid, filtration is as easy as pouring the whole mixture through filter paper. An everyday example of filtration can be seen in a coffee maker, where the coffee passes through a paper filter but the grounds do not.

Distillation

When one compound is dissolved in another, or when two liquids are mixed together, the most commonly used method to separate them is distillation. In a distillation, the mixture is slowly heated over a Bunsen burner or hotplate. Because the components in a mixture have different boiling points, one of them will boil before the other. The vapor from this compound can be collected from a condenser, enabling it to be isolated in a pure form. A distillation apparatus is shown in the following figure.

Figure 6.3A distillation apparatus (frequently referred to as a "still") uses the different boiling points of the components in a mixture to separate them.

Chromatography

At some time or another, all of us have marked our shirt with a pen. Sometimes we get lucky and the ink doesn't stick well to the fabric—in these cases, we can clean the shirt by putting it in the wash. Sometimes we get very unlucky and the ink sticks to the fabric so well that it's there for good, no matter how many times it's washed with bleach and detergent.

In the same way, chemical substances can frequently be separated from one another based on how well they stick to a solid. The use of this difference in "stickiness" to separate the components of a mixture is referred to as chromatography.

Typically, chromatography is performed by placing a mixture of two or more chemicals into a glass column filled with silica. When an organic solvent such as ethyl acetate or alcohol is poured through the column, one of the components of the mixture will tend to stick to the silica better than the other. As a result, the less sticky one will pass through the column more quickly, while the stickier one will take a little longer.

Extraction

Let's say that you have a compound dissolved in a liquid that you want to remove. For example, you have a small amount of salt dissolved in oil and want to remove it. How would you do this?

Though distillation could do the job, it takes a long time and considerable effort. An alternate way of making this separation is to find a liquid that isn't soluble with the first liquid and that's better at dissolving the salt than the oil is. When the two liquids are mixed and shaken, the salt will tend to move from the oil (where it's not very soluble) into the water (where it is). When this process is complete, it's a simple matter to pour out the water, leaving behind the pure oil.

Excerpted from The Complete Idiot's Guide to Chemistry © 2003 by Ian Guch. All rights reserved including the right of reproduction in whole or in part in any form. Used by arrangement with Alpha Books, a member of Penguin Group (USA) Inc.

To order this book direct from the publisher, visit the Penguin USA website or call 1-800-253-6476. You can also purchase this book at Amazon.com and Barnes & Noble.

Chemistry: Shake It Up: Mixtures

Compounds are pure substances. They are made from the same types of molecules. Each molecule of a compound is made from two or more different kinds of atoms that are chemically bonded. Mixtures are made of two or more substances — elements or compounds — that are mixed physically but not chemically; they do not contain any atomic bonds.

Comparison chart

Compound versus Mixture comparison chart

	Compound	Mixture
Definition	A compound contains atoms of different elements chemically combined together in a fixed ratio.	A mixture is a combination of two or more substances where there is no chemical combination or reaction.
Composition	Compounds contain different elements in a fixed ratio arranged in a defined manner through chemical bonds. They contain only one type of molecule. Elements that compose the compound are chemically combined.	Mixtures contain different elements and compounds but the ratio is not fixed nor are they combined via chemical bonds. The ingredients are physically mixed but chemically separate. Often they are visibly distinct.
Ability to break down	A compound can be separated into simpler substances by chemical methods/reactions.	A mixture can be separated into simpler substances by physical or mechanical methods.
Examples	Water (H2O), Sodium chloride (NaCl), Sodium bicarbonate (NaHCO3) and Hydrochloric acid (HCl) are examples of compounds.	Salt in water; pasta and sauce; sand; pebbles; solutions such as rubbing alcohol, dental amalgam, vapor in air; colloids such as mayonnaise, milk, cheese; coarse suspensions such as mud in water, oil in water.
Representation	A compound is represented using its chemical formula that represents the symbols of its constituent elements and the number of atoms of each element in one molecule of the compound.	Mixtures cannot be represented by chemical formulas.
Chemical and physical properties	Compounds have specific chemical and physical properties that are distinct from their constituent elements because the constituent elements lose their properties when they combine to make the compound.	Mixtures do not have specific, consistent chemical and physical properties of their own. They reflect the properties of their constituent substances, which retain their original properties. e.g. chocolate milk retains properties of chocolate and milk
Types	A huge, virtually limitless, number of chemical compounds can be created. Compounds are classified into molecular compounds, ionic compounds, intermetallic compounds and complexes.	Solids, Liquids and Gases can be combined to create a mixture. Mixtures can be homogeneous or non-homogeneous.
Mass ratio	Compounds have specific mass ratios. e.g. pyrite has 46.6% iron and 53.4% sulphur by mass. This is true of all pyrite no matter the sample size.	Mixtures have a variable mass ratio depending upon what quantities of ingredients have been combined in the mixture.

Constituents of Compounds and Mixtures

Compounds are made up of elements, which are pure substances with only one kind of atoms. Atoms of the elements form bonds to combine and make up a molecule of the compound. The compound contains a uniform distribution of these molecules.

A compound has different physical and chemical characteristics than its component elements. It is not possible to see the elements when you see the compound. e.g. water is made of hydrogen and oxygen but you cannot see either element separately when you look at water. Salt is made of sodium and chloride but the physical and chemical properties of salt are completely different from those of sodium or chloride.

Types of matter: elements, compounds, homogeneous and heterogeneous mixtures.

Both elements and compounds are called pure substances because they contain only one type of molecule. A mixture contains two or more types of pure substances. The molecules of these substances do not form any chemical bonds in a mixture. Components of a mixture retain their chemical independence but physically blend into each other. It is often possible to see these components and differentiate them visually.

Separating the components

The component elements of a compound can only be separated via a chemical reaction that breaks the atomic bonds that bind its molecules.

The ingredients of a mixture may be separated by physical means like sedimentation or decantation.

References

Mixture - Wikipedia
Compounds - Wikipedia
Experiments to see how compounds and mixtures of iron and sulphide behave under various conditions - YouTube
Matter: Mixtures vs Compounds - YouTube

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What is easier to separate into elements a compound or a mixture?

The substances of the mixtures are easy to separate by different physical methods like filtration, chromatography, and evaporation. It is not easy to separate the elements of compounds.

Why is a mixture easier to separate?

The substances in a mixture are separated by the differences in their physical properties, such as their particle size. The more different the properties are, the easier it is to separate the substances. Tea leaves do not dissolve in water, so you can use a strainer to FILTER them.

What is easier to separate a mixture or a compound quizlet?

Properties: Compound has unique physical and chemical properties; Mixture same properties as its components. Separation: Compound not easily separated. They can only be separated by chemical means. Mixture easy to separate through physical process.

Can compound be separated easily?

A compound can be separated into simpler substances by chemical methods/reactions. Elements cannot be broken down into simpler substances by chemical reactions or any physical method.