The main methods for separating inhomogeneous and homogeneous mixtures. Chemical and physical methods of separation of mixtures. Tasks are more difficult

home » Middle Ages The main methods for separating inhomogeneous and homogeneous mixtures. Chemical and physical methods of separation of mixtures. Tasks are more difficult

Do you know what methods exist for separating mixtures? Do not rush to a negative answer. Many of them you apply in your daily activities.

Pure substance: what is it

Atoms, molecules, substances and mixtures are the basic chemical concepts. What do they stand for? In the table of D. I. Mendeleev 118 chemical elements. These are different types elementary particles- atoms. They differ in mass.

Atoms combine with each other to form molecules, or substances. The latter, when combined with each other, form mixtures. Pure substances have constant composition and properties. These are homogeneous structures. But they can be divided into components by chemical reactions.

Scientists say that pure substances in nature practically do not exist. A small amount of impurities is in each of them. This is because most substances differ in activity. Even metals immersed in water dissolve in it at the ion level.

The composition of pure substances is always constant. It is simply impossible to change it. So, if the amount of carbon or oxygen in a carbon dioxide molecule is increased, it will be a completely different substance. And in the mixture, you can increase or decrease the number of components. This will change its composition, but not the fact of existence.

What is a mixture

A combination of several substances is called a mixture. They can be of two types. If the individual components in the mixture are indistinguishable, it is called homogeneous, or homogeneous. There is another name that is most often used in everyday life - a solution. The components of such a mixture cannot be separated physical methods. For example, from a saline solution, it will not be possible to mechanically extract the crystals that are dissolved in it. In nature, there are not only liquid solutions. So, air is a gaseous homogeneous mixture, and an alloy of metals is a solid.

In heterogeneous or heterogeneous mixtures, individual particles are visible to the naked eye. They differ from each other in composition and properties. This means that they can be separated from each other purely mechanically. Cinderella perfectly coped with this task, which the evil stepmother forced to separate the beans from the peas.

Chemistry: ways to separate mixtures

A huge number of mixtures are found in everyday life and nature. How to choose the right way to separate them? It must necessarily be based on the physical properties of the individual components. If substances have different boiling points, then evaporation followed by crystallization, as well as distillation, will be effective. Such methods are used to separate homogeneous solutions. To separate heterogeneous mixtures, the difference in other properties of their constituents is used: density, wettability, solubility, size, magnetism, etc.

Physical methods for separating mixtures

When the components of the mixture are separated, the composition of the substances themselves does not change. Therefore, it is impossible to name methods for separating mixtures chemical process. So, by settling, filtering and applying a magnet, it is possible to separate the individual components mechanically. Various devices are used in the laboratory: separating funnel, filter paper, magnetic stripes. These are methods for separating heterogeneous mixtures.

Screening

This method is perhaps the simplest. Every housewife knows him. It is based on the difference in the sizes of the solid components of the mixture. Sifting is used in everyday life to separate flour from impurities, insect larvae and various contaminants. In agricultural production, cereal grains are thus cleaned of foreign debris. Construction workers are sifting a mixture of sand and gravel.

settling

This method of separation of mixtures is used for components with different densities. If the sand gets into the water, the resulting solution must be mixed well and left for a while. The same can be done with a mixture of water and vegetable oil or oil. The sand will sink to the bottom. But the oil, on the contrary, will be collected from above. This method is observed in everyday life and nature. For example, soot settles from smoke, and separate drops of dew from fog. And if you leave homemade milk for the night, then by morning you can collect the cream.

Filtration

Drinkers of brewed tea use this method daily. We are talking about filtration - a method of separating mixtures based on the different solubility of the components. Imagine that iron filings and salt got into the water. Large insoluble particles will remain on the filter. And the dissolved salt will pass through it. The principle of this method underlies the work of vacuum cleaners, the action of respiratory masks and gauze bandages.

Magnet action

Suggest a method for separating mixtures of sulfur and iron powders. Naturally, this is the action of a magnet. Are all metals capable of this? Not at all. According to the degree of susceptibility, three groups of substances are distinguished. For example, gold, copper and zinc will not attach to a magnet. They belong to the group of diamagnets. Magnesium, platinum and aluminum differ in weak perception. But if the composition of the mixture includes ferromagnets, then this method will be the most effective. These include, for example, iron, cobalt, nickel, terbium, holmium, thulium.

Evaporation

What method of separation of mixtures is suitable for an aqueous homogeneous solution? This is evaporation. If you only have salty water, but you need a clean one - you should not immediately get upset. You need to heat the mixture to boiling point. As a result, the water will evaporate. And at the bottom of the dish, crystals of the dissolved substance will be visible. To collect water, it must be condensed - transferred from a gaseous state to a liquid one. To do this, the vapors are cooled, touching the surface with a lower temperature, and flow into the prepared container.

Crystallization

In science, this term is considered in a broader sense. It is not just a method for obtaining pure substances. By their nature, icebergs, minerals, bones and tooth enamel are crystals.

Their growth occurs under the same conditions. Crystals are formed as a result of cooling liquids or supersaturation of steam, and in the future the temperature should no longer change. Thus, some limiting conditions are first reached. As a result, a crystallization center appears, around which atoms of a liquid, melt, gas, or glass gather.

Distillation

Surely you have heard about the water, which is called distilled. This purified liquid is necessary for the manufacture of medicines, laboratory research, and cooling systems. And they get it in special devices. They are called distillers.

Distillation is a method of separating mixtures of substances with different boiling points. Translated from Latin the term means "drip-dropping". With this method, for example, alcohol and water can be separated from a solution. The first substance will begin to boil at a temperature of +78 o C. Alcohol vapors will subsequently condense. The water will remain in liquid form.

In a similar way, products of its processing are obtained from oil: gasoline, kerosene, gas oil. This process is not a chemical reaction. Oil is separated into separate fractions, each of which has its own boiling point. This happens in several stages. First, the primary separation of oil is carried out. It is cleaned from associated gas, mechanical impurities and water vapor. At the next stage, the resulting product is placed in distillation columns and heated. This is the atmospheric distillation of oil. At a temperature of less than 62 degrees, the remaining associated gas volatilizes. By heating the mixture to 180 degrees, gasoline fractions are obtained, up to 240 - kerosene, up to 350 - diesel fuel. The residue of thermal oil processing is fuel oil, which is used as a lubricant.

Chromatography

This method is named after the scientist who first used it. His name was Mikhail Semenovich Tsvet. Initially, the method was used to separate plant pigments. Literally, chromatography translates from Greek as "painting with color". Dip the filter paper into the mixture of water and ink. The first will immediately begin to be absorbed. This is due to varying degrees of adsorbing properties. This also takes into account diffusion and the degree of solubility.

Adsorption

Some substances have the ability to attract molecules of another kind. For example, we take activated charcoal for poisoning to get rid of toxins. This process requires an interface that is between the two phases.

This method is used in the chemical industry for the separation of benzene from gaseous mixtures, purification of liquid products of oil refining, their purification from impurities.

So, in our article, we examined the main methods for separating mixtures. A person uses them both at home and on an industrial scale. The choice of method depends on the type of mixture. An important factor is the features of the physical properties of its components. To separate solutions in which individual parts are visually indistinguishable, evaporation, crystallization, chromatography and distillation methods are used. If the individual components can be determined, such mixtures are called heterogeneous. To separate them, methods of settling, filtering and using a magnet are used.

Job directory.
Tasks 1. Pure substances and mixtures

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1) flour from iron filings that fell into it;

2) water from non-or-ha-no-che-salts dissolved in it?

Sp-so-would be times-de-le-niya mix-this: from-sta-and-va-nie, fil-tro-va-nie, dis-steel-la-tion (pe-re-race), action magician-ni-tom, you-pa-ri- va-nie, kri-became-li-for-tion. On ri-sun-kah 1–3, there are examples of using-pol-zo-va-niya of some of the en-re-number-len-spo-so -bov.


Rice. 1	Rice. 2	Rice. 3

Which of the named ways of de-le-la-ming mixtures can be used for cleansing:

1) in a boiled salt from iron filings that fell into it;

2) water from small particles of car-bo-on-ta calcium?

For-write-shi-te in the table-li-tsu the number of ri-sun-ka and the name of the co-from-the-reply-to-th-s-so-ba once-de-le-niya mixtures.

From the course of chemistry, you will know the following ways to de-le-se-mixes: from-sta-and-va-nie, fil-tro-va-nie, dis-steel-la-tion (pe-re-race), action magician-ni-tom, you-pa-ri- va-nie, kri-became-li-for-tion. On ri-sun-kah 1–3, there are examples of using-pol-zo-va-niya of some of the en-re-number-len-spo-so -bov.


Rice. 1	Rice. 2	Rice. 3

Which of the named ways of de-le-la-ming mixtures can be used for cleansing:

1) eta-no-la and water;

2) water and sand?

For-write-shi-te in the table-li-tsu the number of ri-sun-ka and the name of the co-from-the-reply-to-th-s-so-ba once-de-le-niya mixtures.


Rice. 1	Rice. 2	Rice. 3

Which of the named ways of de-le-la-ming mixtures can be used for cleansing:

1) water and potassium chloride;

2) me-ta-no-la and ku-soch-kov sulfur?

For-write-shi-te in the table-li-tsu the number of ri-sun-ka and the name of the co-from-the-reply-to-th-s-so-ba once-de-le-niya mixtures.


Rice. 1	Rice. 2	Rice. 3

Which of the named ways of de-le-la-ming mixtures can be used for cleansing:

1) a mixture of iron-lez-no-go and aluminum-mi-ni-e-vo-go in a rosh-ka;

2) water and oil?

For-write-shi-te in the table-li-tsu the number of ri-sun-ka and the name of the co-from-the-reply-to-th-s-so-ba once-de-le-niya mixtures.


Rice. 1	Rice. 2	Rice. 3

Which of the named ways of de-le-la-ming mixtures can be used for cleansing:

1) a mixture of ok-si-da silicon and metal-li-che-co-co-bal-ta;

2) ace-to-on and iso-pro-pi-la

For-write-shi-te in the table-li-tsu the number of ri-sun-ka and the name of the co-from-the-reply-to-th-s-so-ba once-de-le-niya mixtures.


Rice. 1	Rice. 2	Rice. 3

Which of the named ways of de-le-la-ming mixtures can be used for cleansing:

1) mixtures of barium sul-fa-ta and water;

2) water and pro-pa-no-la?

For-write-shi-te in the table-li-tsu the number of ri-sun-ka and the name of the co-from-the-reply-to-th-s-so-ba once-de-le-niya mixtures.


Rice. 1	Rice. 2	Rice. 3

Which of the named ways of de-le-la-ming mixtures can be used for cleansing:

1) a mixture of iron-lez-no-go and three-e-vo-go-rosh-ka;

2) ace-to-on and coal-no-rosh-ka?

For-write-shi-te in the table-li-tsu the number of ri-sun-ka and the name of the co-from-the-reply-to-th-s-so-ba once-de-le-niya mixtures.

A	B	IN	G

Answer:

Write down the numbers in response, sort them out in a row, corresponding to the letter-to-you:

A	B	IN	G

Answer:

Get-but-vi-the-correspondence between the substance and the area of its application: to each position, denoted -noy letter-howl, under-be-ri-te with-from-vet-stvo-th-th-th-th-zi-tion, denoted by a number swarm.

Write down the numbers in response, sort them out in a row, corresponding to the letter-to-you:

A	B	IN	G

Answer:

Get-but-vi-the-correspondence between the substance and the source-of-no-one of its-be-che-niya: to each in-zi-tion, designation -chen-noy letter-howl, under-be-ri-te with-from-vet-stu-u-th-studio-zi-tion, denoted by a number swarm.

Write down the numbers in response, sort them out in a row, corresponding to the letter-to-you:

A	B	IN	G

Answer:

Write down the numbers in response, sort them out in a row, corresponding to the letter-to-you:

A	B	IN	G

Answer:

Write down the numbers in response, sort them out in a row, corresponding to the letter-to-you:

A	B	IN	G

Answer:

Get-but-you-te-correspond-between the capacity and its sign-no-no: to each in-zi-tion, denoted by the beech -howl, under-be-ri-te with-from-the-reply-stu-stu-u-sche-zi-tion, denoted by a number swarm.

CAPACITY

FUNCTION

A) reverse ho-lo-dil-nick

B) measured qi-lindr

B) straight-my ho-lo-dil-nick

D) far-fo-ro-way mortar

4) from-melting solids

5) from-me-re-tion volume-e-ma dis-creative-ditch

Write down the numbers in response, sort them out in a row, corresponding to the letter-to-you:

A	B	IN	G

Answer:

Write down the numbers in response, sort them out in a row, corresponding to the letter-to-you:

A	B	IN	G

Answer:

Write down the numbers in response, sort them out in a row, corresponding to the letter-to-you:

A	B	IN	G

Answer:

CAPACITY

FUNCTION

A) reverse ho-lo-dil-nick

B) measuring flask

B) straight-my ho-lo-dil-nick

D) chlorine-calcium-qi-e-way pipe

1) in a step-pe-noe with-ka-py-va-nie race

2) con-den-si-ro-va-ing of vapors and return of con-den-sa-ta to the re-ac-ci-on-ny vessel

3) part of the pri-bo-ra for re-re-gon-ki

4) dehumidification of gases

5) at-go-tov-le-nie dis-tvo-ra defin-de-len-noy con-center-tra-tion

Write down the numbers in response, sort them out in a row, corresponding to the letter-to-you:

A	B	IN	G

Answer:

Write down the numbers in response, sort them out in a row, corresponding to the letter-to-you:

A	B	IN	G

Answer:

Write down the numbers in response, sort them out in a row, corresponding to the letter-to-you:

A	B	IN	G

Answer:

Write down the numbers in response, sort them out in a row, corresponding to the letter-to-you:

A	B	IN	G

Answer:

Get tired of the correspondence between the process and its goal: to each position, indicated by the letter, under-be-ri -te co-from-vet-stvo-u-sche-zi-tion, denoted by a numeral swarm.

Write down the numbers in response, sort them out in a row, corresponding to the letter-to-you:

A	B	IN	G

Answer:

1) cast iron sawdust from wood sawdust;

2) air from races-dusty in more small drops of water-to-emul-si-on-noy paint?

Which of the ways, some-rye-ka-za-us on ri-sun-kah, can you separate the mixture to clean it:

1) a solution of sodium chloride-and-sodium from the precipitation of hydro-rock-si-da-zhe-le-za (III);

2) uk-sus-nuyu sour-lo-tu, so-der-zha-shchu-yu-sya in a hundred-lo-voi uk-su-se, from water?

On-zo-vi-these method, someone was applied in each of the above examples.

From-ve-you write-shi-te in the following-du-th-table-li-tsu:

Which of the ways, some-rye-ka-za-us on ri-sun-kah, can you separate the mixture to clean it:

1) a solution of chlorine-da-sodium from the precipitation of sul-fa-ta barium;

2) iron shavings from wood sawdust?

On-zo-vi-these method, someone was applied in each of the above examples.

From-ve-you write-shi-te in the following-du-th-table-li-tsu:

Which of the ways, some-rye-ka-za-us on ri-sun-kah, can you separate the mixture to clean it:

1) medicinal herbal infusion from the use of the use of the bath for its preparation of the herbal mixture;

2) acetone from other components of nail polish remover?

On-zo-vi-these method, someone was applied in each of the above examples.

From-ve-you write-shi-te in the following-du-th-table-li-tsu:

Which of the ways, some-rye-ka-za-us on ri-sun-kah, can you separate the mixture to clean it:

1) water from the dissolved salts in it;

2) a solution of nit-ra-ta sodium from precipitation of chlo-ri-da se-reb-ra?

On-zo-vi-these method, someone was applied in each of the above examples.

From-ve-you write-shi-te in the following-du-th-table-li-tsu:

1) curd and curd sy-vo-mouth;

2) steel and plastic-mass-co-strings?

On-zo-vi-these method, someone was applied in each of the above examples.

From-ve-you write-shi-te in the following-du-th-table-li-tsu:

Which of the ways, some-rye-for-us on ri-sun-kah, can you de-pour the following mixtures:

1) a solution of sul-fa-ta sodium and a precipitate of hydro-rock-si-da copper (II);

2) iron nails and river sand?

On-zo-vi-these method, someone was applied in each of the above examples.

From-ve-you write-shi-te in the following-du-th-table-li-tsu:

1) you-yav-le-niya from-me-not-niy, pro-is-go-dying with races-the-ne-i-mi after outside-se-ing of conveniences;

2) determine-de-le-niya time-me-no races-tvo-re-niya sa-ha-ra in cold water.

On-zo-vi-these method, someone was applied in each of the above examples.

From-ve-you write-shi-te in the following-du-th-table-li-tsu:

From the course of chemistry, you will know the following methods of knowledge: on-blue-de-nie, ex-pe-ri-ment, from-me-re-nie.

On ri-sun-kah 1-3, there are representations of si-tu-a-tions, in some cases, in some cases, the indicated methods are known -tion.

The indicated methods can be used in all-day life with the aim of:

1) determine the de-le-tion of the values of the-pe-ra-tu-ry, with some-swarm the first bubbles, swirls de-tel-stvu-yu-schi about for-ki-pa-ni water;

2) study of the influence of the dis-creation of uk-su-sa on the dis-creation of drinking soda.

On-zo-vi-these method, someone was applied in each of the above examples.

From-ve-you write-shi-te in the following-du-th-table-li-tsu:

Process example	Ri-sun-ka number	Knowledge Method
define-de-le-tion the meanings of those-pe-ra-tu-ry, with some-swarm the first bubbles-ki, sw-de- tel-stu-yu-shchi about for-ki-pa-nii water
Ga-she-nie dis-two-ra pi-thie-how of soda uk-su-som

From the course of chemistry, you will know the following methods of knowledge: on-blue-de-nie, ex-pe-ri-ment, from-me-re-nie.

On ri-sun-kah 1-3, there are representations of si-tu-a-tions, in some cases, in some cases, the indicated methods are known -tion.

The indicated methods can be used in all-day life with the aim of:

1) definition of de-le-tion of the meaning of con-centr-tra-tion of nit-ra-tov in ar-bu-ze;

2) fix-sa-tion from-me-not-ny, pro-iso-went-shih with dre-ve-si-noy after its about-ra-bot-ki hi-mi-che-ski-mi-re- ak-ti-va-mi.

On-zo-vi-these method, someone was applied in each of the above examples.

From-ve-you write-shi-te in the following-du-th-table-li-tsu:

Process example	Ri-sun-ka number	Knowledge Method
define-de-le-tion the meaning of con-centr-tra-tion of nit-ra-tov in ar-bu-ze
fic-sa-tion from-me-not-ny, pro-iso-went-shih with dre-ve-si-noy after its re-ra-bot-ki ras-tvo-rum per-man-ha-na- that potassium

Which of the named ways of de-le-la-ming mixtures can be used for cleansing:

1) steel buttons from wood sawdust;

2) air-du-ha from dusty small drops of water-to-emul-si-on-noy paint?

For-write-shi-te in the table-li-tsu the number of ri-sun-ka and the name of the co-from-the-reply-to-th-s-so-ba once-de-le-niya mixtures.

Which of the named ways of de-le-la-ming mixtures can be used for cleansing:

1) cereals and iron sawdust that fell into it;

2) water and salts dissolved in it.

For-write-shi-te in the table-li-tsu the number of ri-sun-ka and the name of the co-from-the-reply-to-th-s-so-ba once-de-le-niya mixtures.

Which of the named ways of de-le-la-ming mixtures can be used for cleansing:

1) this-no-la and uk-sus-noy sour-lo-you;

2) water and shake-tan clay in it.

For-write-shi-te in the table-li-tsu the number of ri-sun-ka and the name of the co-from-the-reply-to-th-s-so-ba once-de-le-niya mixtures.

Pro-ana-li-zi-rui-te given ri-sun-ki and opre-de-li-te:

1) an atom of a chi-mi-che-sko-th element in the representation of the mo-de-lyah mo-le-cool manifests-la-et va-lentes -ness equal to IV;

2) the atoms of a chi-mi-che-sko-th element in the representation of the mo-de-lyah mo-le-cool are united between with itself with a-ra-zo-va-ni-em of a pro-hundred-th substance.

For-write-shi-te in the table-li-tsu for the title of hi-mi-che-sko-go element-men-ta and the number of ri-sun-ka.

Particularly ben-no-sti stro-e-niya	Chemical element	Ri-sun-ka number
Manifestation of valency IV
Connect with each other with an ob-ra-zo-va-ni-em pro-hundred-th

From the course of chemistry, you from-wes-we-do-u-s so-so-would time-de-le-niya mix-this: from-sta-and-va-nie, fil-tro-va-nie, dis-steel-la-tion (pe-re-race), action magician-ni-tom, you-pa-ri- wa-tion, pe-re-cree-became-li-for-tion.

From among the en-re-numbers below the mixtures, you-be-ri-those are those that you can de-pour data-us-so-ba-mi:

a) clay and coal;

b) water and sodium sulfate;

c) sugar sand and chalk;

d) pen-tan and ben-zol.

Ri-sun-ka number	Method of dividing the mixture	Composition of the mixture
1
2

and etc.

1) the quality of the determination of the co-hundred-va mi-ne-ral-ny water;

2) determination of the exact value of the pH of the solution of the substance.

On ri-sun-kah 1 and 2, there are representations of pri-bo-ry, use-zu-u-shchi-e-xia to separate the mixtures by two of the indicated busy ways.

From among the number of mixtures below, you-be-ri-those are those that can be de-poured in the way shown on ri-sun -kah:

a) iron and wood sawdust;

b) water and particles of clay;

c) chalk and starch;

d) oil and water.

Write in the columns of the table for the names of the ways of dividing the mixture, corresponding to the answer to each of ri-sun-kov, and co-hundred-you co-from-vet-stvo-u-th-mixtures.

Ri-sun-ka number	Method of dividing the mixture	Composition of the mixture
1
2

One of the scientific methods of knowing substances and chi-mi-che-sky phenomena is yav-la-et-sya mo-de-li-ro-va- nie. So, mo-de-li mo-le-cool give an idea of the relationship between the structure and the properties of substances.

On ri-sun-kah 1–3, there are images of mo-de-li mo-le-cool of three substances.

Pro-ana-li-zi-rui-te data mo-de-li mo-le-cool of things and define-de-li-those thing, someone swarm:

1) ob-ra-zo-van-but with two hi-mi-che-ski-mi ele-men-ta-mi;

2) contains a chi-mi-che-element, which manifests a valence equal to IV.

From the West, but that oxygen is a gas heavier than air-du-ha and poorly dissolves in water. Which of the methods given on ri-sun-kah can be used to co-bi-ra-niya sour-lo-ro-da? Indicate which property of sour-lo-ro-yes you learn-va-et-sya when using each way-so-ba.

The answer is for-pi-shi-te in the table-li-tsu.

The method of co-bi-ra-niya sour-lo-ro-da	Ri-sun-ka number	Property sour-lo-ro-da
You-tes-not-nie air-doo-ha
You-tes-non-water

From the course of chemistry, you will know the following methods for knowing substances and phenomena: on-blue-de-nie, ex-pe-ri-ment, from-me-re-nie, mo-de-li-ro-va-nie and etc.

On ri-sun-kah 1–3, for-a-for-us-a-mea-ry with-me-not-niya of some of these methods.

Determine what methods can be used for:

1) high-quality ana-li-for co-hundred-va sul-fa-ta copper (II);

2) illustration of lu-stra-tion of chi-mi-che-th-th structure of a substance.

For-write-shi-te in the table-li-tsu the names of the methods and the corresponding no-me-ra ri-sun-kov.

From the course of chemistry, you from-wes-we-do-u-s so-so-would

Determine-de-li-those, which of the depicted ways of de-de-le-ing mixtures can be used for di-de-le-ning:

1) flour and iron shavings;

2) water and wood sawdust.

On ri-sun-kah 1–3, there are images of mo-de-li mo-le-cool of three substances.

Pro-ana-li-zi-rui-te ri-sun-ki mo-de-lei mo-le-cool of things and define-de-li-those thing, something swarm:

1) about-ra-zo-va-but with one chi-mi-che-sky element;

2) contains a chi-mi-che-element, something manifests a valence equal to four.

For-write-shi-te in the tab-li-tsu no-me-ra ri-sun-kov and chi-mi-che-form-mu-ly of these substances.

Chi-mi-che-form-mu-ly for-pi-shi-te in the table in the following form: Al2 (SO4) 3.

From the course of chemistry, you know that when you get gas-o-ob-different substances in la-bo-ra-to-ri, collect in-lu- cha-e-my gas can be in two ways-so-ba-mi: you-tes-don't-eat water and you-tes-don't-eat air-du-ha.

In Figures 1–3, there are images of devices for obtaining and collecting various gases.

From-the-west-but that am-mi-ak - gas is lighter than air-du-ha and ho-ro-sho ras-your-ri-my in water. What are the methods of those, some-rye pri-ve-de-na on ri-sun-kah, it is forbidden use-pol-zo-vat for co-bi-ra-niya am-mi-a-ka? Indicate which properties am-mi-a-ka do not allow these methods to be applied.

For-write-shi-te in the tab-li-tsu no-me-ra ri-sun-kov and the names of co-from-the-reply-stu-u-s-so-so-bov so-bi-ra -tion of gas.

Gas co-bi-ra-tion method	Ri-sun-ka number	Gas property

From the course of chemistry, you from-wes-we-do-u-s so-so-would raz-de-le-niya mixtures: from-hundred-and-va-nie, filter-tro-va-nie, di-steel-la-tion (pe-re-gon-ka), action magician -neither, you-pa-ri-va-nie, pe-re-cree-became-li-za-tion.

On the ri-sun-kah 1–3, there are examples of using some of the en-re-numbers of ways -bov.

Which of the named methods of times-de-le-tion mixtures can be used for de-le-tion:

1) wood shavings from steel nuts;

2) water from water-to-growth and clay in it?

For-write-shi-te in the tab-li-tsu no-me-ra ri-sun-kov and the names of the co-from-the-rep-stu-u-s-s-so-bov times-de-le -tion of the mixture.

On the ri-sun-kah 1–3 images of the same-we-us-me-ry use of some of the en-re-number-len-spo-so -bov.

Define-de-li-those, which of the depicted ways of de-le-la-ing mixtures can be used for de-le-le-ning:

1) sand from iron nails that fell into it;

2) alcohol from the aro-ma-ti-che essential oils dissolved in it?

For-write-shi-te in the tab-li-tsu no-me-ra ri-sun-kov and the names of the co-from-the-rep-stu-u-s-s-so-bov times-de-le -tion of the mixture.

On the ri-sun-kah 1–3 images of the same-we-us-me-ry use of some of the en-re-number-len-spo-so -bov.

Which of the named ways of mixtures can be used to separate the thread:

1) steel and plastic-mass staples;

2) water and chalk gravel?

For-write-shi-te in the tab-li-tsu no-me-ra ri-sun-kov and the names of the co-from-the-rep-stu-u-s-s-so-bov times-de-le -tion of the mixture.

On the ri-sun-kah 1–3 images of the same-we-us-me-ry use of some of the en-re-number-len-spo-so -bov.

Which of the named ways to de-le-fly mixtures can be used for:

1) from de-le-tion of wood shavings from iron nails that fell into them;

2) cleaning the breath-ha-e-mo-th air-du-ha from small particles of as-be-sto-howling dust?

For-write-shi-te in the tab-li-tsu no-me-ra ri-sun-kov and the names of the co-from-the-rep-stu-u-s-s-so-bov times-de-le -tion of the mixture.

From the course of chemistry, you from-wes-we-do-u-s me-to-knowledge : on-blue-de-nie, ex-pe-ri-ment, from-me-re-nie.

1) when you-yav-le-ni from-me-not-niy, pro-is-going-dying after processing the ras-the-ny means against the time-di- te-lei;

2) when determining the concentration of dissolved salts in water-to-wire water.

On-zo-vi-these method, someone was applied in each of the above examples.

Process example	Ri-sun-ka number	Knowledge Method
You-y-y-le-ne from-me-not-ny, about-is-ho-dying after about-ra-bot-ki ras-te-ny means against time-di-te-lei
Determining the concentration of dissolved salts in water-to-wire water

From the course of chemistry, you from-wes-we-do-u-s me-to-knowledge : on-blue-de-nie, ex-pe-ri-ment, from-me-re-nie.

On ri-sun-kah 1–3, there are representations of si-tu-a-tions, in some cases, in some cases, the indicated methods are known -tion.

Determine which of the indicated methods can be used in everyday life:

1) when you-yav-le-nii signs of cor-ro-ziya ku-zo-va av-to-mo-bi-la;

2) when studying the properties of car-bo-on-that sodium.

From-ve-you for-pi-shi-te in the next-du-u-table-tsu.

From the course of chemistry, you from-wes-we-do-u-s me-to-knowledge : on-blue-de-nie, ex-pe-ri-ment, from-me-re-nie.

On ri-sun-kah 1–3, there are representations of si-tu-a-tions, in some cases, in some cases, the indicated methods are known -tion.

Determine which of the indicated methods can be used in everyday life:

1) when you-yav-le-ni from-me-not-ny, pro-is-ho-dying after influencing ema-li-ro-van-nye from de-liya dis- creation of mo-th means;

2) when determining the presence of dissolved substances in water.

From-ve-you for-pi-shi-te in the next-du-u-table-tsu.

Process example	Ri-sun-ka number	Knowledge Method
You-y-y-le-ne from-me-not-ny, about-is-ho-dying with em-li-ro-van-ny-mi from de-li-i-mi after air the effects on them of the dis-creation of my-th-means
Defining the presence of dissolved substances in water

From the course of chemistry, you from-wes-we-do-u-s me-to-knowledge : on-blue-de-nie, ex-pe-ri-ment, from-me-re-nie.

On ri-sun-kah 1–3, there are representations of si-tu-a-tions, in some cases, in some cases, the indicated methods are known -tion.

Determine which of the indicated methods can be used when:

1) you-yav-le-nii signs of pro-te-ka-niya chi-mi-che-sky reaction;

2) define-de-le-nii con-centr-tra-tion of nit-ra-tov in mi-do-ra.

On-zo-vi-these method, someone was applied in each of the above examples.

From-ve-you write-shi-those in the next-du-th-table-li-tsu.

From the course of chemistry, you from-wes-we-do-u-s me-to-knowledge : on-blue-de-nie, ex-pe-ri-ment, from-me-re-nie.

On ri-sun-kah 1–3, there are representations of si-tu-a-tions, in some cases, in some cases, the indicated methods are known -tion.

Determine which of the indicated methods can be used in all-day life with:

1) you-yav-le-ni from-me-not-niy, about-is-ho-dying with con-ser-vi-ro-van-ny-mi vegetables while storing research institutes;

2) define-de-le-nii con-center-tra-tion of the race of my-th-th-th-th means.

From-ve-you for-pi-shi-te in the tab-li-tsu.

Process example	Ri-sun-ka number	Knowledge Method
You-yav-le-ni from-me-not-niy, about-is-ho-dying with con-ser-vi-ro-van-ny-mi vegetables during storage
Determination of the con-centr-tra-tion of the dis-creation of my-th-th-th-th means

One of the scientific methods of knowing substances and chi-mi-che-sky phenomena is yav-la-et-sya mo-de-li-ro-va- nie. So, mo-de-li mo-le-cool from-ra-zha-yut ha-rak-ter-signs of re-al-ny objects.

On fig. 1–3 images of the same mo-de-li mo-le-cool of three substances.

Pro-ana-li-zi-rui-te data mo-de-li mo-le-cool things and define-de-li-those things:

1) ob-ra-zo-van-noe with three hi-mi-che-ski-mi ele-men-ta-mi;

2) in some rum, one of the elements manifests valency II.

Each component of the mixture retains a set of its characteristics, so different substances can be isolated from the mixture.

settling- This is a method based on the different densities of substances.

For example, a mixture of vegetable oil and water can be separated into oil and water by simply allowing the mixture to settle.

Filtration- This is a method based on the different ability of the filter to pass the substances that make up the mixture. For example, with the help of a filter, solid impurities can be separated from a liquid.

Evaporation- is the separation of non-volatile solids from a solution in a volatile solvent - in particular water. For example, to isolate salt dissolved in water, you just need to evaporate the water. The water will evaporate and the salt will remain.

Preparation of solutions.

chemical pollution environment and its consequences.

A14. Qualitative reactions, indicators, gases.

A14. Determination of the nature of the medium of a solution of acids and alkalis using indicators. Qualitative reactions to ions in solution (chloride, sulfate, carbonate ions, ammonium ion). Obtaining gaseous substances. Qualitative reactions to gaseous substances (oxygen, hydrogen, carbon dioxide, ammonia).

1) Table of color changes of indicators in various environments:

2) Qualitative reactions to ions in solution.

For cations:

Cation	Reagent	Observed response
Li +	flame
Na+	flame	Yellow staining
K+	flame	purple staining
Ca 2+	flame	Brick red coloring
Sr2+	flame	Carmine red color
Va 2+	flame SO 4 2-	Yellow-green color Precipitation of a white precipitate, insoluble in acids: Ba 2+ + SO 4 2- → BaSO 4
Сu 2+	HE -	Blue precipitation: Cu 2+ + 2OH - → Cu (OH) 2
Pb 2+	S2-	Black precipitation: Pb 2+ + S 2- → PbS
Ag+	Cl-	Precipitation of a white precipitate; insoluble in HNO 3 but soluble in conc. NH 3 H 2 O: Ag + +Cl - →AgCl
Fe2+	1) OH - 2) potassium hexacyano-ferrate (III) (red blood salt), K 3	1) Precipitation of a light green precipitate: Fe 2+ + 2OH - → Fe (OH) 2 2) Precipitation of a blue precipitate: K + + Fe 2+ + 3- → KFe 4
Fe3+	1) OH - 2) potassium hexacyanoferrate (II) (yellow blood salt) K 4 3) rhodanide ion SCN -	1) Precipitation of a brown precipitate: Fe 3+ + 3OH - → Fe (OH) 3 2) Precipitation of a blue precipitate: K + + Fe 3+ + 4- → KFe 3) Appearance of bright red color due to the formation of Fe (SCN) complex ions ) 2+ , Fe(SCN) + 2
Al 3+	alkali (amphoteric properties of hydroxide)	Precipitation of aluminum hydroxide during the addition of the first portions of alkali and its dissolution upon further addition
NH4+	alkali, heating	The smell of ammonia: NH 4 + + OH - → NH 3 + H 2 O
H + (acidic environment)	indicators: litmus, methyl orange	red coloring red coloring

For anions:

Anion	Reagent	Observed response
SO 4 2-	Va 2+	Precipitation of a white precipitate, insoluble in acids: Ba 2+ + SO 4 2- BaSO 4
NO 3 -	Add conc. H 2 SO 4 and Si, heat up	Formation of a blue solution containing Cu 2+ ions, brown gas evolution (NO 2)
RO 4 3-	Ag+ ions	Precipitation of a light yellow precipitate in a neutral medium: ZAg + + PO 4 3- Ag 3 PO 4
S2-	Pb ions 2+	Black precipitation: Pb 2+ + S 2- PbS
CO 3 2-	Ca 2+ ions	Precipitation of a white precipitate, soluble in acids: Ca 2+ + CO 3 2- \u003d CaCO3
CO2	lime water Ca(OH) 2	Ca (OH) 2 + CO 2 CaCO 3 + H 2 O, CaCO 3 + CO 2 + H 2 O Ca (HCO 3) 2 Precipitation of a white precipitate and its dissolution when passing CO 2
SO 3 2-	H + ions	The appearance of a characteristic odor SO 2: 2H + + SO 3 2- H 2 O + SO 2
F-	Ca 2+ ions	Precipitation of a white precipitate: Ca 2+ + 2F - CaF 2
Cl-	Ag+ ions	Precipitation of a white precipitate, insoluble in HNO 3 but soluble in conc. NH 3 H 2 O: Ag + + CI - AgCl AgCI + 2 (NH 3 H 2 O) + + CI - + 2H 2 O
br-	Ag+ ions	Precipitation of a light yellow precipitate, insoluble in HNO 3: Ag + + Br - = AgBr precipitate darkens in the light
I-	Ag+ ions	Precipitation of a yellow precipitate, insoluble in HNO 3 and NH 3 conc.: Ag + + I - AgI the precipitate darkens in the light
OH - (alkaline)	indicators: litmus phenolphthalein	blue color crimson color

3) Obtaining gaseous substances. Qualitative reactions to gaseous substances (oxygen, hydrogen, carbon dioxide, ammonia).

Gas (brief description)	Getting (reaction equations)	picking up	Recognition
Hydrogen (H 2) is the lightest, colorless, odorless.	Displacement of hydrogen by metals from acid solutions: Zn + 2HCl \u003d ZnCl 2 + H 2.	In a test tube upside down.	When brought to the flame, a "pop" or "barking" sound is heard.
Oxygen (O 2) is odorless and colorless, heavier than air, slightly soluble in water.	1. Decomposition of potassium permanganate: 2KMnO 4 = K 2 MnO 4 + MnO 2 + O 2 2. Decomposition of hydrogen peroxide (MnO 2 catalyst): 2H 2 O 2 = 2H 2 O + O 2	1. Air displacement. 2.Water displacement.	Flashing of a smoldering splinter introduced into a vessel with oxygen.
Carbon dioxide - carbon monoxide (IV) - CO 2. Colourless, odorless, non-flammable, heavier than air. Soluble in water.	1. In industry: CaCO 3 = CaO + CO 2 2. In the laboratory: CaCO 3 + 2HCl = CaCl 2 + H 2 O + CO 2

While studying chemistry, I learned that there are very few pure substances in nature, technology, and everyday life. Much more common are mixtures - combinations of two or more components that are not chemically related to each other. Mixtures differ in the size of the particles of substances included in their composition, as well as the state of aggregation of the components. Chemical research requires pure substances. But how can they be obtained or isolated from the mixture? This is the question I tried to answer in my work.

IN Everyday life we are surrounded by mixtures of substances. The air we breathe, the food we consume, the water we drink, and even ourselves - all these are chemically mixtures containing from 2-3 to many thousands of substances.

Mixtures are systems consisting of several components that are not chemically related to each other. Mixtures are distinguished by the size of their constituent particles of substances. Sometimes these particles are so large that they can be seen with the naked eye. Such mixtures, for example, include washing powder, culinary mixtures for baking, building mixtures. Sometimes the particles of the components in mixtures are smaller, indistinguishable to the eye. For example, flour contains grains of starch and protein that cannot be distinguished with the naked eye. Milk is also a mixture of water, which contains small droplets of fat, protein, lactose and other substances. You can see fat droplets in milk if you look at a drop of milk under a microscope. The aggregate state of substances in mixtures can be different. Toothpaste, for example, is a mixture of solid and liquid ingredients. There are mixtures, during the formation of which substances “penetrate each other” so much that they break up into tiny particles that are not distinguishable even under a microscope. No matter how we peer into the air, we will not be able to distinguish its constituent gases.

Thus, mixtures are classified:

Mixtures in which particles of substances that make up the mixture are visible to the naked eye or under a microscope are called heterogeneous or heterogeneous.

Mixtures in which even with a microscope it is impossible to see the particles of the substances that make up the mixture are called homogeneous or homogeneous.

Homogeneous mixtures according to the state of aggregation are divided into gaseous, liquid and solid. A mixture of any gases is homogeneous. For example, clean air is a homogeneous mixture of nitrogen, oxygen, carbon dioxide and noble gases. But dusty air is already a heterogeneous mixture of the same gases, only containing more dust particles. Oil is a liquid natural mixture. It contains hundreds of different components. Of course, the most common liquid mixture, or rather a solution, is the water of the seas and oceans. 1 liter of sea water contains an average of 35 grams of various salts. We encounter liquid mixtures in everyday life all the time. Shampoos and drinks, potions and household chemicals are all mixtures of substances. Even tap water cannot be considered a pure substance: it contains dissolved salts, the smallest insoluble impurities, as well as microorganisms that are disinfected by chlorination. Solid mixtures are also widespread. Rocks are a mixture of several substances. Soil, sand, clay are solid mixtures. Solid mixtures include glass, ceramics, alloys.

Chemists make mixtures by simply mixing various substances - constituents, the properties of which may be different. It is important that the properties of their constituents are preserved in mixtures. So, for example, gray paint is obtained by mixing black and white. Although we see gray, this does not mean that all particles of such gray paint are gray. Under the microscope, particles of black and white colors are sure to be found, of which black and white paint consisted.

The separation of mixtures into constituent parts (individual substances) is a more difficult task than the preparation of mixtures, but no less important. The most important ways of separating mixtures can be reflected in the scheme:

Using various methods for separating mixtures (settling, filtering, distillation, freezing, and others), oil is obtained from milk, gold from river sand, alcohol from mash, and water is purified from insoluble and soluble impurities.

Chemical laboratories and industry often require pure substances. Pure substances are substances that have constant physical properties, such as distilled water. (Practically absolutely pure substances have not been obtained.)

There are various ways to separate mixtures. Let's take a closer look at these methods.

Isolation from an inhomogeneous mixture.

1. Settling.

a) Isolation of substances of an inhomogeneous mixture formed by water-insoluble substances with different densities. For example, iron filings can be separated from wood filings by shaking this mixture with water and then settling. Iron filings sink to the bottom of the vessel, and wood filings float up, and they can be drained along with water.

b) Some substances are deposited in water at different rates. If you shake clay mixed with sand with water, the sand settles much faster. This method is used in ceramic production to separate sand from clay (production of red bricks, earthenware, etc.) c) Separation of a mixture of liquids with different densities that are slightly soluble in each other. Mixtures of gasoline with water, oil with water, vegetable oil with water quickly separate, so they can be separated using a separating funnel or column. Sometimes liquids with different densities are separated by centrifugation, such as cream from milk.

2. Filtering.

Isolation of substances from an inhomogeneous mixture formed by water-soluble substances.

To isolate table salt, its mixture with sand is shaken in water. Table salt dissolves and sand settles.

To speed up the separation of insoluble particles from the solution, the mixture is filtered. The sand remains on the filter paper, and a clear salt solution passes through the filter.

3. Action by a magnet.

Isolation from an inhomogeneous mixture of substances capable of magnetization. If there is, for example, a mixture of powders of iron and sulfur, they can be separated using a magnet.

Separation of substances from a homogeneous mixture.

4. Evaporation. Crystallization.

In order for a solute, such as table salt, to be separated from a solution, the latter is evaporated. The water evaporates, and table salt remains in the porcelain cup. Sometimes evaporation is used, i.e. partial evaporation of water. As a result, a more concentrated solution is formed, upon cooling of which the solute is released in the form of crystals. This method of purification of substances is called crystallization.

5. Distillation.

This method of separating mixtures is based on the difference in the boiling points of components soluble in each other.

Distillation (distillation) is a technique for separating homogeneous mixtures by evaporation of volatile liquids, followed by condensation of their vapors. For example, getting distilled water.

To do this, water with the substances dissolved in it is boiled in one vessel. The resulting water vapor condenses in another vessel in the form of distilled water.

6. Chromatography.

This method is based on the fact that individual substances are absorbed (bound) by the surface of another substance at different rates.

The essence of this method can be found in the following experiment.

If a strip of filter paper is hung over a vessel with red ink and only the end of the strip is immersed in them, then it can be seen that the solution will be absorbed by the paper and rise along it. However, the paint rise limit will lag behind the water rise limit. Thus, there is a separation of two substances: water and a coloring matter that gives the solution a red color.

Experimental part.

Safety rules in the home laboratory.

It is impossible to imagine chemistry without chemical experiments. Therefore, it is possible to study this science, understand its laws and, of course, fall in love with it only through an experiment. There was an opinion that a chemical experiment is complex equipment and inaccessible reagents, poisonous compounds and terrible explosions, and special conditions are necessary for practicing chemistry. However, more than 300 chemical experiments with the most various substances can be done at home. Due to the fact that there is no fume hood and other special devices in the home laboratory, it is necessary to strictly follow the safety rules:

2. Do not accumulate and store large quantities of reagents at home.

3. Chemical reagents and substances must have labels with names, concentration and production date.

4. Chemicals must not be tasted.

5. To determine the smell, you can not bring a vessel with a substance close to your face. It is necessary to make a few smooth strokes with the palm of your hand from the opening of the vessel to the nose.

6. If acid or alkali has spilled, then the substance is first neutralized or covered with sand and removed with a rag or collected in a scoop.

7. Before conducting an experiment, no matter how simple it may seem, you need to carefully read the description of the experiment and understand the properties of the substances used. For this there are textbooks, reference books and other literature.

Experience number 1. Separation of heterogeneous mixtures.

A) Prepare a heterogeneous mixture of sand and iron powder.

The purpose of the experiment: to learn how to separate heterogeneous mixtures in different ways.

Equipment: river sand, iron powder, magnet, two beakers.

Add one tablespoon of iron powder and river sand to the beaker, gently mix the mixture until the product is evenly colored. Mark its color and test its magnetic properties by holding the magnet to the outside of the glass. Determine what substances give the mixture color and magnetic properties. Separate the prepared heterogeneous mixture with a magnet. To do this, we will bring a magnet to the outer wall of the glass, and lightly tapping the magnet on the outer wall, we will collect iron powder on the inner wall of the glass. Holding the iron with a magnet on the inner wall of the glass, pour the sand into another glass. The experimental data are entered in the table.

B) Prepare a mixture of table salt, earth and shavings formed after sharpening a pencil.

Equipment: table salt, earth, shavings after sharpening a pencil, glass, water, filter, spoon, frying pan.

Experiment Method:

Prepare the mixture by mixing one teaspoon each of table salt, earth and pencil shavings. Dissolve the resulting mixture in a glass of water, remove the floating chips with a slotted spoon and lay them on a sheet of paper to dry. Make a bandage or gauze filter by folding 3-4 layers, and pull it loosely over another glass. Filter the mixture. Dry the filter with the remaining earth, then clean it off the filter. Pour the filtered liquid (filtrate) from a glass into an enameled bowl or pan and evaporate. Collect the separated salt crystals. Compare the amounts of substances before and after the experiments.

Experience number 2. Separation of homogeneous mixtures by paper chromatography.

A) Separate a homogeneous mixture of red and green dye.

Equipment: a strip of filter paper, a beaker, a cork on a beaker, red and green felt-tip pens, alcohol (70% aqueous solution).

Experiment Method:

Take a strip of filter paper, the length of which is 2-3 cm longer than the height of the beaker. In the middle of this strip, mark a point with a simple pencil, stepping back from the edge of 1.5 cm. Apply stains of dyes with a diameter of no more than 5 mm to the marked point with felt-tip pens. First, make a dot 1-2 mm in size with a red felt-tip pen, and then apply green on top of the red spot so that the green spot protrudes beyond the red border by about 1 mm. Let the stain of the mixture dry (1-2 minutes) and then carefully, so as not to damage the paper, circle it with a simple pencil along the contour.

Pour alcohol into a beaker with a layer of 0.5-1 cm. Place a paper strip with a stain of a mixture of dyes vertically into a beaker and bend the protruding part of the strip to the outer surface of the beaker. The stain of dyes should be above the liquid at a distance of 0.5 cm. Cover the glass with an inverted cork. Observe the wetting of the strip of paper and the movement of the colored spot upwards, dividing it into two spots. It will take about 20 minutes to completely separate the dye mixture. After the paper is completely saturated with alcohol, take it out and let it dry for 5-10 minutes. Mark the colors of the spot separation. Record the results of observations in the table.

B) Separate the following mixtures by chromatography on paper: an alcoholic solution of "brilliant green"; aqueous solution of black ink for drawing work.

The purpose of the experiment: to master the method of paper chromatography, to learn how to determine the difference between pure substances and mixtures.

Equipment: a chemical beaker, a strip of filter or blotting paper, an alcohol solution of "brilliant green", an aqueous solution of ink for drawing work.

Experiment Method:

A strip of filter paper must be hung over a vessel with a solution of greenery and black ink so that the paper only touches the solution.

The border of the rise of "brilliant green" and the coloring matter will lag behind the border of the rise of alcohol and water, respectively. Thus, there is a separation of two substances in the composition of homogeneous mixtures: a) alcohol and brilliant green, b) water and coloring matter.

Experience number 3. Diffusion.

The purpose of the experiment: to study in practice the process of diffusion.

Equipment: food gelatin, potassium permanganate, copper sulfate, water, saucepan, stainless steel spoon for stirring, electric or gas stove, tweezers, two transparent vials.

Experiment Method:

Drop a teaspoon of gelatin into a glass of cold water and leave for an hour or two so that the powder has time to swell. Pour the mixture into a small saucepan. Heat the mixture over low heat; make sure that it does not boil in any case! Stir the contents of the saucepan until the gelatin is completely dissolved. Pour the hot solution into two vials. When it cools down, in the middle of one of the bubbles, with a quick and careful movement, insert tweezers in which a crystal of potassium permanganate is clamped. Slightly open the tweezers and quickly remove them. In another vial, add a crystal of copper sulfate. Gelatin slows down the diffusion process, and for several hours in a row you can observe a very interesting picture: a colored ball will grow around the crystals.

Experience number 4. Separation of homogeneous mixtures by crystallization.

Grow a crystal or crystals from a saturated sodium chloride solution, copper sulphate, or potassium alum.

The purpose of the experiment: to learn how to prepare a saturated solution of table salt or other substances, grow crystals of various sizes, consolidate skills and abilities when working with substances and chemical equipment.

Equipment: a glass and a liter jar for preparing a solution, a wooden spoon or a stirring stick, salt for the experiment - table salt, blue vitriol or alum, hot water, a seed - a salt crystal suspended on a thread, a funnel and filter paper.

Experiment Method:

Prepare a saturated salt solution. To do this, first pour into a jar hot water up to half its volume, then add the appropriate salt in portions, stirring constantly. Add salt until it no longer dissolves. Filter the resulting solution into a glass through a funnel with filter paper or cotton and leave the solution to cool for 2-3 hours. Introduce a seed into the cooled solution - a salt crystal suspended on a thread, carefully cover the solution with a lid and leave for a long time (2-3 days or more).

Results of the work and conclusions:

Examine your crystal and answer the questions:

How many days did you grow the crystal?

What is its shape?

What color is the crystal?

Is it transparent or not?

What are the dimensions of the crystal: height, width, thickness?

What is the mass of the crystal?

Sketch or photograph your crystal.

Experience number 5. Separation of homogeneous mixtures by distillation.

Get at home 50 ml of distilled water.

The purpose of the experiment: to learn how to separate homogeneous mixtures by distillation.

Equipment: enameled teapot, two glass jars.

Experiment Method:

Pour 1/3 of the water into an enameled teapot and place it on a gas stove so that the spout of the teapot protrudes beyond the edge of the stove. When the water boils, fasten a glass jar-refrigerator on the spout of the kettle, under which fit a second jar to collect condensate. In order for the refrigerator jar not to overheat, you can put a napkin moistened with cold water on it.

Results of the work and conclusions:

Answer the questions posed:

What is tap water?

How are homogeneous mixtures separated?

What is distilled water? Where and for what purposes is it used?

Write down your experience.

Experience number 6. Extraction of starch from potatoes.

Get a small amount of starch at home.

Equipment: 2-3 potatoes, grater, cheesecloth, small saucepan, water.

Experiment Method:

Grate the peeled potatoes on a fine grater and stir the resulting mass in water. Then filter it through cheesecloth and squeeze. Mix the rest of the mass in gauze again with water. Let the liquid settle. The starch will settle to the bottom of the dish. Drain the liquid, and stir the settled starch again. Repeat the operation several times until the starch is completely clean and white. Filter and dry the resulting starch.

What do you think, from which potato will you get more starch: from a young one (which was recently dug up) or an old one (which has been in a vegetable store all winter)?

Experience number 7. Extraction of sugar from sugar beets.

Get a small amount of sugar at home.

The purpose of the experiment: to learn how to extract substances from plant materials.

Equipment: large sugar beet, activated carbon, river sand, saucepan, two cans, cotton wool, spoon, funnel, gauze.

Experiment Method:

Cut the beets into small pieces, put them in a saucepan, pour a glass of water into it and boil for 15-20 minutes. Rub the slices of cooked beets thoroughly with a spoon or pestle. Filter this dark mass through a funnel containing cotton wool. Then filter the resulting solution through a funnel prepared in a special way. Put a piece of gauze in it, a thin layer of cotton wool on the gauze, then crushed activated carbon (4-5 tablets) and a thin layer (1 cm) of clean river sand (wash and dry the river sand in advance). The resulting solution (filtrate) is placed in a saucepan. It is necessary to evaporate part of it until transparent crystals appear. This is sugar. Taste it!

Why do you think it is necessary to filter the liquid through a layer of activated carbon?

Experience number 8. Extraction of cottage cheese from milk.

Get a few grams of cottage cheese at home.

The purpose of the experiment: to learn how to make cottage cheese at home.

Equipment: milk, vinegar, saucepan, gauze, gas stove.

Experiment Method:

There is protein in milk. If the milk boils, “runs away” over the edge, then the smell characteristic of burnt protein immediately spreads. The appearance of a characteristic smell of burnt milk indicates that the phenomenon of denaturation has occurred (folding of the protein and its transition to an insoluble form). Protein denaturation is not only due to heat.

Let's do the following experiment. Let's heat up half a glass of milk so that it becomes a little warm, and add vinegar. The milk will immediately curdle, forming large flakes. (If the milk is left in a warm place, then the protein also coagulates, but for a different reason - this is the “work” of lactic acid bacteria). The contents of the saucepan are filtered through cheesecloth, holding it by the edges. If you then connect the edges of the gauze, lift it above the glass and squeeze it out, then a thick mass will remain on it - cottage cheese.

Experience number 9. Getting butter.

Get a small amount of butter at home.

The purpose of the experiment: to learn how to extract butter from milk at home.

Equipment: milk, a glass jar, a small transparent vial with a cork or a tight-fitting lid.

Experiment Method:

Pour fresh milk into a glass jar, put it in the refrigerator. After a few hours, but better the next day, look carefully: what happened to the milk? Explain what you see.

With a small spoon, carefully scoop up the cream (the top layer of milk) and transfer it to a vial. If you need to make butter from cream, you will have to shake it for a long time and patiently for at least half an hour in a vial closed with a lid until an oil lump forms.

Experience number 10. Extraction.

Practice the extraction process.

The purpose of the experiment: to carry out the extraction process in practice.

A) Equipment: sunflower seeds, gasoline, test tube, saucer, mortar and pestle.

Experiment Method:

Grind a few sunflower seeds in a mortar. Transfer the crushed seeds into a test tube, and fill with a small amount of gasoline, shake well several times. Let the test tube stand for two hours (away from the fire), not forgetting to shake it from time to time. Drain the gasoline on a saucer and put it on the balcony. When the gasoline evaporates, there will be some oil left at the bottom that has been dissolved in the gasoline.

B) Equipment: iodine tincture, water, gasoline, test tube.

Experiment Method:

Gasoline can also extract iodine from a pharmacy iodine tincture. To do this, pour a third of water into a test tube, add about 1 ml of iodine tincture and add the same amount of gasoline to the resulting brownish solution. Shake the test tube and leave it alone. When the mixture stratifies, the upper gasoline layer will become dark brown, and the lower, aqueous layer will become almost colorless: after all, iodine does not dissolve well in water, but well in gasoline.

What is extraction? The process of separating a mixture of liquid or solid substances by means of extraction - selective dissolution in certain liquids (extractants) of one or another component of the mixture. Most often, substances are extracted from aqueous solutions with organic solvents, which are usually immiscible with water. The main requirements for extractants are: selectivity (selectivity of action), non-toxicity, possibly low volatility, chemical inertness and low cost. Extraction is used in the chemical industry, oil refining, drug production, and especially widely in non-ferrous metallurgy.

Conclusion.

Work conclusions.

In doing this work, I learned how to prepare heterogeneous and homogeneous mixtures, conducted a study of the properties of substances and found out that when simply compiling a mixture of two components, these substances do not transfer their properties to each other, but keep them to themselves. The properties of the initial components (such as: volatility, state of aggregation, ability to magnetize, solubility in water, particle size, and others) are also based on methods for their separation. When performing educational research, I mastered the following methods for separating heterogeneous mixtures: magnet action, settling, filtering and homogeneous mixtures: evaporation, crystallization, distillation, chromatography, extraction. I was able to isolate pure substances from food products: sugar from sugar beets, starch from potatoes, cottage cheese and butter from milk. I realized that chemistry is a very interesting and informative science, and that the knowledge gained in chemistry classes and after school hours will be very useful to me in life.

The results of the separation of a mixture of iron and sand.

experience #1 #1 #1 #2 #2

substance iron sand mixture part 1 part 2

color gray yellow gray-yellow gray yellow magnet attraction yes no yes yes no

sand are different sand have different properties of both iron and iron sand sand

The results of the separation of dyes on paper.

experiment No. 1 No. 2 substance mixture of dyes before separation mixture of dyes after separation color black dye No. 1 - red dye No. 2 - green conclusion this mixture is homogeneous. the mixture is divided into two starting materials; These are red and green dyes.

Here are the names of various chemical systems. Divide them into: mixtures; pure substances and true solutions.

Distilled water

Sea water
Oxygen
Silver

Sodium chloride solution for injection

Hydrogen
Cast iron
Carbon dioxide
Air

Basalt
Glass

Emulsion "oil in water"
Lead

Suggest methods for separating mixtures: a) water and sand; b) wood and iron filings; c) water and ink; d) water and oil.

Pure substances and mixtures.

In everyday life, each of us is faced with many mixtures of substances, dealing not only with pure, but also with polluted substances. It is important to be able to distinguish between these concepts and be able to determine by specific features what you are dealing with: a pure or contaminated substance, an individual substance or a mixture of substances. After all, a person wants to use only the water that does not contain harmful impurities. We want to breathe air that is not polluted by gases that are harmful to health. In medicine and the production of drugs, the problem of obtaining and using pure substances is especially relevant.

Let's get acquainted with the main terms of the lesson.

Mixture- this is what is formed when two or more substances of different properties are mixed.

The substances that make up a mixture are called components. For example, air is a mixture of gases: nitrogen, oxygen, carbon dioxide and others.

If the mass of one component is tens of times less than the mass of another component of the mixture, then it is called impurity. The substance is said to be contaminated. For example, the air can be polluted with carbon monoxide, a product of the incomplete combustion of organic compounds such as gasoline. By the way, gasoline is a mixture organic matter- hydrocarbons.

CLASSIFICATION OF MIXTURES

Mixtures differ from each other in appearance. For example, salt water (a mixture of table salt and water) and a mixture of river sand and water. In the first case, the solid-liquid interface cannot be seen. Such a mixture is called homogeneous (or homogeneous). Other examples of homogeneous mixtures are vinegar (a mixture of acetic acid and water), air, sugar syrup.

A mixture of river sand and water is referred to as heterogeneous (or heterogeneous) mixtures, because the composition of such a mixture is not the same in different points volume. Mixtures of clay and water, gasoline and water are heterogeneous.

Basically, everything that surrounds us is a mixture of substances. Moreover, there are no substances that are absolutely free of impurities.

But it is customary to talk about the relative purity of a substance, i.e. substances have different degrees of purity.

Degree of purity of a substance

If impurities are not detected when a substance is used for technical purposes, then the substance is called technically clean. For example, the substance from which violet ink is made may contain impurities. But if these impurities do not affect the quality of the ink, then it is technically pure.

If impurities are not detected by chemical reactions, then the substance is classified as chemically pure. For example, it is distilled water.

Signs of the individuality of a substance

A pure substance is sometimes called an individual substance, because it has well-defined properties. For example, only distilled water has a melting point of 0°C, a boiling point of 100°C, and is tasteless and odorless.

Do the properties of substances change in a mixture? To answer this question, let's do a simple experiment. Mix powders of sulfur and iron. We know that iron is attracted to a magnet, but sulfur is not. Did iron retain its property after mixing with sulfur?

CONCLUSION: The properties of substances in a mixture do not change. Knowledge of the properties of the components of a mixture is used to separate mixtures and purify substances.

Methods for separating mixtures and purifying substances

Let us define the difference between "methods for separating mixtures" and "methods for purifying substances." In the first case, it is important to obtain in pure form all the components that make up the mixture. When purifying a substance, obtaining impurities in a pure form is usually neglected.

SETTLEMENT

How to separate a mixture of sand and clay? This is one of the stages in ceramic production (for example, in the production of bricks). To separate such a mixture, the settling method is used. The mixture is placed in water and stirred. Clay and sand settle in water at different rates. Therefore, sand will settle much faster than clay (Fig. 1).

Rice. 1. Separation of a mixture of clay and sand by settling

The settling method is also used to separate mixtures of water-insoluble solids with different densities. For example, a mixture of iron and sawdust can be separated in this way (the sawdust will float in water, while the iron will settle).

A mixture of vegetable oil and water can also be separated by settling, because the oil does not dissolve in water and has a lower density (Fig. 2). Thus, by settling, it is possible to separate mixtures of liquids insoluble in each other with different densities.

Rice. 2. Separation of a mixture of vegetable oil and water by settling

Filtration

To separate a mixture of table salt and river sand, you can use the settling method (when mixed with water, the salt will dissolve, the sand will settle), but it will be more reliable to separate the sand from the salt solution by another method - the filtration method.

Filtration of this mixture can be carried out using a paper filter and a funnel lowered into a glass. Grains of sand remain on the filter paper, and a clear solution of table salt passes through the filter. In this case, the river sand is the sediment, and the salt solution is the leachate (Fig. 3).

Rice. 3. Using filtration method to separate river sand from salt solution

Filtration can be carried out not only with filter paper, but also with other porous or loose materials. For example, bulk materials include quartz sand, and porous materials include glass wool and baked clay.

Some mixtures can be separated using the "hot filtration" method. For example, a mixture of sulfur and iron powders. Iron melts at over 1500 C and sulfur around 120 C. Molten sulfur can be separated from the iron powder using heated glass wool.

Pure substance: what is it

What is a mixture

Chemistry: ways to separate mixtures

Physical methods for separating mixtures

Screening

settling

Filtration

Magnet action

Evaporation

Crystallization

Distillation

Chromatography

Adsorption

ecosystems

Zoology

Biology

Long 19th century

recent history

Middle Ages

new time

Interwar period