All categories

4 years ago

Select all that apply to colloids.

2 answers:

8 0

The following applied to colloids:
1. They can not be separated by filtration. This is because colloids are uniform and homogeneous in nature. They do not produce sediments when left standing.
2. Colloids can be be seen using optical microscope. This is because, the diameter of the dispersed particles range from 1 to 1000 nanometer. This size range can easily be seen under optical microscope.
3. Fog and smoke are example of colloids. Smoke is a type of colloid in which solid is dispersed in gas while in fog, liquid is dispersed in gas.
4. The Tyndall effect is a test that determine whether or not a mixture is a colloid. Light is dispersed by colloidal particles.

Scilla [17]4 years ago

6 0

Answer: All the points apply for colloids.

Explanation: This question can be answered only by looking at the properties of colloids:

The particle size of these systems range from 1nm to 1mm.
These are generally considered as heterogeneous mixtures but have some properties of homogeneous mixtures. There is some physical boundary present between solute and solvent.
These solutions cannot be separated by ordinary filtration.
Tyndall effect: This effect is generally seen in colloidal solutions or solutions having very fine suspension. This effect is basically the scattering of light by the particles. This effect can be seen in the sky when sunlight is scattered by clouds.
These solutions have small particle size thus it cannot be seen from bare eyes, thus we need optical microscope.
Cloud, Milk, Fog and Smoke are some of the examples of Colloidal solutions.

These properties enlisted above show that all the points given in the question are correct for colloidal solutions.

You might be interested in

35. Ethan-1,1-diol has two-OH groups attached to one of its carbons. Draw out this molecule

aleksklad [387]

Answer: structure of Ethane- 1,1- diol is in pic

Explanation:

8 0

3 years ago

What are the roles of producers,consumers, and decomposers in an ecosystem?

scoundrel [369]

The producers of an ecosystem make energy available to all the other living parts of an ecosystems. Consumers like humans eat the food that producers like plants made decomposers decompose dead plants and animals when they die like bacteria is a decomposer

5 0

3 years ago

Read 2 more answers

You are on the Titanic and want to find something that will float because you didn't

damaskus [11]

Find volume of pillow

L=78cm

B=55cm

H=25cm

$\\ \bull\tt\longrightarrow V=LBH$

$\\ \bull\tt\longrightarrow V=25(78)(55)$

$\\ \bull\tt\longrightarrow V=107250cm^3$

$\\ \bull\tt\longrightarrow V=10.72m^3$

Now

Mass=5.5kg

$\\ \bull\tt\longrightarrow Density=\dfrac{Mass}{Volume}$

$\\ \bull\tt\longrightarrow Density=\dfrac{5.5}{10.72}$

$\\ \bull\tt\longrightarrow Density=0.5kg/m^3$

Density of water=1000kg/m^3

As it is less than density of water it will float on water

8 0

3 years ago

What are the boiling points and freezing points (in oC) of a solution of 50.3 g of I2 in 350 g of chloroform? The kb = 3.63 oC/m

patriot [66]

Answer:

Boiling point: 63.3°C

Freezing point: -66.2°C.

Explanation:

The boiling point of a solution increases regard to boiling point of the pure solvent. In the same way, freezing point decreases regard to pure solvent. The equations are:

Boiling point increasing:

ΔT = kb*m*i

Freezing point depression:

ΔT = kf*m*i

ΔT are the °C that change boiling or freezing point.

m is molality of the solution (moles / kg)

And i is Van't Hoff factor (1 for I₂ in chloroform)

Molality of 50.3g of I₂ in 350g of chloroform is:

50.3g * (1mol / 253.8g) = 0.198 moles in 350g = 0.350kg:

0.198 moles / 0.350kg = 0.566m

Replacing:

Boiling point:

ΔT = kb*m*i

ΔT = 3.63°C/m*0.566m*1

ΔT = 2.1°C

As boiling point of pure substance is 61.2°C, boiling point of the solution is:

61.2°C + 2.1°C = 63.3°C

Freezing point:

ΔT = kf*m*i

ΔT = 4.70°C/m*0.566m*1

ΔT = 2.7°C

As freezing point is -63.5°C, the freezing point of the solution is:

-63.5°C - 2.7°C = -66.2°C

7 0

3 years ago

In a reaction, 25 grams of reactant

Vsevolod [243]

Answer:

D. 15g

Explanation:

The law of conservation of mass states that, in a chemical reaction, mass can neither be created nor destroyed. This means that the amount of matter in the elements of the reactants must be equal to the amount in the resulting products.

In this question, 25 grams of a reactant AB, was broken down in a reaction to produce 10 grams of products A and X grams of product B. According to the law of conservation of mass, the mass of the reactant must be equal to the total mass of the products. This means that 25 grams must also be the total mass of both products in this reaction. Hence, if product A is 10 grams, product B will be 25 grams - 10 grams = 15 grams.

Therefore, product B must be 15 grams in order to form a total of 25 grams when added to the mass of product A. This will equate the mass of the reactant AB and fulfill the law of conservation of mass.

8 0

4 years ago