#1: When you squeeze an air-filled balloon, what happens inside?

A. There are more collisions of air molecules against the wall of the balloon.

B. There are fewer collisions of air molecules against the wall of the balloon.

C. There is no change in the number of collisions of air molecules against the wall of the balloon.

D. The temperature inside the balloon decreases.

**my answer: A
is that right? not too sure haha @aaronq :)

Answer: "physical change" .

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This would be a "physical change" . ________________________________________________________

Note: This would change from a "solid" to a "liquid" / mere rearrangement of molecules/ NOT a new chemical substance—hence, a "physical change".

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When two substances that cannot dissolve each other are mixed, a mixture is formed. a heterogeneous mixture that has very small dispersed particles and stays mixed for a long time is  a "Colloid"

An example of colloid can be gels, sols, or emulsions; where solids or liquids are dispersed in the mixture. It usually takes very long time to settle down.

A heterogeneous mixture that has larger dispersed particles that settle over time is a "Suspension"

Suspensions are those mixtures which usually has large particles and which takes comparatively less time than colloids to get settled. Like salt water, muddy water, fine sand in water, etc.

Answer:

First one is: heterogeneous

Second one is: colloid

Third one is: suspension

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Explanation:

The trimethylammonium ion (CH3)3NH+ has a total of 25 valence electrons after accounting for its positive charge; 26 electrons from the combined valence electrons of nitrogen, carbon, and hydrogen atoms and subtracting one electron for the positive charge.

To calculate the number of valence electrons in the trimethylammonium ion (CH3)3NH+, we first need to sum the valence electrons of all the atoms. Nitrogen (N) has 5 valence electrons, each hydrogen (H) atom has 1, and each carbon (C) atom has 4. Since there are three methyl groups (CH3), we have 3 carbons and 9 hydrogens:

Adding these up gives 5 + 12 + 9 = 26 valence electrons. However, since we have a positively charged ion (NH+), we need to subtract one electron to account for the charge. This leaves us with a total of 25 valence electrons in the trimethylammonium ion. When drawing the Lewis structure of this polyatomic ion, it is also common practice to enclose the structure in brackets and denote the charge outside of it.

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The trimethylammonium ion, [tex](CH\(_3\))\(_3\)NH\(^+\)[/tex], has 0 valence electrons.

The trimethylammonium ion, [tex](CH\(_3\))\(_3\)NH\(^+\),[/tex]is composed of a nitrogen atom bonded to three methyl groups [tex](CH\(_3\))[/tex] and a hydrogen atom, with an additional positive charge indicating the loss of an electron compared to the neutral molecule.

First, let's consider the valence electrons in the neutral trimethylamine molecule, [tex](CH\(_3\))\(_3\)NH,[/tex] before it gains a positive charge:

Each element has a unique arrangement of electrons, so each element has different spectrum. Therefore, the correct option is option B.

The quantity of protons an element has defines it. An element's atoms all contain the same amount of protons, but its electron and neutron counts might vary. Ions are produced by altering the electron to proton ratio, whereas isotopes are produced by altering the neutron count.

A material that cannot be destroyed chemically is referred to as a chemical element. Although chemical processes cannot modify an atom, nuclear reactions can create new elements. Each element has a unique arrangement of electrons, so each element has different spectrum.

Therefore, the correct option is option B.

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Answer: Option (b) is the correct answer.

Explanation:

When there is no change in chemical composition of a substance  then this change is known as physical change.

Where as when there is change in chemical composition of a substance then it is known as chemical change.

When sugar is heated, it results in the formation of carbon dioxide and water. This means that composition of sugar has changed thus, it is a chemical change.

When solid ice is melted, it turns into liquid. This shows that only state of water has changed. There is no change in chemical composition because when we freeze water then again liquid water changes into solid ice. Thus, it is a physical change.

When sodium reacts with chlorine then the reaction is as follows.

         [tex]2Na + Cl_{2} \rightarrow 2NaCl[/tex]

It shows that chemical composition of sodium has changed due to the formation of sodium chloride. Thus, it is a chemical change.

Also, when aluminium is is heated in air then it results in the formation of aluminium oxide. This means that the chemical composition of aluminium has changed.

Hence, we can conclude that out of the given options, solid ice, when heated, turning into liquid water is an example of a physical change.

Yes, the precipitate of silver carbonate will form.

To determine if a precipitate will form when 65.0 mL of 0.0200 M Ag2SO4 is mixed with 50.0 mL of 0.00500 M K2CO3, we need to compare the ion product (Qsp) with the solubility product constant (Ksp) for silver carbonate (Ag2CO3).

First, let's calculate the concentrations of ions after mixing the solutions:

For Ag2SO4:

- Initial moles of Ag2SO4 = 0.0200 M * 0.0650 L = 0.00130 moles

- Moles of Ag+ ions = 2 * 0.00130 moles = 0.00260 moles

- Concentration of Ag+ ions = 0.00260 moles / (0.0650 L + 0.0500 L) = 0.0200 M

For K2CO3:

- Initial moles of K2CO3 = 0.00500 M * 0.0500 L = 0.000250 moles

- Moles of CO3^2- ions = 0.000250 moles

- Concentration of CO3^2- ions = 0.000250 moles / (0.0650 L + 0.0500 L) = 0.00192 M

Now, to find out if a precipitate will form, we calculate the ion product, Qsp, for silver carbonate:

Qsp = [tex][Ag+]^2 * [CO3^2-][/tex]

Qsp = [tex](0.0200)^2 * (0.00192)[/tex]

Qsp = 7.68 x 10^-6

Compare Qsp with the Ksp of silver carbonate (Ag2CO3):

Ksp = 8.00 x 10^-12

Since Qsp (7.68 x 10^-6) is greater than Ksp (8.00 x 10^-12), the ion product exceeds the solubility product constant. According to the principles of solubility and precipitation, when Qsp > Ksp, a precipitate of silver carbonate (Ag2CO3) will form.

The precipitate of silver carbonate (Ag2CO3) will form when 65.0 mL of 0.0200 M Ag2SO4 is mixed with 50.0 mL of 0.00500 M K2CO3.

5,500 ears if u using usatestprep

When solute concentration exceeds the solubility limit in a solution, a supersaturated solution is created, which subsequently initiates precipitation in order to achieve equilibrium. This results in the formation of a new solid phase that is distinct from the original solution.

The concept you're referring to involves solubility and the formation of new phases when the concentration of a solute in a solution exceeds its solubility limit. Solubility refers to the maximum amount of solute that can be dissolved in a solvent at a given temperature. When this limit is surpassed, a supersaturated solution is formed. This is not a stable state, and it often results in precipitation. This is the process where a solute becomes insoluble and forms a new, separate solid phase.

For instance, if we take a saturated solution of silver chloride (AgCl), and add more AgCl to it, the excess will precipitate out of solution. Here, the concentration of AgCl has exceeded its solubility, leading to the formation of a new solid phase that is distinct from the original solution.

The exact composition and form of the new solid phase can depend on a variety of factors, including the type of solvent and solute involved, temperature, and pressure.

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Final answer:

To calculate the mass of 0.446 mol Na₂CO₃, multiply the number of moles by its molar mass of 105.98 g/mol, resulting in 47.27 grams of Na₂CO₃.

Explanation:

To find out how many grams 0.446 mol of Na₂CO₃ corresponds to, we can use the molar mass of Na₂CO₃.

First, we should recall the molar mass of Na₂CO₃. Using the atomic masses Na (22.99), C (12.00), and O (16.00), the molar mass would be:

(2 × 22.99) + 12.00 + (3 × 16.00) = 105.98 g/mol

Now, we can calculate the mass of 0.446 mol of Na₂CO₃:

0.446 mol Na₂CO₃ × 105.98 g/mol = 47.27 grams

The amount of carbon that could be recovered from 769g of a substance that is 35.7% carbon by mass is approximately 275g.

The question involves a percentage by mass calculation, which falls under the subject of Chemistry. The substance in question is 35.7% carbon by mass. Therefore, to find the amount of carbon in a 769g sample, we multiply the total mass of the substance by the percentage of carbon.

Here's the calculation: 769g (total mass) x 0.357 (percentage of carbon as a decimal) = 274.653g. Therefore, we can recover approximately 275g (if we round to the nearest whole number) of carbon from the 769 g of the substance.

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To find how much carbon is in 769 g of a substance that is 35.7% carbon by mass, multiply 769 g by 0.357. This calculation shows that 274.833 g of carbon can be recovered.

To determine this, we can use the percentage by mass to find the amount of carbon in the total mass of the substance. Here's the step-by-step calculation:

First, convert the percentage into a decimal: 35.7% = 0.357

Amount of carbon = mass of the substance × percentage of carbon (in decimal form)

Amount of carbon = 769g × 0.357

Amount of carbon = 274.553g

Therefore, you could recover approximately 274.553 grams of carbon from 769 grams of the substance.

Answer: 1. 8 electrons

2. 7 electrons

Explanation: energy shell are orbits which Carry's electrons around an atom's nucleus.

To determine the number of electrons in an energy shell, use the formula

2(n^2)

n= number of energy shell

Therefore the second energy shell is n=2

Substituting n in the equation above,

2(2^2)=8

2. Valence electrons are the electrons on the outermost shell of an atomic nucleus.

The group number of an element is the same as the valence electrons of that element.

Therefore chlorine which belongs to group 7 elements has 7 valence electron.

We can also get the valence electrons using the K L M N shell.

The K shell which has maximum of 2 electrons, while other shells can contain maximum of 8 electron.

SEE PICTURE ATTACHED TO UNDERSTAND THE K L M N SHELL BETTER.

The words 'matter', 'accuracy', 'precision', 'meniscus', 'volume', and 'density' have been linked with their suitable definitions, clarifying their individual meanings.

Here are the words matched to their definitions:

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A. The mass of CO₂ produced is 176 g.

B. The mass of H₂O produced is 36 g

We'll begin by calculating the mass of C₂H₂ that reacted and the masses of CO₂ and H₂O produced from the balanced equation.

2C₂H₂ + 5O₂ —> 4CO₂ + 2H₂O

Molar mass of C₂H₂ = (2×12) + (2×1) = 26 g/mol

Mass of C₂H₂ from the balanced equation = 2 × 26 = 52 g

Molar mass of CO₂ = 12 + (16×2) = 44 g/mol.

Mass of CO₂ from the balanced equation = 4 × 44 = 176 g

Molar mass of H₂O = (2×1) + 16 = 18 g/mol

Mass of H₂O from the balanced equation = 2 × 18 = 36 g

SUMMARY:

From the balanced equation above,

52 g of C₂H₂ reacted to produce 176 g of CO₂ and 36 g of H₂O.

From the above, we can see that 52 g of C₂H₂ produced:

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Answer: According to continental drift, the continents were once connected

Explanation:

According to continental drift, the continents were once connected this statement is true.

Pangaea split into fragments over the course of millions of years, and each piece migrated away from the other. These components gradually came together to form the continent that is known today.

Today's scientists believe that a number of supercontinents, including Pangaea, have developed and fragmented during the Earth's history.

The theory of continental drift holds that Earth's continents have shifted relative to one another during geologic time, giving the impression that they have "drifted" over the ocean floor.

During one or more geologic periods, continents moved horizontally at a huge scale in relation to one another and to the ocean basins. This idea served as a crucial building block for the theory of plate tectonics, which includes it.

Thus, option C is correct.

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