Dead space is the portion of the respiratory system that: Select one: A.. must be filled with air before gas exchange can take place. B. contains no alveoli and does not participate in gas exchange. C. includes the alveoli and capillaries surrounding the alveoli. D. receives oxygen but is unable to release carbon dioxide.

Answer:

Binary molecular compounds are the compounds consisting of two non-metallic elements. Examples of binary molecular compounds include: NO2, HCl, HF, P2O5 e.t.c.

Rules For Naming Binary Molecular Compounds

Naming binary molecular compounds is quite easy,

1. The first element is given its name.

2. The second element is given its root name (such as, hydro, carb,ox, chlor e.t.c.) followed by suffix ide.

Name of N2O4 - Dinitrogen tetraoxide

Chemical Formula of;

 iodic acid: HI

disulfur trioxide: S2O3

dinitrogen monoxide: N2O

hydrofluoric acid: HF

Difference between Binary acid and an oxyacid

An oxyacid is an acid consisting of an oxygen atom bonded to a hydrogen atom and at least one other non-metallic element. Examples of oxyacids include HNO3, H2SO4 e.t.c.

Binary acids are the acids consisting of hydrogen atom bonded to a non-metallic element. Examples include HF, HCl, HI  e.t.c.

Answer:

Explanation:Rrules for naming binary compounds.

1. The less electronegative element is written first.This is not always true for all elements.Nonmetals follow this order:C,p,N,H,S,I,Br,Cl,O,F.

2.The right numeric prefix is used example mono for 1 atom,did for 2 atoms,tri for 3 atoms,tetra for 4 atoms.etc

3. The second element is named after the first with the ending of the element's name changed to-ide then the right prefix is used for the second element.

4.Drop the 'a' in a prefix ending in one prior to the one starting with the vowel'o'. Example write tetroxide instead of tetra oxide.

32. A binary compound is a compound that contains two non metals.

33. A binary acid is a compound that contains a hydrogen atom that is bonded to a non metal in its molecule.They are called hydracids.The general formular is H-X.Examples are HCl,H2S, etcwhile oxyacid are compounds that are composed of hydrogen,oxygen and other elements in the molecule. An eample is HClO3.

34. N2O3 will be named dintrogentetroxide.This is because it is a covalent compound and will follow rule 2 by putting the right numeric prefix based on the number of atoms of nitrogen and oxygen in the molecule.The 'a"at the end of tetra dropped because of the vowel 'o'in the next letter.

35. a. Molecular formulae of iodic acid is HIO3

b.Molecular formulae for disulfurtrioxide is

S2O3

c.Molecular formulae for dinirtrogenmonoxide is N2O

d. Hydrogenchloric ice HCl

36. Answer 35

Answer:

The equation in function notation is:

= [tex]f(q)=\frac{1}{2}s-\frac{3}{2}[/tex]

Explanation:

Given equation:

[tex]6q = 3s-9[/tex]

Where q is the independent variable.

To write the equation in function notation we will do the following:

Step 1 : divide 6 on both sides:

[tex]\frac{6q}{6}=\frac{3s-9}{6}[/tex]

[tex]q=\frac{1}{2}s-\frac{3}{2}[/tex]

The function notation will become:

[tex]f(q)=\frac{1}{2}s-\frac{3}{2}[/tex]

Answer:

D. f(q)=2q+3

Explanation:

The answer should be D. f(q)=2q+3

If you need a explannation, comments below and I will edit the explannation  

Answer: 2 lone pairs

Explanation: this is clearly a water molecule in which two hydrogen atom is bonded to one oxygen atom.

Please see attachment for explanation

The molecule with a central atom and two bonded atoms is bent with a bond angle of 105°. It has two lone pairs of electrons on the central atom.

The molecule with a central atom and two bonded atoms is bent with a bond angle of 105°. When a central atom has two bonded atoms and a bond angle less than the typical angle for that geometry, it indicates the presence of one or more lone pairs of electrons on the central atom. In this case, since the molecule is bent, it suggests the presence of two lone pairs of electrons on the central atom. The central atom satisfies the octet rule, which requires it to have 8 valence electrons, made up of both shared and unshared electrons.

Answer:

5.21 g of solute (LiCl)

48.79 g of solvent (water)

Explanation:

This is our information

[LiCl] = 2.40 M → 2.40 moles of salt in 1L of solution

Density of solution: 1.0538 g/mL (solution mass / solution volume)

54 g → solution mass

Let's determine solution volume with density

1.0538 g/mL = solution mass / solution volume

1.0538 g/mL = 54 g / solution volume

Solution volume = 54 g / 1.0538 g/mL → 51.2 mL

Now, we can know the mass of solute, by molarity.

In 1 L of solution (1000 mL) we know that we have 2.40 mol of chloride.

Then, how many moles of chloride, do we have in 51.2mL of solution. We make a rule of three:

1000 mL has 2.40 moles of LiCl

51.2 mL would have (51.2 . 2.40)/1000 = 0.123 moles of solute

We apply molar mass to know the mass ( mol . molar mass)

0.123 moles .  42.39 g/m = 5.21 g of LiCl

Finally solute mass + solvent mass = solution mass

5.21 g LiCl + solvent mass = 54 g

54 g - 5.21 g = solvent mass → 48.79 g

The mass of solute is 5.22 g and the mass of solvent is 48.78 g

Molarity of LiCl = 2.40 M

Therefore, 2.40 moles of salt is present in 1L of solution

Density of solution: 1.0538 g/mL

Mass of solution = 54.0 g

Volume = 54 g / 1.0538 g/mL

Volume of solution = 51.2 mL

1 L or 1000 mL solution contains 2.40 moles

51.2 mL will contain 51.2 * 2.4 mole/1000

Number of moles of LiCl present in 51.2 mL solution = 0.123 moles

Using mass = number of moles * molar mass  

molar mass of LiCl = 42.5 g

mass of LiCl = 0.123 * 42.5 g

mass of LiCl = 5.22 g of LiCl

mass of solvent = solution mass - mass of solute

mass of solvent = 54.0 g - 5.22 g

mass of solvent = 48.78

5.21 g LiCl + solvent mass = 54 g

Therefore, the mass of solute is 5.22 g and the mass of solvent is 48.78 g

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Answer:

The amount of Cl2 gas left , after the reaction goes to completion is : 139.655 grams

Explanation:

Molar mass : It is the mass in grams present in one mole of the substance.

Moles of the substance is calculated by:

[tex]Moles=\frac{Mass}{Molar\ mass}[/tex]

[tex]2Al(s)+3Cl_{2}(g)\leftarrow 2AlCl_{3}(g)[/tex]

According  to this equation:

2 mole of Al = 3 mole of Cl2 = 2 mole of AlCl3

Molar mass of Al = 27.0 g/mol

Mass of Al = 20.1 gram

Moles of Al present in the reaction :

[tex]Moles=\frac{Mass}{Molar\ mass}[/tex]

[tex]Moles=\frac{20.1}{26.98}[/tex]

Moles of Al = 0.744

Similarly calculate the moles of Cl2

Molar mass of Cl2 = 71.0 g/mol

Mass = 219 gram

[tex]Moles=\frac{Mass}{Molar\ mass}[/tex]

[tex]Moles=\frac{219}{70.98}[/tex]

Moles of Cl2 = 3.08 moles

According to equation,

2 mole of Al reacts with = 3 mole of Cl2

1 moles of Al reacts with = 3/2  mole of Cl2

0.744 moles of Al reacts with = 3/2(0.744) moles of Cl2

= 1.116 moles of Cl2

But actually present Cl2 = 3.08 moles

Hence Al is the limiting reagent , and Cl2 is the excess reagent.

The whole Aluminium Al get consumed during the reaction.

The amount of Cl2 in excess = Total Cl2 - Cl2 consumed

Cl2 in excess = 3.08 - 1.116 = 1.964 moles

Cl2 in grams = 1.964 x 70.90 = 139.655 grams

Answer:

A reducing agent is an element or compound that loses (or "donates") an electron to an electron recipient (oxidizing agent) in a redox chemical reaction.

Explanation:

Redox reaction is defined as the reaction in which oxidation and reduction reaction occur simultaneously.

Oxidation reaction is defined as the chemical reaction in which an atom looses its electrons. The oxidation number of the atom gets increased during this reaction.

[tex]X\rightarrow X^{n+}+ne^-[/tex]

Reduction reaction is defined as the chemical reaction in which an atom gains electrons. The oxidation number of the atom gets reduced during this reaction.

[tex]X^{n+}+ne^-\rightarrow X[/tex]

Electrons are transferred from one atom to another in this type of reaction.

Reducing agent is defined as those substance which reduces other chemical compound and oxidizes itself by donating electrons.

Oxidizing agent is defined as those substance which oxidizes other chemical compound and reduces itself by accepting electrons.

Answer:

A reducing agent

Explanation:

A reducing agent--(also called a reductant or reducer) is an element or compound that loses (or "donates") an electron to an electron recipient (oxidizing agent) in a redox chemical reaction.

A reducing agent thus oxides( loses an electron) itself to electron acceptor. This mean that oxidation and reduction occur in pair. One element is oxidized and the other is reduced.

Answer:

27oz

Explanation:

Let the volume quantity of the 10% solution = x

The volume quantity of the 15% alcohol solution is known as = 18oz

Therefore the volume of the 12% product = 18oz + x

Therefore

0.10 × x + 0.15 × 18oz = 0.12 × (18oz+x)

0.15×18oz - 0.12×18oz = 0.12×x - 0.10×x

.

0.03*18oz = 0.02x

Dividing both sides by 0.02

x = 27oz

Verifying the answer, we have

0.1 × 27 + 18 × 0.15 = 0.12 × 45

2.7 + 2.7 = 5.4

Answer:

We have 1.15 *10^23 nitrogen atoms

Explanation:

Step 1: Data given

Mass of N2O = 4.19 grams

Number of N2O molecules = 5.73 *10^22 molecules

Molar mass = 44.01 g/mol

Step 2: Calculate moles N2O

Moles N2O = mass N2O / molar mass N2O

Moles N2O = 4.19 grams / 44.01 g/mol

Moles N2O = 0.0952 moles

Step 3: Calculate moles nitrogen

For each mol N2O we have 2 moles of Nitrogen

For 0.0952 moles N2O we have 2*0.0952 = 0.1904 moles nitrogen

Step 4: Calculate atoms nitrogen

Number of nitrogen atoms = moles * number of Avogadro

Number of nitrogen atoms = 0.1904 moles * 6.022*10^23

Number of nitrogen atoms = 1.15 *10^23 atoms

We have 1.15 *10^23 nitrogen atoms

For every molecule of Nitrous Oxide, there are two nitrogen atoms. Multiplying the given number of N2O molecules (5.73 x 10^22) by two gives us the total number of nitrogen atoms in the sample, which is approximately 1.146 × 10^23 nitrogen atoms.

To calculate the number of nitrogen atoms in a sample of nitrous oxide (N2O), we must first understand the molecular structure of N2O. This molecule consists of two nitrogen atoms bonded to one oxygen atom. Thus, for every one molecule of N2O, there are two nitrogen atoms.

The question stated that the sample contained 5.73 × 1022 N2O molecules. By multiplying this number by two (for the two nitrogen atoms per molecule), the total number of nitrogen atoms in the sample can be calculated.

Therefore, 5.73 × 1022 N2O molecules * 2 N atoms per molecule = 1.146 × 1023 nitrogen atoms.

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Answer:

The answer to your question is below

Explanation:

Reaction

                            C₂H₂ (g) + O₂(g)   ⇒   CO₂ (g)   +  H₂O (g)

                            Reactants         Elements         Reactants

                                    2                       C                       1

                                    2                       H                       2

                                    2                       O                       3

This reaction is unbalance

Reaction balanced

                          2C₂H₂ (g) +   5O₂(g)   ⇒   4CO₂ (g)   +  2H₂O (g)

                            Reactants         Elements         Reactants

                                    4                       C                       4

                                    4                       H                       4

                                   10                       O                      10

Now, the reaction is balanced

a) Calculate the molecular mass of acetylene and water

Acetylene = (12 x 2) + (2) = 26 g

Water = (1 x 2) + (1 x 16) = 18 g

                           2(26) g of Acetylene ---------------  2(18) g of Water

                               113 g  of Acetylene --------------   x

                                x = (113 x (2 x 18)) / 2(26)

                                x = 4068 / 52

                               x = 78. 2 g of water

b)                2 moles of Acetylene ------------  4 moles of carbon dioxide

                   x moles of acetylene ------------  1.10 moles of carbon dioxide

                         x = (1.10 x 2) / 4

                        x = 0.55 moles of acetylene

Answer:

a) 78.19 grams H2O

b) 14.3 grams acetylene

Explanation:

Step 1: Data given

Molar mass of acetylene = 26.04 g/mol

Molar mass of H2O = 18.02 g/mol

Step 2: The balanced equation

2C2H2 + 5O2 → 4CO2 + 2H2O

Step 3: a. How many grams of water can form if 113g of acetylene is burned?

Calculate moles of acetylene:

Moles = mass / molar mass

Moles = 113.0 grams / 26.04 g/mol

Moles = 4.339 moles

calculate moles of H2O

For 2 moles acetylene we need 5 moles O2 to produce 4 moles CO2 and 2 moles H2O

For 4.339 moles of acetylene we'll have 4.339 moles H2O

Calculate mass of H2O

Mass H2O = 4.339 moles * 18.02 g/mol

Mass H2O = 78.19 grams H2O

b. How many grams of acetylene react if 1.10 mol of CO2 are produced?

For 2 moles acetylene we need 5 moles O2 to produce 4 moles CO2 and 2 moles H2O

For 1.10 mol CO2 we need 1.10/2 = 0.55 moles of acetylene

Mass acetylene = 0.55 moles * 26.04 g/mol

Mass acetylene = 14.3 grams acetylene

Answer:

508 cm^3

Explanation:

3.99 kg * (1000 g)/(1 kg) = 3990 g

density = mass/volume

density * volume = mass

volume = mass/density

volume = (3990 g)/(7.86 g/cm^3)

volume = 508 cm^3

By following the stoichiometry of the balanced chemical equation for combustion of acetylene, it is calculated that 113 g of acetylene will produce 78.20 g of water, and 14.32 g of acetylene are required to produce 1.10 mol of CO₂.

Combustion of Acetylene

The balanced chemical equation for the combustion of acetylene (C2H2) is:

2C₂H₂(g) + 5O₂(g)⇒ 4CO₂(g) + 2H₂O(g)

Part A: Grams of Water Formed

Step 1: Calculate the moles of C2H2 using its molar mass (26.04 g/mol).

Moles ofC₂H₂ = 113 g / 26.04 g/mol = 4.34 mol

Step 2: From the balanced equation, 1 mol of C2H2 produces 1 mol of H2O. Therefore, 4.34 mol of C2H2 will produce 4.34 mol of H2O.

Step 3: Convert moles of H2O to grams using its molar mass (18.02 g/mol).

Grams of H2O = 4.34 mol x 18.02 g/mol = 78.20 g

113 g ofC₂H₂ will produce 78.20 g of water.

Part B: Grams of Acetylene Reacted

Step 1: From the balanced equation, 2 mol of C₂H₂ produce 4 mol of CO₂. So, 1 mol ofCO₂ is produced by 0.5 mol of  C₂H₂.

Step 2: Calculate the moles of C₂H₂ needed to produce 1.10 mol ofCO₂.

Moles of C₂H₂ = 1.10 molCO₂ x 0.5 mol  C₂H₂/mol CO₂ = 0.55 mol C₂H₂

Step 3: Convert moles of C₂H₂  to grams using its molar mass (26.04 g/mol).

Grams of C₂H₂ = 0.55 mol x 26.04 g/mol = 14.32 g

14.32 g of C₂H₂ react to produce 1.10 mol of CO₂.

The given question is incomplete. The complete question is as follows.

The value of Henry's law constant [tex]k_{H}[/tex] for oxygen in water at [tex]25^{o}C[/tex] is [tex]1.66 \times 10^{-6}[/tex] M/torr.

Calculate the solubility of oxygen in water at [tex]25^{o}C[/tex] when the total external pressure is 1 atm and the mole fraction of oxygen in the air is 0.20 atm.

Explanation:

Formula to calculate partial pressure of a gas is as follows.

   Partial pressure of oxygen = mole fraction of oxygen x total pressure

Putting the given values into the above equation as follows.

       = [tex]0.20 \times 760[/tex] = 152 torr

Therefore, solubilty (concentration) of oxygen in water  will be calculated as follows.

        Solubility = Henry's law constant x partial pressure of oxygen

                       = [tex]1.66 \times 10^{-6} M/torr \times 152 torr[/tex]

                       = [tex]2.52 \times 10^{-4}[/tex] M

Thus, we can conclude that solubility of given oxygen is [tex]2.52 \times 10^{-4}[/tex] M.

The solubility of oxygen in water at 25°C, when the total external pressure is 1 atm and the mole fraction of oxygen in the air is 0.2, is approximately [tex]\( 0.000260 \, \text{mol/L} \)[/tex].

The solubility of oxygen in water at 25°C, when the total external pressure is 1 atm and the mole fraction of oxygen in the air is 0.2, can be calculated using Henry's Law. Henry's Law states that the solubility of a gas in a liquid is directly proportional to the partial pressure of the gas above the liquid. The relationship can be expressed as:

[tex]\[ C = k \cdot p \][/tex]

where:

- C  is the concentration of the gas in the liquid (solubility of oxygen in water, in this case),

- k  is the Henry's Law constant for oxygen in water at the given temperature,

-  p is the partial pressure of oxygen above the liquid.

Given that the total external pressure is 1 atm and the mole fraction of oxygen is 0.2, the partial pressure of oxygen [tex](\( p_{O_2} \))[/tex] can be calculated as:

[tex]\[ p_{O_2} = \text{total pressure} \times \text{mole fraction of oxygen} \] \[ p_{O_2} = 1 \, \text{atm} \times 0.2 \] \[ p_{O_2} = 0.2 \, \text{atm} \][/tex]

The Henry's Law constant for oxygen in water at 25°C [tex](\( k_{O_2} \)) is approximately \( 769.23 \, \text{L} \cdot \text{atm/mol} \).[/tex]

Now, we can calculate the solubility of oxygen in water:

[tex]\[ C_{O_2} = k_{O_2} \cdot p_{O_2} \]\[ C_{O_2} = 769.23 \, \text{L} \cdot \text{atm/mol} \times 0.2 \, \text{atm} \] \[ C_{O_2} = 153.846 \, \text{L} \cdot \text{atm/mol} \][/tex]

To express the solubility in terms of molarity (mol/L), we divide the partial pressure by the Henry's Law constant:

[tex]\[ C_{O_2} = \frac{p_{O_2}}{k_{O_2}} \]\[ C_{O_2} = \frac{0.2 \, \text{atm}}{769.23 \, \text{L} \cdot \text{atm/mol}} \]\[ C_{O_2} \approx 0.000260 \, \text{mol/L} \][/tex]

The answer is: [tex]0.000260 \, \text{mol/L}.[/tex]

A homogeneous mixture, also known as a solution, is a combination of substances that is uniform throughout. In the given options, the glass of soda is an example of a homogeneous mixture due to its uniform composition, which differs from a heterogeneous mixture where the composition can vary.

In order to identify a homogeneous mixture, we need to understand what it is. A homogeneous mixture is also known as a solution and it's a combination of substances with a composition that is uniform throughout. Each sample of a homogeneous mixture will show the same proportions of its components. This differs from a heterogeneous mixture, where the composition can vary from point to point. Examples of these would be cookies or salad dressing where the individual components can be visibly distinguished. From the list you provided, the glass of soda represents a homogeneous mixture. This is due to its uniform composition, you cannot tell the difference between one part of the soda from the others because the solute (usually a syrup) is completely dissolved in the solvent (carbonated water). Therefore, every part of the soda sample is identical in properties and composition.

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Answer:

B) The metal temperature changed more than the water temperature did, but the metal lost

the same amount of thermal energy as the water gained.

Explanation:

Heat capacity or thermal capacity is defined as the amount of heat required by a given mass of a material to raise its temperature by one unit which means that the heat capacity of the water, that is the quantity of heat required to cause a rise from 22°C to 35°C that is a rise of 13°C is the quantity of heat that caused the drop in temperature of the metal from 100°C to 35°C a change of 65°C

The water has more capacity to absorb heat or a higher heat capacity than the metal

However, the first law of thermodynamics states that energy is neither created nor destroyed, but it changes from one form to another. In this case, the thermal energy lost by the metal is the same as the thermal or heat energy gained by the water

The branch of science which deals with chemicals and bonds is called chemistry.

The correct answer is B

Heat capacity or thermal capacity is defined as the amount of heat required by a given mass of a material to raise its temperature by one unit which means that the heat capacity of the water

The quantity of heat required to cause a rise from 22°C to 35°C that is a rise of 13°C is the quantity of heat that caused the drop in temperature of the metal from 100°C to 35°C a change of 65°C

The water has more capacity to absorb heat or a higher heat capacity than the metal because the water has more space in between the particles.

However, the first law of thermodynamics states that energy is neither created nor destroyed, but it can transform from one material to another material. The heat always flows from the high temperature to the low temperature.

Hence, the correct option is B that is The metal temperature changed more than the water temperature did, but the metal lost the same amount of thermal energy as the water gained.

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Answer:

Hi

One of the most famous works George Orwell shows us in 1984 a society that is controlled by the Superstate, in such a way that the inhabitants cannot do or say anything without The Big Brother finding out. If anyone tries to oppose this system, it is vaporized and in less than three days society forgets that there was a person who conspired or worse, that existed.

The detentions happened at night. He woke up startled because one hand shook one shoulder, a flashlight focused on him and a circle of grim faces appeared around the bed. In most cases there was no process. People disappeared and always during the night. The name of the individual in question disappeared from all the records, any reference to what he had done was erased from everywhere and his passage through life was completely annulled as if he had never existed.

Explanation:

Answer:

4 for C in CH4

+4 for C in CO2

-2 for O in all substances

+1 for H in both CH4 and H2O

option 1,2,3 and 4 are correct. Option 5 is not correct

Explanation:

Step 1: Data given

Oxidation number of H = +1

Oxidation number of O = -2

Step 2: The balanced equation

CH4(g) + 2O2(g) → CO2(g) + 2H2O(g)

Step 3: The oxidation numbers

-4 for C in CH4

 ⇒ Oxidation number of H = +1

    ⇒ 4x +1 = +4

C has an oxidation number of -4

This is correct.

+4 for C in CO2

 ⇒ Oxidation number of O = -2

    ⇒ 2x -2 = -4

C has an oxidation number of +4

This is correct.

-2 for O in all substances

⇒ this is correct, the oxidation number of O is always -2 (except in H2O2 and Na2O2)

This is correct.

+1 for H in both CH4 and H2O

⇒ this is correct, the oxidation number of H is always +1 (except in metal hydrides).

This is correct.

+4 for O in H2O

 ⇒ Oxidation number of H = +1

    ⇒ 2x +1 = +2

The oxidation number of O is -2

This is not correct

Final answer:

The correct statements regarding oxidation states in the methane combustion reaction are 4 for C in CH4

+4 for C in CO2

-2 for O in all substances

+1 for H in both CH4 and H2O

Explanation:

The student's question relates to the oxidation states of elements in a chemical reaction, specifically in the combustion of methane represented by the equation CH4 + 2O2 → CO2 + 2H2O. Let's evaluate the statements:

Step 1: Data given

Oxidation number of H = +1

Oxidation number of O = -2

Step 2: The balanced equation

CH4(g) + 2O2(g) → CO2(g) + 2H2O(g)

Step 3: The oxidation numbers

-4 for C in CH4

⇒ Oxidation number of H = +1

   ⇒ 4x +1 = +4

C has an oxidation number of -4

This is correct.

+4 for C in CO2

⇒ Oxidation number of O = -2

   ⇒ 2x -2 = -4

C has an oxidation number of +4

This is correct.

-2 for O in all substances

⇒ this is correct, the oxidation number of O is always -2 (except in H2O2 and Na2O2)

This is correct.

+1 for H in both CH4 and H2O

⇒ this is correct, the oxidation number of H is always +1 (except in metal hydrides).

This is correct.

+4 for O in H2O

⇒ Oxidation number of H = +1

   ⇒ 2x +1 = +2

The oxidation number of O is -2

This is not correct

To solve this problem, we first need to determine the limiting reagent, which is the chemical that is completely used up in the reaction and thus dictates the amount of the product that can be formed. This is achieved by calculating the moles of the product, Ca3(PO4)2, that each reagent can potentially produce, and then choosing the smaller value.

We have 3.40 moles of Ca(NO3)2 and from the balanced reaction equation, we see that 3 moles of Ca(NO3)2 react to produce 1 mole of Ca3(PO4)2. Therefore, we can calculate the amount of Ca3(PO4)2 that can theoretically be produced by Ca(NO3)2:

3.40 moles / 3 = 1.133 moles of Ca3(PO4)2

Similarly, we have 2.40 moles of Li3PO4, and 2 moles of Li3PO4 produce 1 mole of Ca3(PO4)2. Therefore, the theoretical yield of Ca3(PO4)2 from Li3PO4 is:

2.40 moles / 2 = 1.20 moles of Ca3(PO4)2

Since the amount of Ca3(PO4)2 that can be produced from Ca(NO3)2 (1.133 moles) is less than the amount that could be produced from Li3PO4 (1.2 moles), Ca(NO3)2 is the limiting reagent. Therefore, the actual yield of Ca3(PO4)2 will be the smaller value, that is 1.133 moles.

Next, we convert the moles of Ca3(PO4)2 to grams. The molar mass of Ca3(PO4)2 is 310.18 g/mol. We use the conversion factor of molar mass to convert moles to grams:

1.133 moles * 310.18 g/mol = 351.54 g

Therefore, theoretically, 351.54 grams of calcium phosphate can be formed from starting with 3.40 moles of Ca(NO3)2 and 2.40 moles of Li3PO4.

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Answer:

-732.5 5 Joules

Explanation:

This a typical calorimetry problem  that can be solved with the formula:

Q = m . C . ΔT

First of all, we determine the mass of water, by density.

Density is mass /volume

1 g/mL = mass / 6.76 mL → 6.76 g

Q = 6.76 g . 4.184 J/g°C . (13.6°C - 39.5°C)

Q = -732.5 5 Joules

Water is releasing heat to be cooled, that's why the answer is negative.

Question: Atoms of iron (Fe) form metallic bonds with other iron atoms. How are the valence electrons of these atoms rearranged to form the bonds?

A) a few valence electrons are shared between the atoms.

B) many valence electrons are shared between the atoms.

C) electrons are transferred from the iron atoms to atoms in the air.

D) electrons are transferred to the iron atoms from atoms in the air

Answer:

"Many valence electrons are shared between the atoms"

Explanation:

Chemical bonds can be broadly classified into 3 categories:

1) Ionic bond

2) Covalent Bond

3) Metallic bond

Metallic bonds are formed due to the attraction among the mobile valence electrons of the metal atom and its positively charged nucleus. In a piece of iron, the metallic bonds among Fe atoms will spread over the whole molecular assembly due to the de- localization of the valence electrons.  

These de-localized electrons are the valence electrons of metal atoms which are shared between them.

Hence, the correct answer from the given options is option B.

Answer: B) many valence electrons are shared between the atoms.

Explanation:

Answer:

Al2(SO4)3(aq) + 3BaCl2(aq) → 3BaSO4(s) + 2AlCl3(aq)

Explanation:

The question wants you to use the lowest possible coefficients to balance the equation.

According to the question the reaction is as follows ;

Generally, writing the chemical formula requires one to exchange the charge between the cations and anions involved. Example aluminum sulfate has Al3+ and (SO4)2- . cross multiply the charges to get Al2(SO4)3

aluminum sulfate → Al2(SO4)3

barium chloride → BaCl2

barium sulfate → BaSO4

aluminum chloride → AlCl3

Al2(SO4)3(aq) + BaCl2(aq) → BaSO4(s) + AlCl3(aq)

To balance a chemical equation one have to make sure the number of atom of element on the reactant side(left) is equal to the number of atom of elements on the product side(right).

Now, the equation can be be balance with the lowest coefficient as follows;

Al2(SO4)3(aq) + 3BaCl2(aq) → 3BaSO4(s) + 2AlCl3(aq)

The bold numbers is the coefficient use to balance the equation.

The number of atom on the reactant side is equal to the product side. Using aluminium atom as a case study the number of aluminium atom on the reactant side is 2 and the on the product  side it is also  2.

When aqueous aluminum sulfate and barium chloride are mixed, aluminum chloride forms as a product, while barium sulfate precipitates.

When aqueous solutions of aluminum sulfate and barium chloride are mixed, a double replacement reaction occurs. The aluminum sulfate dissociates into aluminum ions (Al³⁺) and sulfate ions (SO₄²⁻), while the barium chloride separates into barium ions (Ba²⁺) and chloride ions (Cl⁻).

The aluminum ions react with the chloride ions, forming aluminum chloride (AlCl₃) as a product. The barium ions react with the sulfate ions, resulting in the formation of solid barium sulfate (BaSO₄) as a precipitate. This reaction can be represented by the chemical equation: 3BaCl₂ + Al₂(SO₄) ₃ → 3BaSO₄ + 2AlCl₃.

In this reaction, the aluminum chloride remains in the aqueous solution, while the barium sulfate precipitates and can be separated from the solution.

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Answer:

This question is incomplete

Explanation:

This illustration refers to an hypertonic solution. Hypertonic solution is a solution in which the surrounding solution has a higher solute concentration (2% of NaCl) than the cell's cytosol (0.9% of NaCl). In hypertonic solution, the solution outside the cell (with higher concentration) pulls the water from the cell's cytosol (via osmosis) causing the cell to shrink.

Final answer:

A cell with 0.9% NaCl placed in a 2% NaCl solution experiences a hypertonic environment, causing it to lose water and shrink due to osmosis.

Explanation:

When a living cell with an internal tonicity equivalent to 0.9% NaCl is placed in a solution containing 2% NaCl, the surrounding solution is considered hypertonic. This is because the extracellular solution has a higher solute (salt) concentration than the cell's cytoplasm. The process of osmosis will cause water to move from the cell, which has a higher water potential, to the outside solution, where the water potential is lower because it has a higher solute concentration. Over time, this will result in the cell shrinking or losing water.

Osmolarity and tonicity are important concepts in understanding how cells interact with their environment. Isotonic conditions mean that the concentration of solutes is equal inside and outside the cell, resulting in no net water movement. Aquaporins, which are channel proteins in the cell membrane, facilitate the rapid movement of water across the cell membrane in response to these tonicity conditions.

Living organisms have developed strategies to maintain osmotic balance, such as the secretion of salts or the regulation of solute concentrations within their cells, to prevent cellular damage from excessive swelling or shrinking in hypo- or hypertonic environments.

Answer:

5

Explanation:

because im a bot :)

Answer:

a. Convergent boundary

b. Transform boundary

c. Divergent boundary

Explanation:

Convergent boundary are boundary where tectonic plates collide with each other. This kind of boundary might involve a collision between continental and oceanic plates, continental and continental plates and oceanic and oceanic plates. Generally, convergent boundary are regions for mountainous structures . Example of mountain formed through convergence are mountain Everest and Himalayas .

Transform boundary are boundary where tectonic plates move past each other . This kind of boundary is responsible for the creation of Extensive Fault like the San Andrea Fault.

Divergent boundary are boundary where tectonic plates move away from each other.  The diverging movements brings about oceanic ridges. The mid oceanic ridges is where magma rises to the surface to form a new crust. The up welling of this magma causes further separation of this plates.

The picture above illustrate convergent, divergent and transform boundary.

In plate tectonics, boundaries are categorized based on the relative movement of the lithospheric plates. Convergent boundaries occur when plates move toward each other, transform boundaries occur when plates slide past each other, and divergent boundaries occur when plates move away from each other.

In plate tectonics, the boundaries between different lithospheric plates are categorized based on their movement relative to each other.

a) Boundaries where plates move toward each other are known as convergent boundaries. At these boundaries, often one plate is forced under the other and is destroyed in the mantle in a process known as subduction. Examples include the boundary between the Pacific Plate and the North American Plate.

b) Boundaries where plates slide past each other are called transform boundaries. These usually cause earthquakes as the plates scrape against each other, the San Andreas Fault in California is a well-known example.

c) Boundaries where plates move away from each other are referred to as divergent boundaries. Here new crust is formed as magma wells up from the mantle, such as at the Mid-Atlantic Ridge.

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Answer:

52.0 gof CO2 contains 7.1 *10^23 molecules

1 molecule of CO2 has a mass of 7.3*10^-23 grams

Explanation:

Step 1: Data given

Mass of CO2 = 52.0 grams

Molar mass of CO2 = 44.01 g/mol

Number of Avogadro = 6.022 * 10^23 / mol

Step 2: Calculate moles of CO2

Moles CO2 = Mass CO2 / molar mass CO2

Moles CO2 = 52.0 grams / 44.01 g/mol

Moles CO2 = 1.18 moles

Step 3: Calculate molecules in 1.18 moles CO2

Number of molecules = 1.18 moles * 6.022*10^23 = 7.1 *10^23 molecules

1 molecule of CO2

Number of moles = 1 / 6.022*10^23

Number of moles = 1.66 *10^-24

Mass CO2 = 1.66*10^-24 moles * 44.01 g/mol

Mass CO2 = 7.3*10^-23 grams

To calculate the mass in grams of one molecule of CO₂, we divide the molar mass of CO₂ (44.01 g/mol) by Avogadro's number (6.022 × 10²³ molecules/mol), resulting in a mass of approximately 7.31 × 10⁻²³ g for one molecule.

To find the mass in grams of one molecule of CO₂, we use the molar mass of carbon dioxide and Avogadro's number. The molar mass of CO₂ is 44.01 g/mol, which means 1 mole (6.022 × 10²³ molecules) of CO₂ has a mass of 44.01 grams. To find the mass of one molecule, divide the molar mass by Avogadro's number:

Molar mass of CO₂ = 44.01 g/mol

Mass of one CO₂ molecule = Molar mass / Avogadro's number

Mass of one CO₂ molecule = 44.01 g/mol ÷ 6.022 × 10²³ molecules/mol

Mass of one CO₂ molecule ≈ 7.31 × 10⁻²³ g

To express this mass in terms of a single molecule of CO₂, we describe it as an extremely small mass because it represents a miniscule fraction of the mass of a mole of CO₂.

Answer:

Explanation:

The elements of group 17 are called halogens. These are six elements Fluorine, Chlorine, Bromine, Iodine, Astatine. Halogens are very reactive these elements can not be found free in nature. Their chemical properties are resemble greatly with each other.

Fluorine:

it is flammable gas.

It has pungent smell.

its reactions with all other elements are very vigorous except neon, oxygen, krypton and helium.  

It has adverse effect on human health. It is absorbed and lead to teeth decay.

It effects the nerves, kidney and muscles.

It causes osteoporosis.

Chlorine:

it is greenish-yellow irritating gas.

it is disinfectant and can kill the bacteria.

it is also used in manufacturing of paper, paints and textile industries.

It also have some adverse effect on human health such as it can effect the respiratory system, immune system and heart.

Bromine:

it is present in reddish brown color.

it has pungent odor.

it is very corrosive for human tissues.

Its vapors create irritation in throat and eyes.

In organic form it causes our lungs, gastrointestinal track and stomach.

Iodine:    

It is very corrosive and has pungent odor.  

It is used for thyroid treatment but large exposure to its radiations cause the tissue damage.

Answer:

F = -1.604x10⁻⁸ N

Explanation:

The Coulomb force (F) of repulsion between nearest-neighbor O²⁻ ions in CaO can be calculated using the next equation:    

[tex] F = K frac{(Z_{Ca^{2+}})(Z_{O^{2-}})(e^{-})^{2}}{r^{2}} [/tex]

where K: is the coulomb's constant, Z: is the charge of the Ca²⁺ and O²⁻ ions, e⁻: is the electron's charge, and r: is the distance between the nuclei of the two ions.  

Having that:

The Coulomb force (F) of repulsion is:

[tex] F = 9\cdot 10^{9} N*m^{2}*C^{-2} \frac{(2+)(2-)(1.602\cdot 10^{-19}C)^{2}}{(2.4\cdot 10^{-10} m)^{2}} = -1.604 \cdot 10^{-8} N [/tex]

Hence, the Coulomb force of repulsion between the two ions in CaO is -1.604x10⁻⁸ N.

I hope it helps you!

The coulombic force of repulsion between nearest-neighbour O²⁻ ions in CaO can be calculated using Coulomb's law and the crystal structure of CaO. The formula for calculating the force is F = k(q₁ × q₂)/r₂, where q₁ and q₂ are the charges of the ions, r is the distance between them, and k is a constant.

The coulombic force of repulsion between nearest-neighbor O²⁻ ions in CaO can be calculated using Coulomb's law. The formula for calculating the force of repulsion between two ions with charges q1 and q2, separated by a distance r, is given by:

F = k(q₁ × q₂)/r₂

In this case, the charge of each O²⁻ ion is -2. The distance between the ions can be determined using the crystal structure of CaO, which is rock salt. The nearest-neighbour distance (equilibrium separation distance) in a rock salt crystal is equal to the sum of the ionic radii of the cation and anion.

The value of the constant k in Coulomb's law is 8.99 x 109Nm²/C². The ionic radii of the O²⁻ and Ca²⁺ ions can be obtained from a reference table or provided data. Using the given values, you can calculate the coulombic force of repulsion between the nearest-neighbor O²⁻ ions in CaO.

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The steps associated with energy entering the system during the dissolution process involve the endothermic separation of solvent molecules and the separation of solute molecules, which require energy to overcome intermolecular forces.

The steps associated with energy entering the system during the dissolution process are:

Both the separation of solvent molecules (step 1) and the separation of solute molecules (step 2) are endothermic processes that require energy input. These processes involve overcoming the intermolecular attractive forces holding the respective particles together. Conversely, the mixing of solute and solvent molecules (step 3) is an exothermic process where energy is released, thus not associated with energy entering the system.

Whether the dissolution process is overall exothermic or endothermic depends on the relative magnitudes of the energy changes during these steps. For example, if the energy released during solvation is greater than the energy required for separating solute and solvent molecules, the overall process is exothermic. Conversely, if more energy is consumed in overcoming the solute-solute and solvent-solvent attractive forces than is released during solvation, the overall process is endothermic.

Final answer:

The molarity of the KNO3 solution is calculated by first finding the molar mass of KNO3, then determining the number of moles of KNO3 dissolved, and finally dividing the moles by the volume of the solution in liters, resulting in a molarity of 0.4118 M.

Explanation:

To calculate the molarity of a KNO3 solution made by dissolving 76.6 g of KNO3 in a total solution volume of 1.84 L, follow these steps:

Therefore, the molarity of the KNO3 solution is 0.4118 M.

Answer:Deficiency of vitamin D or Magnesium

Explanation:

Hypocalcemia is a condition where the calcium in body fluid such as plasma or blood is lower than the critical level. And this can be caused by a deficiency of vitamin D

Hypocalcemia could be caused by the apoptosis of parathyroid cells, failure of osteoclasts to respond to PTH and malfunction of the parathyroid hormone receptors in kidney tubule cells. Therefore, option D is correct.

The parathyroid glands produce parathyroid hormone (PTH), which plays a crucial role in regulating calcium levels.

Osteoclasts are cells responsible for breaking down bone tissue and releasing calcium into the bloodstream under the influence of PTH.

The kidneys play a crucial role in regulating calcium levels by reabsorbing or excreting calcium in response to PTH.

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The reaction rate increases by a factor of 6 when the concentration of NO2 is increased by half and the concentration of F2 is increased by four. This is because the reaction is first order with respect to both reactants, meaning the rate is directly proportional to their concentrations.

The chemical reaction is first order in NO2 and first order in F2, meaning the rate of the reaction is directly proportional to the concentration of these two reactants. If the concentration of NO2 is increased by a factor of 1.5 (or by half), the reaction rate also increases by a factor of 1.5. Likewise, if the concentration of F2 is increased by a factor of 4, the reaction rate also increases by a factor of 4. Therefore, with both these changes, the overall reaction rate would increase by a factor of 1.5 * 4 = 6.

In general, for a reaction that is first order in respect to a certain reactant, doubling the concentration of that reactant would double the rate of the reaction. Therefore, in this case, increasing the concentration of NO2 by half increases the rate by the same factor (1.5), and increasing the concentration of F2 by 4 increases the rate by the same factor (4).

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Final answer:

For a reaction that is first order in both NO₂ and F₂, increasing NO₂ concentration by half and F₂ concentration by four would result in a sixfold increase in the reaction rate.

Explanation:

The reaction being described is first order in NO₂ and first order in F₂. The rate of the reaction would increase in proportion to the changes in concentrations of both reactants, since it is first order with respect to each one. If the concentration of NO₂ was increased by half (a factor of 1.5) and the concentration of F₂ was increased by four (a factor of 4), the overall increase in rate would be calculated by multiplying the individual rate increases due to each reactant. This would give us an overall rate increase by a factor of 1.5 (due to NO₂) × 4 (due to F₂) = 6.