If 20 moles of fuel are combusted in C4H8 + 6 O2 -> 4 CO2 + 4 H2O, how many moles of O2 are consumed?

The value of the atomic mass of the metal calculated would be too high if the hot metal sample cooled off before it was transferred to the water in the calorimeter.

The atomic mass of an element is defined as the mass of an atom of an element in atomic mass units (amu). One atomic mass unit is defined as 1/12th of the mass of an atom of carbon-12.

The atomic mass of an element can be calculated using the following formula:

Atomic mass = (mass of isotope 1 × % abundance of isotope 1) + (mass of isotope 2 × % abundance of isotope 2) + (mass of isotope 3 × % abundance of isotope 3) + ...

If the hot metal sample cooled off before it was transferred to the water in the calorimeter, the temperature of the sample would have decreased. The decrease in temperature would result in a decrease in the thermal energy of the sample. Consequently, the amount of heat absorbed by the water in the calorimeter would decrease, leading to a lower value of the heat capacity of the metal.

Since the heat capacity is directly proportional to the mass of the sample, a lower value of the heat capacity would lead to a higher value of the atomic mass of the metal calculated. Therefore, the value of the atomic mass of the metal calculated would be too high if the hot metal sample cooled off before it was transferred to the water in the calorimeter.

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Using the Ideal Gas Law equation, the molar mass of a 98. 2 g sample of gas that fills a 50. 0-liter container at STP is 48 g/mol

The correct answer is option D.

The Ideal Gas Law is PV=nRT, where P is pressure, V is volume, n is the number of moles of the gas, R is the ideal gas constant and T is temperature.

According to the Ideal Gas Law equation to find the molar mass of a 98.2 g sample of gas that fills a 50.0-liter container at STP is given by:

It is not clear which gas is present in the container, but since the temperature and pressure are fixed (standard pressure and temperature), we can assume that this gas is an ideal gas.

We can use the ideal gas law to calculate the number of moles of this gas:

PV=nRT

⟹n=PV/RT

=1.00 atm×50.0 L/0.0821 L·atm/mol·K×273 K

=1.96 mol

Since we know the mass of this gas, we can now calculate its molar mass:

M=mass/number of moles

=98.2 g/1.96 mol=48 g/mol

So the molar mass of the given gas is 48 g/mol.

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The electron transport chain (ETC) is an essential part of cellular respiration, which is a series of molecules that transfer electrons from one molecule to another used by cells to convert nutrients into energy.

This starts with the oxidation of molecules such as glucose, which releases electrons that are then transferred to a series of electron carriers in the ETC. The electron carriers are molecules that hold the electrons and can transfer them to other molecules which is known as redox reactions. As the electrons move through the ETC, they release energy which is used to form a proton gradient that is then used to drive the synthesis of ATP, the energy currency of the cell. The ETC is an essential part of cellular respiration as it is the process responsible for generating the energy necessary for cells to function.

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The correct option based on the information given is:a. succinate dehydrogenase is the enzyme, and fumarate is the substrate.

Explanation:Succinate dehydrogenase is the enzyme involved in the conversion of succinate to fumarate.

This enzyme complex is also known as Complex II of the electron transport chain. The reaction catalyzed by succinate dehydrogenase is an oxidation-reduction reaction.

In this reaction, succinate is oxidized to fumarate, and FAD is reduced to FADH2.

This reaction is an important step in the process of cellular respiration, as it generates a molecule of FADH2 that can be used to produce ATP through oxidative phosphorylation.

These inhibitors bind to the active site of the enzyme and block the binding of succinate

.This inhibition is reversible, as the inhibitor can be displaced by high concentrations of substrate

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Consulting the laboratory notebook and notes about the color changes observed during titration, it is seen that the most accurate option for phenolphthalein is option (a).

When phenolphthalein was added to the solution, it started out colorless, turned to pink at about pH 9, and was deep purple at the first equivalence point.

Phenolphthalein is a pH-sensitive indicator that changes color in the pH range of 8.3 to 10.0. The colorless form of phenolphthalein is present in acidic solutions, whereas the pink form of phenolphthalein is present in basic solutions. The deep purple coloration is representative of the first equivalence point.

The pH of a solution can be determined using an acid-base indicator. Indicators are chemicals that change color in response to changes in acidity. Indicators are typically used to determine the endpoint of an acid-base titration when the pH changes rapidly over a small range of volumes. The color of the indicator corresponds to a specific pH value.

A colorless solution with a low pH will gradually become pink as it approaches the endpoint. As a result, the pH range observed with the phenolphthalein indicator is from about pH 8.3 to 10.0, with a color change from colorless to pink occurring around pH 9.0.

Therefore, "When the indicator was added to the solution, it started out colorless, turned to pink at about pH 9, and was deep purple at the first equivalence point" is the correct answer.

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When the  12. 00 mol Iron react with 6.00 mol O2 then 4.00 mol of Fe3O4 can be produced.

In order to know  how many moles of Fe3O4 can be produced from the reaction of 12.00 mol Fe with 6.00 mol O2, we first need to get balance the chemical equation for the reaction:

4 Fe + 3 O2 -----> 2 Fe3O4

From the balanced equation, we can see that for every 4 moles of Fe that react, we need 3 moles of O2. Therefore, the limiting reactant in this case is O2, since we only have 6.00 mol available, while we need 8.00 mol to react with all 12.00 mol of Fe. This means that Fe will be in excess and we can calculate the amount of Fe3O4 produced based on the amount of O2 that reacts.

To do this, we can use the mole ratio from the balanced equation:

3 mol O2 --------> 2 mol Fe3O4

So, for every 3 moles of oxygen that react, we can produce 2 moles of Fe3O4. Since we have 6.00 mol of O2, we can obtain the moles of Fe3O4 produced as follows:

6.00 mol O2 x (2 mol Fe3O4 / 3 mol O2) = 4.00 mol Fe3O4

Therefore, it can be concluded that 4.00 mol of Fe3O4 can be produced when 12.00 mol Iron reacts with 6.00 mol O2.

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When 27 g of iron reacts with oxygen, a total of 8 electrons are transferred.

The balanced equation for this reaction is:  
4Fe + 3O2 → 2Fe2O3

This equation tells us that 4 moles of iron (Fe) react with 3 moles of oxygen (O2) to form 2 moles of iron oxide (Fe2O3).

Molar mass of iron = 55.85 g/mol.

The number of moles: 27 g Fe × (1 mol Fe/55.85 g Fe) = 0.483 mol Fe

Therefore, 27 g of iron is equivalent to 0.483 moles of iron.

0.483 mol Fe × 4 electrons/mol Fe = 1.932 electrons

To convert this value to the number of electrons per 27 g of iron. To do this, we can use Avogadro's number, which tells us the number of particles (including electrons) in one mole of a substance:

1.932 electrons/mol × 6.022 × 10^23 electrons/mol = 1.162 × 10^24 electrons ≈ 8

Therefore, the number of electrons transferred when 27 g of iron reacts is approximately 8.

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The precipitate that will form when a solution of aluminum chloride is mixed with a solution of potassium phosphate is aluminum phosphate (AlPO4).

When aluminum chloride and potassium phosphate are mixed together, the cations and anions form different combinations of ion pairs. This causes the precipitation of a solid phase (AlPO4) from the solution. The chemical reaction that occurs can be represented as follows:

3K3PO4 + 2AlCl3 → 6KCl + AlPO4

The aluminum ion (Al3+) in the aluminum chloride solution and the phosphate ion (PO43−) in the potassium phosphate solution combine to form a precipitate of aluminum phosphate (AlPO4). The resulting solid aluminum phosphate (AlPO4) will appear as a white or slightly yellowish powder. The solubility of AlPO4 in water is relatively low, with a solubility of about 0.06 grams per liter of water at room temperature (25°C).

Therefore, it will readily settle out of the solution as a solid mass, rather than remaining dissolved.

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0.566 moles of hydrogen iodide will be formed upon the complete reaction of 0.283 moles of hydrogen gas with excess iodine.

To determine how many moles of hydrogen iodide will be formed, we need to use stoichiometry.

The balanced chemical equation for the given reaction is:-

H₂ (g) + I₂ (s) → 2HI (g)

From the balanced chemical equation, we know that 1 mole of hydrogen reacts with 1 mole of iodine to produce 2 moles of hydrogen iodide.

Since the number of moles of hydrogen is given as 0.283 moles, therefore, the number of moles of iodine required is also 0.283 moles.

Therefore, the number of moles of hydrogen iodide formed = 2 x 0.283 mol= 0.566 mol.

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The molecule with the highest boiling point is 1,4-butanediol. This is because of the presence of intermolecular hydrogen bonding. Thus, the correct option is C.

A hydrogen bond is an intermolecular force that exists between a hydrogen atom bonded to a highly electronegative atom (like N, O, or F) and another highly electronegative atom in another molecule. Hydrogen bonding is a type of dipole-dipole interaction that occurs between molecules that have a permanent dipole.

The four molecules, 3-methoxy-1-propanol, 1,2-dimethoxyethane, 1,4-butanediol, and 2-methoxy-1-propanol, all have oxygen atoms that are capable of forming hydrogen bonds. In order to form a hydrogen bond, a hydrogen atom in one molecule must be bonded to an electronegative atom like oxygen or nitrogen, and another electronegative atom in a neighboring molecule must be present.

In this case, 1,4-butanediol has two -OH groups on the ends of the carbon chain that are capable of forming hydrogen bonds with neighboring molecules, resulting in a higher boiling point. Because of the presence of intermolecular hydrogen bonding, the molecules have stronger intermolecular forces that require more energy to break, resulting in a higher boiling point.

Therefore, the correct option is C.

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The equations that relate the partial derivatives of pressure, volume, temperature, and entropy of a simple compressible system are called Maxwell relations.

Maxwell's relations or thermodynamic equations of state are the set of equations in thermodynamics that relate partial derivatives of properties of a thermodynamic system to each other. The Maxwell relations arise from the fundamental relations between thermodynamic potentials.The Maxwell relations relate the partial derivatives of thermodynamic properties such as pressure, volume, temperature, and entropy. They are a consequence of the symmetry of the second derivative of the thermodynamic potential.

The four thermodynamic potentials are internal energy, enthalpy, Helmholtz free energy, and Gibbs free energy. The relations are named after James Clerk Maxwell, who presented them as part of his 1871 textbook "Theory of Heat."The Maxwell relations are named after James Clerk Maxwell, a Scottish physicist who first published them in 1871 in his book Theory of Heat. They are applied in thermodynamics to help connect and calculate various thermodynamic properties of a system.

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The appropriate unit for a third-order rate constant is  The L² mol-² s-¹. A third-order reaction is a type of chemical reaction where the concentration of each molecular responding determines how quickly the reaction proceeds.

A reaction rate constant, or reaction rate coefficient, k, quantifies the rate and direction of a chemical reaction in chemical kinetics. The rate constant, also known as the specific rate constant, is the proportionality constant in the equation expressing the relationship between the rate of a chemical reaction and the concentrations of the reactants.

A third-order reaction is a type of chemical reaction where the concentration of each molecular responding determines how quickly the reaction proceeds. Typically, the variation of three concentration factors in this reaction determines the rate.

There may be various cases involved when dealing with a third-order reaction. It might be;

(i) The concentrations of the three reactants are equal.

(ii) Two reactants are present in an equal amount, but one is present in a different amount.

(iii) The concentrations of the three reactants vary or are uneven.

Use formula,

(mol/L)¹⁻ⁿ s⁻¹

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A synthesis of the compound can begin by reacting the indole group of tryptophan with an alkyl halide to form a quaternary ammonium salt.

The structure below is an inhibitor of the enzyme phosphodiesterase type 5 and a blockbuster FDA-approved drug. To propose a synthesis of this compound using tryptophan as a starting material, we need to understand the chemical structure of the compound.

The structure of the compound contains two nitrogen atoms, one hydrogen atom, and two nitrogen-hydrogen bonds (NHNN). The starting material, tryptophan, contains a ring structure with an indole group, two nitrogen atoms, and four carbon atoms.

A synthesis of the compound can begin by reacting the indole group of tryptophan with an alkyl halide to form a quaternary ammonium salt. This salt can then be reacted with a Lewis acid to form a substituted Indolium ion. The Indolium ion can be reacted with a nucleophile such as hydrazine to form an oxazolidinone intermediate.

Finally, a ring closure of the oxazolidinone intermediate can yield the desired compound.

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The statement that best identify the main idea of the article are, A and C

A) Fingerprints are still the most accurate way to identify a person.

C) Biometric features are slightly different in everyone.

The article seems to focus on biometric technology and the different ways it can be used for identification, security, and health purposes.

It explains that fingerprints remain the most accurate way to identify a person, but also discusses the unique features of other biometric identifiers such as facial recognition and blood vessels.

Lastly, the article emphasizes the importance of recognizing that biometric features are unique to each individual.

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The average atomic mass of m is 79.90 amu.

The average atomic mass of m is given by the formula below:

The average atomic mass of m= [(Abundance of 79m * Mass of 79m) + (Abundance of 81m * Mass of 81m)]/100

Average atomic mass of m = [(50.69% * 78.9183 amu) + (49.31% * 80.9163 amu)]/100

The average atomic mass of m = [(0.5069 * 78.9183) + (0.4931 * 80.9163)]/100

The average atomic mass of m = 79.90 amu

Therefore, the average atomic mass of m is found to be 79.90 amu.

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The reaction of hydrogen gas and oxygen gas to produce water is an exothermic reaction because more energy is released in the formation of the products than is needed to break the bonds of the reactants.

In other words, more energy is released when the hydrogen and oxygen molecules combine to form water molecules than is needed to break the bonds between the hydrogen and oxygen molecules.

Exothermic reaction- It is a type of reaction in which the two atoms react with each other to form a stable compound and release energy in the process of doing so.

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The following are thought to be key requirements for a world to have life: A source of energy to fuel metabolism, A source of molecules from which to build living cells, A liquid medium, These are the primary requirements for a world to have life. These requirements are key to the development and sustainability of life on Earth.

Every living organism requires energy to survive, and this energy comes from a variety of sources, including sunlight, food, or chemical reactions. It's necessary to have a source of energy to fuel metabolism, as it helps with the growth, development, and reproduction of an organism.  A source of molecules from which to build living cells

These molecules can include things like amino acids, sugars, and lipids. A liquid medium is essential for life because it provides an environment in which chemical reactions can occur. Most chemical reactions require water to proceed, and water is also the medium in which cells operate. This is why water is considered to be the universal solvent and is an essential component for life on Earth.

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Answer:

Explanation: Use the formula density = mass divided by volume

so to get the answer multiply the density by the volume

Answer: 1.63 x (0.25x1000)

we multiply 0.25 by 1000 because we need to use volume in ml instead of L.

2.32 g of  CO2 will dissolve if the pressure is raised to 1. 35 atm and the temperature will remain the same.

The given data is:

Pressure = 1 atm

Temperature = 20 degrees =  293 K

CO2 weight = 1.72g

Water weight = 1L

Henry's law is used which defines that the amount of gas dissolved in a fluid is proportional to the partial pressure of the gas beyond the liquid.

Mathematically,

C = kH * P

C is the concentration of the gas given.

1.72 g CO2 / 44.01 g/mol = 0.039 mol CO2

C = 0.039 mol/L

kH = C/P

kH = 0.039 mol/L / 1 atm = 0.039 mol/(L*atm)

CO2 when the pressure is raised to 1.35 atm:

P' = 1.35 atm

C' = kH * P'

C' = (0.039 mol/(L*atm)) * 1.35 atm

C' = 0.0527 mol/L

The amount of CO2 dissolved in the water is

m = C' * M * V

m = 0.0527 mol/L * 44.01 g/mol * 1 L

m = 2.32 g

Therefore, a pressure of 1.35 atm is required and at a temperature of 20°C,  makes 2.32g of CO2 will dissolve.

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The longest chain is pentane

The functional group is alkene

The name of the compound would be based on the kinds of substituents present.

In organic chemistry, there are two main types of branching in organic compounds: chain branching and positional branching.

Chain branching: Chain branching occurs when a side chain (alkyl group) is attached to the main carbon chain of a molecule. This results in a change in the chemical and physical properties of the molecule, such as boiling point, melting point, and solubility. Examples of chain-branched compounds include isobutane (2-methylpropane), isopentane (2-methylbutane), and neopentane (2,2-dimethylpropane).

Positional branching: Positional branching occurs when a substituent is attached to a specific position on the main carbon chain of a molecule. This type of branching can occur in cyclic or acyclic molecules, and can have a significant impact on the properties and reactivity of the molecule. Examples of positional-branched compounds include tert-butyl alcohol (2-methyl-2-propanol), 1-chloro-3-methylbutane, and 2,4-dimethylhexane.

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The electronic configuration for an atom of oxygen is:

1s2 2s2 2p2

The correct options is:

C. This specific electron configuration has one unpaired electron.

Electron configuration can be defined as the specific arrangement of negatively charged electrons in different energy levels around atomic nuclei.

The correct statements about this electron configuration are:

A. The atom of oxygen represented by this configuration will have a charge: This statement is incorrect. The electron configuration provided is for a neutral oxygen atom, which means it has no charge.

B. This specific electron configuration has three unpaired electrons: This statement is incorrect. The 2p subshell contains a total of 4 electrons, which are arranged in 2 orbitals with opposite spins. This means that there are 2 paired electrons and 2 unpaired electrons, not 3.

C. This specific electron configuration has one unpaired electron: This statement is correct. The 2p subshell contains 2 orbitals, each of which can hold a maximum of 2 electrons. Since the 2p subshell contains 4 electrons, there are 2 paired electrons and 2 unpaired electrons, with one unpaired electron in each of the two 2p orbitals.

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There are five chemical bonds that you can learn about in chemistry. These chemical bonds include: Covalent bond, Ionic bond, Polar covalent bond, Metallic bond, and Hydrogen bond.

Covalent bond: It is the bond formed by sharing electrons between two atoms. It is one of the most powerful chemical bonds that holds molecules together. This bond can be formed between atoms of the same or different elements.

Ionic bond: It is the bond formed by the transfer of electrons from one atom to another. This bond is formed between metals and non-metals.

Polar covalent bond: It is the bond formed between two atoms that have different electronegativity values. The electrons in this bond are shared unequally between the two atoms. This bond is intermediate between the covalent and ionic bond.

Metallic bond: It is the bond formed between metal atoms. In this bond, electrons move freely between metal atoms.

Hydrogen bond: It is the bond formed between a hydrogen atom and an electronegative atom. This bond is responsible for many of the unique properties of water.

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Answer:

Gravity helps move water into the ground.

Therefore, the constancy in color intensity can be an indicator of a dynamic equilibrium, where the rates of the forward and reverse reactions are equal and the concentrations of reactants and products remain constant over time.

Chemical equilibrium occurs when a reversible reaction takes place, where the reactants can form products and the products can also react to form reactants. At the beginning of the reaction, the reactants are transformed into products, and as the reaction progresses, the concentration of the reactants decreases while the concentration of the products increases. Eventually, a point is reached where the rate of the forward reaction is equal to the rate of the reverse reaction, and the concentrations of the reactants and products remain constant. This state is called chemical equilibrium.

Here,

The constancy in color intensity can indicate the dynamic nature of equilibrium in certain cases. In a chemical equilibrium, the forward and reverse reactions are occurring simultaneously, but at equal rates, resulting in a constant concentration of reactants and products. Many chemical reactions involve colored species, and changes in the intensity of the color can indicate a change in the concentration of the species involved. For example, consider the reaction between iodine and starch:

I2 + starch ⇌ I2-starch complex

In this reaction, the iodine-starch complex is a blue-purple color, while the reactants (iodine and starch) are colorless. As the reaction proceeds, the concentration of the complex increases, leading to an increase in color intensity. However, if the reaction reaches equilibrium, the forward and reverse reactions will be occurring at equal rates, and the concentration of the complex will remain constant. This will result in a constant color intensity, indicating the dynamic nature of the equilibrium.

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Food fats and oils decay through a process known as rancidity, which affects the taste, texture, and flavour of the meal as well as the odour and smell. Unsaturated fatty acid oxidation is what triggers this process.

Rancidity is known to be influenced by time, temperature, light, air, exposed surface, moisture, nitrogenous organic material, and traces of metals.

Unsaturated fatty acids that contain double bonds in their molecules are peroxidation-prone. Lipids can undergo this peroxidation, often known as "oxidative degradation," in one of two ways. Autoxidation is one method, and it's by far the most significant one. A less significant alternative is an enzymatic oxidation. A fatty acid molecule undergoes oxidation when an oxygen ion replaces a hydrogen ion, and the likelihood of autoxidation rises as the number of double bonds increases inside the fatty acid.

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To solve this problem, we need to use the ideal gas law, which relates the pressure, volume, and temperature of a gas to the number of moles of gas present. We can use the balanced chemical equation to determine the number of moles of oxygen produced by the reaction of LICIO4.

The molar mass of LICIO4 is:

LICIO4: Li = 1 x 1 = 1 g/mol, I = 127 g/mol, O4 = 4 x 16 = 64 g/mol

Total molar mass = 1 + 127 + 64 = 192 g/mol

So, 500 g of LICIO4 is equal to:

500 g / 192 g/mol = 2.604 moles of LICIO4

From the balanced chemical equation, we see that for every mole of LICIO4, two moles of oxygen are produced:

1 mol LICIO4 → 2 mol O2

Therefore, 2.604 moles of LICIO4 will produce:

2.604 moles x 2 mol O2/1 mol LICIO4 = 5.208 moles of O2

Now we can use the ideal gas law to calculate the volume of oxygen produced at the given temperature and pressure:

PV = nRT

where P is the pressure (101.5 kPa), V is the volume we want to find, n is the number of moles of oxygen (5.208 moles), R is the ideal gas constant (8.314 J/mol K), and T is the temperature in Kelvin (21°C + 273 = 294 K).

V = (nRT)/P

V = (5.208 mol x 8.314 J/mol K x 294 K)/101.5 kPa

Converting kPa to Pa, we get:

V = (5.208 mol x 8.314 J/mol K x 294 K)/(101.5 x 1000 Pa)

V = 101.92 m3 or 101,920 L

Therefore, the system would produce approximately 101,920 liters of oxygen at the station's standard operating conditions.

Answer:

   Fatty acids

   Steroids

   Glycolipids

   Triacylglycerols

   Sphingolipids

   Phospholipids

The reaction demonstrates that energy is needed to dissociate the hydrogen atoms from one another, and as a result energy is consumed.

When a chemical bond is broken, energy is required to break the bond, and thus energy is absorbed. The equation that represents energy being absorbed as a bond is broken is option D, which is:

H2 + energy → 2H

In this equation, the energy is shown as a reactant on the left-hand side of the arrow, indicating that it is required for the reaction to proceed. The H2 molecule on the left-hand side represents a molecule with a covalent bond between two hydrogen atoms. When energy is added to the molecule, the bond between the two hydrogen atoms is broken, and the atoms become separated. This results in the formation of two hydrogen atoms on the right-hand side of the arrow, each with one unpaired electron.

Overall, the reaction shows that energy is required to break the bond between the hydrogen atoms, and thus energy is absorbed during the process.

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