JAMB UTME - Chemistry - 2023

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The device used to determine the heat of reaction experimentally is called a calorimeter.

A calorimeter is a tool designed to measure the amount of heat absorbed or released during a chemical reaction or a physical process. It is commonly used in chemistry laboratories to determine the heat changes associated with chemical reactions, such as the heat of reaction.

The principle behind a calorimeter is that the heat released or absorbed by a reaction is transferred to the surrounding environment, which includes the substances inside the calorimeter. By measuring the temperature change of the substances inside the calorimeter, the heat of reaction can be determined.

A simple calorimeter consists of a container, often made of a good insulator, such as Styrofoam, to minimize heat exchange with the surroundings. Inside the container, the reactants are mixed, and the temperature change is monitored with a thermometer.

During a chemical reaction, if heat is absorbed from the surroundings, the temperature inside the calorimeter will decrease. Conversely, if heat is released to the surroundings, the temperature inside the calorimeter will increase. By measuring the temperature change and knowing the specific heat capacity of the substances involved, the heat of reaction can be calculated.

Therefore, a calorimeter is essential for determining the heat of reaction experimentally, allowing scientists to understand the energy changes associated with chemical reactions.

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The reaction where benzene is converted to toluene by the addition of a methyl group is an example of electrophilic substitution. In electrophilic substitution reactions, a hydrogen atom in the benzene ring is replaced by an electrophile (electron deficient species) to form a new compound.

Here, the methyl group is the electrophile that replaces one of the hydrogen atoms in the benzene ring, resulting in the formation of toluene.

During the reaction, the benzene ring undergoes a series of steps:

1. An electrophile, in this case, the methyl group, is attracted to the electron-rich benzene ring.
2. The electrophile forms a bond with one of the carbon atoms in the benzene ring, breaking the aromaticity of the ring.
3. This leads to the formation of a sigma complex, where the electrophile is attached to the benzene ring.
4. Finally, the sigma complex is converted back into an aromatic compound by the loss of a proton, resulting in the formation of toluene.

Therefore, the addition of a methyl group to benzene to form toluene is an example of electrophilic substitution.

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An example of a primary cell is an alkaline battery.

Primary cells are non-rechargeable batteries, meaning once they have been depleted of their energy, they cannot be recharged and must be replaced. These types of batteries are commonly found in everyday household items like remote controls, toys, and flashlights.

The alkaline battery works by converting chemical energy into electrical energy. Inside the battery, there are two electrodes - a negative electrode (anode) and a positive electrode (cathode). These electrodes are separated by an electrolyte, which allows the flow of ions between them.

During use, a chemical reaction occurs at the anode, causing zinc ions to be released into the electrolyte. At the cathode, manganese dioxide reacts with the zinc ions and water, producing hydroxide ions. The movement of ions creates an electron flow from the anode to the cathode, generating an electric current.

As the reactions continue, the zinc anode gradually gets consumed, and the battery loses its ability to produce electricity. Once the chemical reactions are complete, the alkaline battery is considered "dead" and needs to be replaced.

In contrast, the other options given are not primary cells:

• A fuel cell is an electrochemical cell that continuously converts fuel and an oxidizing agent into electricity. It differs from a primary cell because the reactants can be replenished, allowing it to produce electricity continuously.
• A lead-acid battery is a rechargeable battery, often used in automotive applications. It can be recharged by reversing the chemical reactions that occur during discharge.
• A lithium-ion battery is also a rechargeable battery commonly used in portable electronic devices. Similar to the lead-acid battery, its chemical reactions can be reversed through charging.

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The solubility product constant (Ksp) is used to calculate the solubility of a solute in a given solvent. It helps us understand how much of a particular compound can dissolve in a specific solvent at a given temperature. : "To measure the total mass of a solute that can dissolve in a solvent" - This option is incorrect. The solubility product constant does not directly measure the mass of a solute that can dissolve. It calculates the maximum amount of solute that can dissolve in the solvent. : "To determine the concentration of a solute in a saturated solution" - This option is partially correct. The solubility product constant is involved in determining the concentration of a solute in a saturated solution. By knowing the Ksp value and the concentrations of the ions in the saturated solution, we can calculate the solute concentration. : "To calculate the solubility of a solute in a given solvent" - This option is correct. The solubility product constant is used to calculate the solubility of a solute in a given solvent. Solubility refers to the maximum amount of solute that can dissolve in a specific amount of solvent at a given temperature. : "To compare the solubilities of different solutes in the same solvent" - This option is not directly related to the solubility product constant. While Ksp values can be used to indirectly compare the solubilities of different solutes, the primary purpose of Ksp is to calculate solubility, not comparison. In summary, the solubility product constant (Ksp) is mainly used to calculate the solubility of a solute in a given solvent. It helps determine the maximum amount of solute that can dissolve in the solvent at a specific temperature.

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The highest entropy change would be expected in the Liquid → Gas reaction.

Entropy is a measure of the disorder or randomness in a system. When a substance changes from a state of lower disorder to a state of higher disorder, its entropy increases.

In the Liquid → Gas reaction, the substance is changing from a liquid state (where the particles are more closely packed and have less freedom of movement) to a gas state (where the particles are more spread out and have more freedom of movement).

As the particles transition from being tightly packed in the liquid phase to being more spread out in the gas phase, their randomness increases. This increase in randomness leads to an increase in entropy.

Therefore, the Liquid → Gas reaction would be expected to have the highest entropy change among the given options.

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To calculate the mass of ethanol, we need to use its density and volume. The density of ethanol is given as 0.789 grams per milliliter.

First, let's convert the volume from milliliters to liters. Since there are 1000 milliliters in a liter, 500 mL is equivalent to 0.5 liters.

Now, we can use the formula:

Mass = Density x Volume

Substituting the value, we have:

Mass = 0.789 g/mL x 0.5 L

Multiplying these values, we find that the mass of 500 mL of ethanol is 0.3945 grams. Therefore, the correct answer is 394.5 g.

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The symbol used to represent an alpha particle is α. An alpha particle is a type of particle that is often emitted during radioactive decay. It consists of two protons and two neutrons, giving it a positive charge of +2. The symbol α is derived from the Greek letter alpha (α), which represents the first letter of the Greek alphabet. It is used in scientific notations and equations to indicate the presence or interaction of an alpha particle.

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The pressure exerted by a gas is due to the collisions of gas particles with the container walls. This is explained by the kinetic theory of gases, which provides a simple model to understand the behavior of gases. According to the kinetic theory, a gas is made up of tiny particles (such as atoms or molecules) that are in constant random motion. These particles move in straight lines until they collide with each other or with the walls of the container. When gas particles collide with the walls of the container, they exert a force on the walls. This force is what we call pressure. The more frequently and forcefully the particles collide with the walls, the greater the pressure exerted by the gas. The other options mentioned - the vibrations of gas particles, the weight of the gas particles, and the attractive forces between gas particles - are not the primary factors contributing to the pressure exerted by a gas. While these factors may play a role in certain situations, they are not the main reason for the pressure in a gas. In summary, the pressure exerted by a gas is primarily due to the collisions of gas particles with the container walls. This concept is explained by the kinetic theory of gases, which helps us understand the behavior of gases and how they exert pressure.

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An electrovalent bond, also known as an ionic bond, is a type of chemical bond that forms between two atoms when one atom transfers electrons to another. This creates a bond between the positively charged ion and the negatively charged ion.

Out of the given compounds, NaCl (sodium chloride) is an example of an electrovalent bond.

In NaCl, a sodium atom transfers one electron to a chlorine atom. This results in the formation of a sodium ion (Na+) and a chlorine ion (Cl-). The sodium ion has a positive charge because it lost an electron and the chlorine ion has a negative charge because it gained an electron.

The opposite charges of the sodium and chlorine ions attract each other, resulting in the formation of a strong electrovalent/ionic bond between them. This bond holds the sodium and chloride ions together to form a crystal lattice structure of sodium chloride.

On the other hand, CO2 (carbon dioxide), H2O (water), and CH4 (methane) do not involve the transfer of electrons between atoms. These compounds have covalent bonds, where electrons are shared between atoms.

Understanding the concept of electrovalent bonds is important because it helps explain the properties and behavior of ionic compounds, such as their high melting and boiling points, solubility in water, and ability to conduct electricity when dissolved or molten.

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The state of matter in which particles are widely spaced and move freely with high kinetic energy is gas.

Gas is one of the four fundamental states of matter, along with solid, liquid, and plasma. In the gas state, the particles are not tightly packed together like in solids and liquids. Instead, they are widely spread apart and move around in random directions at high speeds.

The high kinetic energy of gas particles allows them to move freely and independently from one another. They are not constrained by any definite shape or volume, which means gases can expand to fill the entire container they are placed in.

Particles in a gas state have weak attractive forces between them, resulting in the lack of a fixed arrangement or structure. This makes gases highly compressible, meaning their volume can be reduced by applying pressure.

Examples of gases include oxygen, nitrogen, carbon dioxide, and helium. They exist in various forms in our everyday lives, from the air we breathe to the gases used in cooking, heating, and industrial processes.

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A unique property of water compared to other liquids is that it expands when freezing.

When most substances freeze, the molecules become more closely packed together and the substance contracts or becomes denser. However, water is different. As it cools below 4 degrees Celsius, the water molecules start forming a crystal lattice structure. This structure has a more open arrangement, causing the water molecules to move further apart and take up more space. This expansion causes ice to be less dense than liquid water. This expansion is why ice floats in liquid water. If water did not expand when freezing, ice would sink and bodies of water like lakes and oceans would freeze from the bottom up, endangering aquatic life. The expansion of water when freezing is also important for another reason. It helps prevent the environment from experiencing rapid temperature fluctuations. When the temperature drops, the top layer of a body of water freezes, acting as an insulating layer for the water below, and protecting aquatic life during cold winter months. Overall, the expansion of water when freezing is a unique property of water that has significant implications for the survival of organisms and the stability of ecosystems.

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Soap and detergent molecules have a **hydrophilic head** and a **hydrophobic tail**. The hydrophilic head is attracted to water and likes to be in contact with it. It is made up of a polar group, which means it has charges that can interact with water molecules. This allows the head to dissolve in water. On the other hand, the hydrophobic tail is repelled by water and does not like to be in contact with it. It is made up of a nonpolar group, which means it does not have charges that can interact with water molecules. This causes the tail to repel water. The combination of the hydrophilic head and hydrophobic tail makes soap and detergent molecules very effective at cleaning. This is because when soap or detergent is added to water, the hydrophobic tails cluster together and try to avoid the water, while the hydrophilic heads face outwards and interact with the water. This arrangement forms structures called micelles, where the hydrophobic tails are shielded from the water and the hydrophilic heads are exposed. The micelles can trap dirt, oils, and grease in their hydrophobic core, while the hydrophilic heads allow the micelles to be easily rinsed away with water. In summary, the chemical structure of soap and detergent molecules consists of a hydrophilic head that likes water and a hydrophobic tail that repels water. This structure allows them to effectively clean by forming micelles that can trap dirt and oils, which can then be easily rinsed away with water.

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Chlorine gas is commonly used in the production of chlorofluorocarbons (CFCs). CFCs are industrial compounds that were widely used in the past as refrigerants, propellants in aerosol cans, and as solvents. However, due to their harmful effects on the ozone layer, their production and use have been greatly reduced.

Chlorine gas, when combined with carbon and fluorine atoms, forms CFCs. These compounds are stable and can remain in the atmosphere for a long time, causing damage to the ozone layer. The chlorine atoms in CFCs react with ozone (O3) molecules, breaking them apart and depleting the ozone layer.

Despite the harmful environmental impact of CFCs, it is important to understand their historical uses and the role chlorine gas plays in their production.

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The type of chemical combination that involves the transfer of electrons from one atom to another, resulting in the formation of oppositely charged ions, is ionic bonding.

In an ionic bond, one atom donates electrons to another atom. This happens when one atom has a stronger attraction for electrons than the other. The atom that donates electrons becomes positively charged (known as a cation), while the atom that receives the electrons becomes negatively charged (known as an anion).

The transfer of electrons occurs because atoms want to achieve a stable electron configuration, usually by having a complete outermost electron shell. By transferring electrons, atoms can achieve this stability. The resulting oppositely charged ions are attracted to each other due to the electrostatic force, forming an ionic bond.

For example, in the formation of table salt (sodium chloride), sodium (Na) donates an electron to chlorine (Cl). Sodium becomes a positively charged ion (Na+), and chlorine becomes a negatively charged ion (Cl-). The positive and negative charges attract each other, creating the ionic bond in sodium chloride.

Overall, ionic bonding involves the transfer of electrons, resulting in the formation of oppositely charged ions. This type of chemical combination is an essential concept in understanding various compounds and their properties.

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The correct answer is Niels Bohr. Niels Bohr proposed the planetary model of the atom with electrons orbiting the nucleus. His model was an improvement on the earlier atomic models proposed by J.J. Thomson and Ernest Rutherford. In Bohr's model, electrons exist in specific energy levels or orbits around the nucleus. These energy levels are represented by the electron shells. The electrons occupy the shells closest to the nucleus first, and then fill the outer shells successively. Bohr also introduced the concept of quantized energy in his model. According to his theory, electrons can only exist in certain energy levels and cannot exist in between. When an electron absorbs or emits energy, it jumps between these energy levels. This model provided a better understanding of the stability of atoms and explained aspects such as the spectral lines observed in atomic emission and absorption spectra. In summary, Niels Bohr proposed the planetary model of the atom with electrons orbiting the nucleus, which helped explain the behavior and stability of atoms.

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Isotopes of an element have the same number of protons (which defines the element) but may have different numbers of neutrons. Since atoms are electrically neutral, the number of protons must equal the number of electrons in an atom.

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The reaction involved in the formation of alkanols from alkenes is called addition reaction.

In an addition reaction, two reactants combine together to form a larger product molecule. In this case, the alkene (a hydrocarbon with a carbon-carbon double bond) reacts with a molecule of water (H2O) to form an alkanol (an alcohol).

During the reaction, the carbon-carbon double bond in the alkene breaks, and each carbon atom bonds to a hydrogen atom from the water molecule.

This results in the formation of a single bond between the carbon atoms and a bond between each carbon atom and a hydrogen atom.

The remaining oxygen and hydrogen atoms from the water molecule form a hydroxyl group (-OH) on one of the carbon atoms. This addition reaction is a way to introduce an -OH group and create an alcohol from an alkene.

It is important to note that alkanols are a specific type of alcohol where the hydroxyl group is attached to a saturated carbon atom (a carbon atom bonded to four other atoms).

Therefore, the correct answer is addition reaction.

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The main source of carbon monoxide (CO) in urban areas is vehicle emissions.

When vehicles burn fuel, such as gasoline or diesel, they produce a variety of air pollutants, including carbon monoxide. This occurs because the fuel combustion process is not completely efficient, resulting in the release of carbon monoxide gas into the air.

Vehicle emissions are a significant contributor to air pollution in urban areas, especially in densely populated cities where there is a high concentration of vehicles. The exhaust from cars, trucks, buses, and motorcycles contributes to the elevated levels of carbon monoxide in the surrounding air.

Carbon monoxide is a colorless and odorless gas that is harmful to human health. It can be particularly dangerous in enclosed spaces, as it can build up to toxic levels and interfere with the body's ability to carry oxygen to vital organs.

To reduce the levels of carbon monoxide in urban areas, it is important to implement measures such as adopting cleaner transportation technologies, promoting public transportation, and improving vehicle emission standards. These efforts can help mitigate the negative impacts of carbon monoxide on air quality and public health.

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The process of rusting is an example of the formation of an acidic oxide.

Rusting occurs when iron or steel react with oxygen and moisture in the presence of an electrolyte (such as water or salt). This reaction forms a reddish-brown substance called rust.

Rust is considered an acidic oxide because it reacts with water to form an acid. When moisture is present, iron reacts with oxygen to create iron(III) oxide, which is the main component of rust. This iron oxide reacts further with water to produce hydrated iron(III) oxide and releases H+ ions, making the resulting solution acidic.

For example, the reaction between iron, oxygen, and water can be represented by the following equations:

Iron + Oxygen → Iron(III) Oxide

Fe + O2 → Fe2O3

Iron(III) Oxide + Water → Hydrated Iron(III) Oxide + Acid

Fe2O3 + xH2O → Fe2O3·xH2O + H+

Therefore, it is clear that the formation of rust is an example of the formation of an acidic oxide.

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The transition metal that is known for its multiple colorful oxidation states and compounds used in pigments and paints is copper (Cu). Copper is an element that belongs to the transition metal group in the periodic table. Transition metals are known for their ability to have multiple oxidation states, meaning they can gain or lose different numbers of electrons when forming chemical compounds. What makes copper particularly interesting is that it can form compounds with a range of oxidation states, including +1, +2, and +3. Each of these oxidation states gives copper a unique color, and this is why it is commonly used in pigments and paints to achieve a variety of vibrant hues. In its +1 oxidation state, copper compounds appear as a pale blue color. This form of copper is often called "cuprous" and is used in the production of blue pigments. One example is Egyptian blue, which was widely used in ancient artwork. In its +2 oxidation state, copper compounds have a greenish color. This is the most common oxidation state for copper and is responsible for the green patina that forms on copper surfaces, such as statues and roofs, over time. It is also used in the production of green pigments, including verdigris. Lastly, in its +3 oxidation state, copper compounds can appear in various shades of blue and green. This oxidation state is less common but still plays a role in the production of pigments and paints. Overall, the ability of copper to exhibit multiple colorful oxidation states makes it a highly desirable choice for creating a wide range of pigments and paints that add vibrancy and visual appeal to various artistic and decorative applications.

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The main environmental concern associated with sulfur dioxide emissions is the formation of acid rain.

When sulfur dioxide (SO2) is released into the atmosphere, it reacts with oxygen and water vapor to form sulfuric acid (H2SO4). This acid then falls back to the Earth's surface as acid rain.

Acid rain can have damaging effects on the environment, including lakes, forests, and buildings. It can make water bodies more acidic, which harms aquatic plants and animals. It can also damage trees and vegetation, making it difficult for them to grow and survive. In addition, acid rain can corrode buildings, statues, and other structures made of stone or metal.

So, the main environmental concern associated with sulfur dioxide emissions is the formation of acid rain, which can have destructive impacts on ecosystems and man-made structures.

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In the given reaction, Zn reacts with CuSO4 to form ZnSO4 and Cu. To identify the reducing agent in this reaction, we need to understand the concept of oxidation and reduction. Oxidation is the loss of electrons, while reduction is the gain of electrons. In any redox reaction, there is an oxidizing agent (which causes oxidation) and a reducing agent (which causes reduction). Let's analyze the reaction: Zn + CuSO4 → ZnSO4 + Cu In this reaction, Zn is being oxidized because it loses two electrons to form Zn2+ ions in ZnSO4. On the other hand, Cu2+ ions in CuSO4 are being reduced because they gain two electrons to form Cu atoms. The reducing agent is the species that causes the reduction to occur. In this reaction, Zn is the reducing agent because it gives away its two electrons, causing the Cu2+ ions to be reduced to Cu atoms. Therefore, the reducing agent in this reaction is **Zinc (Zn)**.

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In the electrochemical series, also known as the reactivity series, Sodium is placed at the top. The electrochemical series is a list of elements in the order of their standard electrode potentials (or redox potentials). Elements at the top of the series are more reactive and have a greater tendency to lose electrons and form positive ions.

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The molecular geometry of a molecule with three bonding pairs and no lone pairs around the central atom is trigonal planar. In a molecule, the arrangement of atoms around the central atom determines its molecular geometry. In this case, we have three bonding pairs around the central atom. To determine the molecular geometry, we use the valence shell electron pair repulsion (VSEPR) theory. According to this theory, electron pairs (both bonding and lone pairs) will arrange themselves in such a way as to minimize repulsion between them. In a trigonal planar arrangement, the three bonding pairs are arranged in a flat plane, with each bond angle being 120 degrees. This means that the central atom is surrounded by three other atoms in a triangular shape. The other options mentioned, such as tetrahedral, linear, and octahedral, do not apply to this particular scenario because they involve different numbers of bonding pairs and/or lone pairs. In summary, a molecule with three bonding pairs and no lone pairs around the central atom has a trigonal planar molecular geometry.

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The unit of temperature that should be used when applying the ideal gas law is Kelvin (K).

The ideal gas law is a mathematical relationship that describes the behavior of gases under various conditions. It states that for a given amount of gas, the pressure (P), volume (V), and temperature (T) are related by the equation:

PV = nRT

Where: - P is the pressure of the gas - V is the volume of the gas - n is the number of moles of gas - R is the ideal gas constant - T is the temperature in Kelvin

Using Kelvin as the unit of temperature in the ideal gas law is important because Kelvin is an absolute temperature scale. Unlike Fahrenheit and Celsius, which have arbitrary zero points, Kelvin has a zero point at absolute zero, the lowest possible temperature.

Since temperature is proportional to the average kinetic energy of gas particles, it is essential to use an absolute temperature scale when applying the ideal gas law. By using Kelvin, we can ensure that temperature is measured relative to absolute zero, providing a more accurate representation of the gas particles' motion and behavior.

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The IUPAC name for the compound CCl4 is tetrachloromethane

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Crude oil is composed of various hydrocarbons, which are organic compounds made up of hydrogen and carbon atoms. Hydrocarbons are the primary constituents of crude oil. They can vary in size and structure, giving rise to different components of crude oil. Out of the options given, **methane** is a primary constituent of crude oil. Methane is the simplest hydrocarbon and is commonly known as natural gas. It consists of one carbon atom bonded to four hydrogen atoms (CH4). While methane is primarily associated with natural gas, it can also be found as a component of crude oil. Pentane, ethanol, and heptane are also hydrocarbons but are not considered primary constituents of crude oil. Pentane and heptane are both hydrocarbons composed of five and seven carbon atoms respectively, while ethanol is an alcohol composed of two carbon atoms, six hydrogen atoms, and one oxygen atom. To summarize, the primary constituent of crude oil is **methane**, which is a simple hydrocarbon consisting of one carbon atom and four hydrogen atoms.

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The valency of an element is a measure of its ability to combine with other elements to form compounds. It is determined by the number of electrons an atom can gain, lose, or share in order to achieve a stable electronic configuration.

In the given electronic configuration 2, 8, 7, the element has a total of 17 electrons. In order to achieve a stable electronic configuration, the element needs to either gain one electron to complete its outermost shell or lose seven electrons to empty its outermost shell.

The valency of an element is typically determined by the number of electrons in its outermost shell, also known as the valence shell. In this case, the element has 7 electrons in its valence shell, which means it needs to gain one electron to achieve a stable configuration.

Therefore, the valency of the element with the electronic configuration 2, 8, 7 is 1, as it needs to gain one electron to achieve stability.

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The type of salt found in antacid medications to relieve heartburn and indigestion is magnesium chloride.

Magnesium chloride is used as an active ingredient in antacids because it has the ability to neutralize excess stomach acid. When you have heartburn or indigestion, it means that there is too much acid in your stomach, causing discomfort and a burning sensation.

Magnesium chloride works by reacting with the excess stomach acid to form magnesium hydroxide. This compound, magnesium hydroxide, is a strong base that can effectively neutralize the acid, reducing the symptoms of heartburn and indigestion.

By taking antacid medications that contain magnesium chloride, you can help to balance the acidity in your stomach and provide relief from the discomfort caused by excess acid.

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The common name for ethanoic acid is acetic acid.

Acetic acid is a clear, colorless liquid with a strong, pungent odor. It is a weak acid commonly found in vinegar, giving it its sour taste and distinct smell. Acetic acid is also used in many industries, such as food production, pharmaceuticals, and cleaning products.

The name "acetic acid" is derived from the Latin word "acetum," which means vinegar. This is because acetic acid is the main component of vinegar.

In summary, the common name for ethanoic acid is acetic acid, which is a weak acid found in vinegar and used in various industries.

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The molar mass of water (H2O) is 18 g/mol.

To understand why, we need to look at the atomic masses of the elements present in water.

The atomic mass of hydrogen (H) is approximately 1 g/mol, and the atomic mass of oxygen (O) is approximately 16 g/mol.

In the water molecule (H2O), there are two hydrogen atoms and one oxygen atom.

To calculate the molar mass of water, we multiply the number of atoms of each element by its atomic mass and add them together.

For hydrogen: 2 atoms × 1 g/mol = 2 g/mol

For oxygen: 1 atom × 16 g/mol = 16 g/mol

Adding these two values gives us a total of 18 g/mol.

Therefore, the molar mass of water (H2O) is 18 g/mol.

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An element with an atomic number of 8 and a mass number of 16 has 8 neutrons.

Let's break down the information to understand why.

The atomic number of an element tells you the number of protons in its nucleus. In this case, the element has an atomic number of 8, which means it has 8 protons.

The mass number of an element is the sum of its protons and neutrons. In this case, the mass number is 16.

To calculate the number of neutrons, we subtract the atomic number from the mass number: Number of Neutrons = Mass Number - Atomic Number

So, in this case, the number of neutrons would be: 16 (mass number) - 8 (atomic number) = 8 neutrons.

Therefore, the element in question has 8 neutrons.

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The contact process is used for the industrial production of sulfuric acid (H2SO4).

Sulfuric acid is a very important chemical that is widely used in various industries. It serves as a key raw material for the production of fertilizers, detergents, dyes, and many other products.

The contact process is the main method used to produce sulfuric acid on a large scale. The process involves the conversion of sulfur dioxide (SO2) into sulfur trioxide (SO3), which is then reacted with water to produce sulfuric acid. The reaction between sulfur dioxide and oxygen occurs in the presence of a catalyst, typically vanadium pentoxide (V2O5).

Here is a simplified explanation of the steps involved in the contact process:

1. Burning sulfur or sulfide ores: The process starts with burning sulfur or sulfide ores to produce sulfur dioxide gas (SO2). Alternatively, sulfur dioxide can be obtained from the purification of natural gas or as a byproduct from other industrial processes.

2. Conversion of sulfur dioxide to sulfur trioxide: The sulfur dioxide gas is then oxidized to sulfur trioxide gas by passing it over a catalyst, which is usually vanadium pentoxide (V2O5). This step takes place at a high temperature, typically around 450-500 degrees Celsius.

3. Absorption of sulfur trioxide in sulfuric acid: The sulfur trioxide gas obtained in the previous step is then passed into a tower containing concentrated sulfuric acid. The two substances react to form oleum, which is a solution containing sulfuric acid and excess sulfur trioxide.

4. Dilution of oleum with water: The oleum is then diluted with water to produce the final product, which is sulfuric acid. The dilution process also generates a large amount of heat, which is typically recovered and used in other parts of the industrial plant.

Overall, the contact process allows for the efficient and large-scale production of sulfuric acid, which is an essential chemical in various industrial processes.

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Fluorine is a halogen that is a gas at room temperature and is pale yellow in color. Halogens are a group in the periodic table consisting of five chemically related elements: fluorine (F), chlorine (Cl), bromine (Br), iodine (I), and astatine (At). Among these, only Fluorine and Chlorine are gases at room temperature, but Chlorine is greenish-yellow, not pale yellow.

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The trace gas in the atmosphere that plays a significant role in the greenhouse effect is carbon dioxide.

The greenhouse effect is a natural process that helps to regulate the Earth's temperature. When sunlight reaches the Earth's surface, some of it is absorbed and warms the planet. However, some of this heat is also radiated back into space.

Greenhouse gases, such as carbon dioxide, trap some of this heat and prevent it from escaping into space. They act like a blanket around the Earth, keeping it warm. Without these greenhouse gases, the Earth would be much colder and life as we know it would not be possible.

However, human activities, such as burning fossil fuels like coal, oil, and natural gas, have been increasing the concentration of carbon dioxide in the atmosphere. This excessive amount of carbon dioxide has enhanced the greenhouse effect, leading to global warming.

Global warming is the long-term increase in Earth's average temperature due to the increased levels of greenhouse gases. It is causing changes in climate patterns, melting of polar ice caps, rising sea levels, and extreme weather events.

So, in summary, carbon dioxide is the trace gas in the atmosphere that plays a significant role in the greenhouse effect and contributes to global warming.

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The blue litmus paper turning red when dipped into a solution indicates that the solution is acidic.

Litmus paper is a commonly used indicator to determine the acidity or alkalinity of a solution. It undergoes a color change depending on the nature of the solution it is exposed to. Blue litmus paper is specifically used to test for acidity. In an acidic solution, which has a high concentration of hydrogen ions (H+), the blue litmus paper reacts with the hydrogen ions. This reaction causes the litmus paper to change from blue to red. This color change is a clear indication that the solution being tested is acidic in nature. Therefore, in this scenario, since the blue litmus paper turns red when dipped into the solution, it confirms that the solution is acidic. It is important to note that this indicates the nature of the solution and not a fault in the litmus paper itself.

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Hematite (Fe2 ${}_2$O3 ${}_3$) is the principal ore of iron and is widely mined for the extraction of iron metal.

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The lanthanides and actinides are located in the f-block of the periodic table.

The periodic table is organized into blocks based on the electron configuration of the elements. The f-block elements are located at the bottom of the periodic table, separated from the rest of the elements.

The lanthanides and actinides are a group of elements that have similar properties and electron configurations. They are also known as the "rare earth elements." These elements have electrons filling the 4f and 5f orbitals, hence they are placed in the f-block.

The f-block elements are very important in many scientific and technological applications. They are used in the production of magnets, catalysts, high-strength alloys, and various electronic devices. Some lanthanides and actinides are also used in medical imaging and cancer treatments.

Overall, the f-block elements play a crucial role in various fields of science and technology, and their placement in the periodic table helps to highlight their unique properties and characteristics.

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A colloid is a type of mixture where tiny particles of one substance are dispersed evenly throughout another substance. The particles in a colloid are larger than the molecules in a solution, which allows them to scatter light and give the mixture a cloudy or opaque appearance. Now let's analyze each option to determine which one is an example of a colloid:

1. Milk: Milk is an example of a colloid. It consists of tiny fat globules (particles) dispersed throughout a watery substance. When light shines through milk, it scatters off of the fat globules, giving it a cloudy appearance.

2. Orange juice: Orange juice is not an example of a colloid. It is a homogenous mixture of water and dissolved molecules, such as sugars and vitamins. The particles in orange juice are too small to scatter light.

3. Saltwater: Saltwater is a solution, not a colloid. It consists of salt (solute) dissolved in water (solvent). In a solution, the particles are very small and evenly distributed, and they do not scatter light.

4. Sugar dissolved in water: Sugar dissolved in water is also a solution, not a colloid. The sugar particles are molecular in size and are completely dispersed in the water.

In conclusion, milk is the only option that is an example of a colloid. The tiny fat globules in milk are larger than the molecules in a solution, causing them to scatter light and give the mixture its cloudy appearance.

Answer Details

The name of the process by which ammonia is produced on an industrial scale is called the Haber process. The Haber process is a very important chemical process that allows the production of ammonia from nitrogen and hydrogen gases. It was developed by Fritz Haber and Carl Bosch in the early 20th century and is still widely used today. In the Haber process, nitrogen gas (N2) from the air is combined with hydrogen gas (H2) obtained from natural gas or other sources. These gases are then reacted under high pressure (around 200 atmospheres) and with the help of a catalyst, usually made of iron, to form ammonia (NH3). The reaction can be represented by the following equation: N2 + 3H2 → 2NH3 The Haber process is carried out at high pressure to increase the yield of ammonia, as the reaction is favored by higher pressure. The catalyst helps to speed up the reaction and increase the efficiency of the process. Ammonia is an important chemical compound used in the production of fertilizers, cleaning products, and various other industrial processes. The Haber process plays a crucial role in meeting the global demand for ammonia and enabling the production of these essential products on a large scale. Therefore, the correct answer is the Haber process.