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Question 1 Report
What is the atomic number of aluminium?
Answer Details
The atomic number of aluminium is 13.
Each atom of an element is uniquely identified by its atomic number. The atomic number represents the number of protons found in the nucleus of an atom. In the case of aluminium, it has 13 protons in its nucleus.
The atomic number is a fundamental property of an element and helps in organizing the elements in the periodic table. It provides information about the position of the element in the periodic table and its chemical characteristics.
In summary, aluminium has an atomic number of 13, which signifies that it has 13 protons in its nucleus.
Question 2 Report
The lanthanides and actinides are located in which block of the periodic table?
Answer Details
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.
Question 3 Report
Which of the following alkanes has a straight-chain structure?
Answer Details
A straight-chain structure in organic chemistry refers to a carbon chain where the carbon atoms are connected in a linear or straight fashion, without any branches or loops.
Among the given options, the alkane that has a straight-chain structure is butane (C4H10).
Butane is composed of four carbon atoms (C4) and ten hydrogen atoms (H10). Its carbon atoms are arranged in a straight or linear chain without any branches.
In contrast, the other options have structures that deviate from a straight-chain. Cyclopentane (C5H10) forms a ring or cyclical structure, Isobutane (C4H10) has a branch coming off the main chain, and Benzene (C6H6) has a cyclic structure.
In summary, only butane (C4H10) has a straight-chain structure among the given options.
Question 4 Report
Which trace gas in the atmosphere plays a significant role in the greenhouse effect?
Answer Details
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.
Question 5 Report
Balance the following redox reaction:
Fe2
O3
+ CO → Fe + CO2
Answer Details
The balanced equation for the given redox reaction is: Fe2O3 + 3CO → 2Fe + 3CO2 To balance this reaction, we need to make sure that the number of atoms of each element is the same on both sides of the equation. In the reaction, we have Fe, O, and C as the elements. Step 1: Balancing Fe There are 2 Fe atoms on the left side and only 1 Fe atom on the right side. To balance the Fe atoms, we need to put a coefficient in front of Fe on the right side. Hence, the equation becomes: Fe2O3 + 3CO → 2Fe + 3CO2 Step 2: Balancing O There are 3 O atoms in Fe2O3 and 3 O atoms in CO2 on the right side. To balance the O atoms, we need to make sure there are 3 O atoms on the left side as well. So we put a coefficient of 2 in front of Fe2O3: 2Fe2O3 + 3CO → 2Fe + 3CO2 Step 3: Balancing C There are already 3 C atoms on both sides, so no further balancing is needed for C. Now the equation is balanced with 2Fe2O3 + 3CO → 2Fe + 3CO2. So the correct option is: Fe2O3 + 3CO → 2Fe + 3CO2
Question 6 Report
Which type of chemical combination involves the transfer of electrons from one atom to another, resulting in the formation of oppositely charged ions?
Answer Details
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.
Question 7 Report
What is the valency of an element with the electronic configuration 2, 8, 7?
Answer Details
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.
Question 8 Report
At room temperature and standard pressure, chlorine gas is in which state of matter?
Answer Details
At room temperature and standard pressure, chlorine gas is in the state of matter called gas.
In chemistry, there are three main states of matter: solid, liquid, and gas. The state of matter depends on the arrangement and movement of the particles that make up a substance.
Let's consider each state of matter one by one:
Solid: In a solid state, the particles are tightly packed together and have fixed positions. They vibrate in place but do not move around freely. Solids have a definite shape and volume. Examples of solids are a desk, a brick, or a piece of ice.
Liquid: In a liquid state, the particles are more spread out compared to solids. They have some freedom to move, but they still remain close to each other. Liquids can flow and take the shape of the container they are in. However, they still have a definite volume. Examples of liquids are water, milk, or oil.
Gas: In a gas state, the particles are far apart and move freely in all directions. They have much more energy compared to particles in solids or liquids. Gases do not have a definite shape or volume and can expand to fill the entire space they are contained in. Examples of gases are air, oxygen, or carbon dioxide.
Chlorine gas, at room temperature and standard pressure, exists as individual chlorine molecules that are far apart and move freely. Therefore, it is classified as a gas.
Question 9 Report
An element has an atomic number of 8 and a mass number of 16. How many neutrons does this element have?
Answer Details
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.
Question 10 Report
What is the trend for ionization energy across a period in the periodic table?
Answer Details
The trend for ionization energy across a period in the periodic table is that it increases from left to right. Ionization energy is the energy required to remove an electron from an atom or ion. When moving from left to right across a period, the number of protons in the nucleus increases, which means there is a stronger attractive force on the electrons. As a result, it becomes more difficult to remove an electron and the ionization energy increases. Therefore, the correct option is that the ionization energy increases from left to right across a period in the periodic table.
Question 11 Report
What is the sum of the oxidation numbers in a neutral compound?
Answer Details
The sum of the oxidation numbers in a neutral compound is always equal to zero.
Oxidation numbers are assigned to each element in a compound to indicate the redistribution of electrons during a chemical reaction.
The oxidation number represents the charge an atom would have if electrons were transferred completely.
In a neutral compound, the total positive charges must balance the total negative charges. Since electrons are neither gained nor lost in a neutral compound, the sum of the oxidation numbers must equal zero.
Therefore, the answer is 0.
Question 12 Report
What is the IUPAC name for the compound CCl4 ?
Answer Details
The IUPAC name for the compound CCl4 is tetrachloromethane
Question 13 Report
Which separation technique is used to separate different pigments in a mixture based on their affinity for a stationary phase and a mobile phase?
Answer Details
The separation technique used to separate different pigments in a mixture based on their affinity for a stationary phase and a mobile phase is chromatography.
Chromatography is a method that takes advantage of the fact that different substances have different affinities for the components of the mixture. It involves two phases: the stationary phase and the mobile phase.
The stationary phase is a solid or a liquid that does not move, while the mobile phase is a liquid or a gas that moves through or over the stationary phase.
When the mixture is applied to the stationary phase, the pigments begin to separate based on their affinity for each phase. Some pigments may have a higher affinity for the stationary phase, causing them to move more slowly, while others have a higher affinity for the mobile phase, causing them to move more quickly.
As the mobile phase moves through the stationary phase, the individual pigments are carried along at different rates, resulting in their separation. The separated pigments can then be collected and analyzed.
In summary, chromatography is used to separate different pigments in a mixture based on their affinity for a stationary phase and a mobile phase. It exploits the fact that each pigment has a different affinity for the phases, allowing for their separation and analysis.
Question 14 Report
What is the state of matter in which particles are widely spaced and move freely with high kinetic energy?
Answer Details
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.
Question 15 Report
Why is water often referred to as the "universal solvent"?
Answer Details
Water is often referred to as the "universal solvent" because it has the ability to dissolve many different substances. This is primarily due to its polar nature.
When we say water is polar, it means that the water molecule has a slight positive charge at one end (hydrogen) and a slight negative charge at the other end (oxygen). This charge difference creates an attraction between the water molecule and other charged molecules or ions.
Because of its polar nature, water can effectively separate and surround particles or molecules of other substances, causing them to separate and disperse. This is known as dissolving. Water can dissolve many substances, including salts, sugars, acids, and many other organic and inorganic compounds.
The ability of water to dissolve so many different substances is important for several reasons. First, it allows nutrients and minerals to be transported within living organisms, facilitating biochemical reactions necessary for life.
Furthermore, water's ability to dissolve substances enables it to act as a solvent in many chemical reactions, making it essential for many industrial and biological processes. Water acts as a medium in which substances can react, allowing chemical reactions to occur efficiently.
Overall, the combination of water's abundance, essentiality for life, involvement in chemical reactions, and its ability to dissolve a wide variety of substances due to its polar nature is why water is often referred to as the "universal solvent."
Question 16 Report
What is the maximum number of electrons that can occupy the second energy level (n=2)?
Answer Details
The maximum number of electrons that can occupy the second energy level (n=2) is 8 electrons. In simple terms, the energy levels of an atom are like different floors in a building. Each energy level has a maximum capacity to hold a certain number of electrons. The first energy level (n=1) can hold a maximum of 2 electrons, while the second energy level (n=2) can hold a maximum of 8 electrons. To understand why, we need to consider the structure of an atom. At the center of an atom, we have a nucleus containing protons and neutrons. Surrounding the nucleus are energy levels, each represented by an electron shell. The first energy level (n=1) is closest to the nucleus and can hold a maximum of 2 electrons. This level is represented by the 1s orbital. The second energy level (n=2) is the next shell or energy level farther away from the nucleus. It can hold a maximum of 8 electrons. This level is represented by the 2s and 2p orbitals. Electrons fill the energy levels and orbitals starting from the lowest energy level (n=1) and moving towards higher energy levels. The electrons in the second energy level occupy the 2s and 2p orbitals, with the 2s orbital being filled with 2 electrons and the 2p orbitals being filled with 6 electrons (2 electrons in each of the three 2p orbitals). Therefore, the maximum number of electrons that can occupy the second energy level (n=2) is 8 electrons.
Question 17 Report
What is the name of the process by which ammonia is produced on an industrial scale?
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.
Question 18 Report
How many pi (π
) bonds are there in an alkene with six carbon atoms?
Answer Details
In an alkene with six carbon atoms, there are 5 sigma (σ) bonds (single bonds) between the carbon atoms. Additionally, there are 4 pi (π
) bonds associated with the double bonds between the carbon atoms.
Question 19 Report
A blue litmus paper turns red when dipped into a solution. What does this indicate about the solution?
Answer Details
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.Question 20 Report
What unit of temperature should be used when applying the ideal gas law?
Answer Details
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.
Question 21 Report
What happens to the position of equilibrium if a reversible reaction is subjected to a decrease in temperature?
Answer Details
The position of equilibrium shifts to the left.
When a reversible reaction is subjected to a decrease in temperature, the reaction tends to favor the production of heat. This means it moves in the direction that releases heat. By Le Chatelier's principle, which states that a system at equilibrium will adjust in response to a change in conditions, the reaction will shift in the direction that counteracts the decrease in temperature. Since the forward reaction is exothermic (releases heat), shifting to the left allows the reaction to produce more heat in order to compensate for the decrease in temperature. This results in more reactants being formed and fewer products being produced. Therefore, the position of equilibrium shifts to the left because the reaction tries to restore the lost heat and maintain equilibrium.Question 22 Report
Which of the following statements is true for strong electrolytes?
Answer Details
Out of the given statements, the true statement for strong electrolytes is:
They completely dissociate into ions in solution.
Now, let's understand what a strong electrolyte is and why this statement is true.
An electrolyte is a substance that conducts electricity when dissolved in water or melted. Strong electrolytes are substances that completely dissociate or break apart into ions when dissolved in water.
When strong electrolytes dissolve in water, the bonds holding the molecules together are broken and they separate into their individual ions. These ions are then free to move and carry electrical charge, allowing the solution to conduct electricity.
On the other hand, weak electrolytes partially dissociate or break apart into ions when dissolved in water. Not all of the molecules separate into ions, resulting in a lower concentration of ions in the solution and less conductivity of electricity compared to strong electrolytes.
In summary, strong electrolytes completely dissociate into ions in solution, allowing for effective electrical conductivity. This is why the statement "They completely dissociate into ions in solution" is true for strong electrolytes.
Question 23 Report
Which of the following is a unique property of water compared to other liquids?
Answer Details
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.Question 24 Report
Alkynes readily undergo addition reactions with which of the following?
Answer Details
Alkynes readily undergo addition reactions with hydrogen gas (H2) in the presence of a metal catalyst, such as palladium (Pd) or platinum (Pt), to form alkenes.
Question 25 Report
The contact process is used for the industrial production of
Answer Details
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.
Question 26 Report
Chlorine gas is commonly used in the production of which of the following industrial compounds?
Answer Details
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.
Question 27 Report
What is the mass (in grams) of 500 mL of ethanol? (density of ethanol = 0.789 g/mL)
Answer Details
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.
Question 28 Report
Which organic compound is responsible for the characteristic aroma of fruits?
Answer Details
The organic compound responsible for the characteristic aroma of fruits is ester.
Esters are organic compounds that are formed when an alcohol reacts with an organic acid in the presence of a catalyst. They have a pleasant fruity, floral, or sweet smell, which is why they are often used in perfumes and flavorings. Esters are volatile compounds, meaning they easily evaporate and contribute to the aroma of fruits.
On the other hand, alkanes and alkynes are hydrocarbons that do not have a specific aroma. They are odorless and are typically found in substances like petroleum and natural gas.
Amines, although they can have distinct odors, are not primarily responsible for the characteristic aroma of fruits. Amines often have a fishy or ammonia-like smell and are found in substances like rotten eggs or urine.
Therefore, the correct answer is ester, as it is the organic compound that gives fruits their delightful scent.
Question 29 Report
Which group does calcium belong to in the periodic table?
Answer Details
Calcium belongs to the alkaline earth metals group in the periodic table.
The periodic table is a chart that organizes elements based on their properties and atomic number. It consists of rows, called periods, and columns, called groups or families.
The alkaline earth metals group is found in the second column of the periodic table, specifically group 2. This group includes elements such as beryllium, magnesium, calcium, strontium, and barium.
So, why does calcium belong to the alkaline earth metals group? It's because of its characteristics and behavior.
Firstly, alkaline earth metals are highly reactive and relatively soft metals. Calcium, like other elements in this group, readily loses its two outermost electrons to form a positive ion with a +2 charge.
Secondly, alkaline earth metals have similar chemical properties. They all react with water to form alkaline solutions and with non-metals to form compounds.
Lastly, calcium is found abundantly in Earth's crust, mainly as calcium carbonate in limestone and chalk. It is an essential element for living organisms and is involved in various biological processes, such as muscle contraction and bone formation.
In conclusion, calcium belongs to the alkaline earth metals group in the periodic table due to its reactivity, similar chemical properties to other group members, and abundance on Earth.
Question 30 Report
Which of the following compounds is an example of an electrovalent bond?
Answer Details
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.
Question 31 Report
Which of the following is a common laboratory indicator for bases?
Answer Details
A laboratory indicator is a substance that changes color in the presence of an acid or a base. It helps us determine the nature of a solution, whether it is acidic or basic.
Out of the given options, Phenolphthalein is a common laboratory indicator for bases.
Phenolphthalein is a colorless compound that turns pink or purple in the presence of a base. It is widely used because it has a clear and distinct color change, making it easy to identify the presence of a base. When a base is added to a solution containing phenolphthalein, the compound undergoes a chemical reaction and changes its structure, resulting in a change in color.
Methyl orange, on the other hand, is a laboratory indicator for acids. It changes color in the presence of an acid but remains unchanged in the presence of a base.
Bromothymol blue is another laboratory indicator commonly used to test for acids and bases. It turns yellow in the presence of an acid and blue in the presence of a base.
Litmus is a natural dye extracted from lichens. It is a general indicator that turns red in the presence of an acid and blue in the presence of a base.
However, out of the options provided, Phenolphthalein is the specific laboratory indicator commonly used to test for bases.
Question 32 Report
What is eutrophication?
Answer Details
Eutrophication is the excessive growth of algae in water bodies, such as lakes, rivers, and oceans, due to an increase in nutrients in the water. These nutrients, mainly nitrogen and phosphorus, come from various sources including agricultural runoff, wastewater discharge, and soil erosion.
When there is an excess of nutrients in the water, it acts as a fertilizer for algae and other aquatic plants. These plants grow rapidly and form dense colonies on the water surface, resulting in what we commonly call an "algal bloom".
During the algal bloom, the water becomes green or murky and can sometimes emit an unpleasant odor. This excessive growth of algae can have several negative impacts on the aquatic ecosystem.
As the algae die and decompose, they consume a large amount of oxygen from the water, leading to oxygen depletion. This reduction in oxygen levels can be harmful to fish and other organisms that depend on oxygen to survive. It can lead to the death of fish and other aquatic organisms, creating what is known as a "dead zone".
Furthermore, the dense layer of algae on the water surface can block sunlight from penetrating into the water, limiting photosynthesis for other aquatic plants and organisms. This can disrupt the balance of the ecosystem, affecting the biodiversity of the water body.
In summary, eutrophication is caused by an excess of nutrients in the water, leading to the rapid growth of algae and the subsequent negative impacts on oxygen levels and biodiversity in the aquatic ecosystem.
Question 33 Report
The heat of reaction can be determined experimentally using a device called a
Answer Details
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.
Question 34 Report
What is the symbol used to represent an alpha particle?
Answer Details
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.
Question 35 Report
When a substance is oxidized, it
Answer Details
When a substance is oxidized, it loses electrons.
Oxidation is a chemical process in which a substance reacts with another substance or element, resulting in the loss of electrons from the oxidized substance. In other words, the oxidized substance gives away electrons to another substance or element.
This loss of electrons during oxidation is significant because electrons are negatively charged particles that play a crucial role in chemical reactions. By losing electrons, the oxidized substance becomes positively charged or oxidized.
It's important to note that oxidation doesn't necessarily involve the gain of oxygen atoms. While some reactions involving oxidation do include the addition of oxygen, it is not a defining characteristic of oxidation. The key factor is the loss of electrons, regardless of whether oxygen atoms are involved or not.
Question 36 Report
Which of the following mixtures is an example of a colloid?
Answer Details
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.
Question 37 Report
Identify the reducing agent in the following reaction:
Zn + CuSO4
→ ZnSO4
+ Cu
Answer Details
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)**.
Question 38 Report
Which of the following metals is commonly alloyed with copper to make brass?
Answer Details
The metal that is commonly alloyed with copper to make brass is zinc. Brass is an alloy made by combining copper and zinc in varying proportions.
Alloys are materials made by mixing two or more metals together. By combining copper and zinc, we create brass, which has different properties than copper or zinc alone.
Zinc is chosen as the common metal to alloy with copper because it has a lower melting point and is more affordable compared to other metals like iron, nickel, or aluminum. This makes it easier and cheaper to produce brass.
Brass has many useful properties that make it a popular material for various applications. It has good corrosion resistance, making it suitable for use in plumbing fittings and musical instruments. It is also easily malleable, meaning it can be shaped into different forms without breaking.
In conclusion, zinc is commonly alloyed with copper to make brass due to its lower melting point, affordability, and the desirable properties it imparts to the alloy.
Question 39 Report
Answer Details
When an acidic solution is diluted by adding more solvent (usually water), the concentration of hydrogen ions (H+ ) decreases. As a result, the pH of the solution decreases, making it less acidic
Question 40 Report
Isotopes of an element have
Answer Details
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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