knowt logoknowt logo
HomeExploreExamsBlog
knowt logoKnowt
Rating
5.0(2)
Exam Icon
Take a practice test
Flashcard Icon
undefined Flashcards
0.0(0)

Studied by 0 people

Tags

Physical Science

science

earth science

physical science

chemical changes

describing chemical reactions

chemical equations

writing chemical equations

classifying  chemical reactions

reaction rates and energy

conservation of mass

balanced equations

9th

Explore Top Notes
Developmental Psych Chapter 17
noteNote
studied byStudied by 9 people
5.0 Stars(1)
Chapter 5 - Demand
noteNote
studied byStudied by 7 people
5.0 Stars(1)
Bio Chapter 2
noteNote
studied byStudied by 6 people
5.0 Stars(2)
Chapter 16 - Aldehydes and Ketones
noteNote
studied byStudied by 11 people
5.0 Stars(1)
AP World History Unit 6 - Lesson 6.6
noteNote
studied byStudied by 14 people
5.0 Stars(1)
Chapter 3: Sentence and Paragraph Order
noteNote
studied byStudied by 25 people
5.0 Stars(1)
knowt logo

Chapter 23: Chemical Reactions 

Section 1: Chemical Changes

  • Describing Chemical Reactions

    • Chemical Reaction: a change in which one or more substances are converted into new substances.

    • Reactants: The substances that react

    • Products: The new substances produced

    • When chemical reactions occur, new compounds form when bonds between atoms in the reactants break and new bonds form.

    • An atomic nucleus changes only when nuclear decay or a nuclear reaction, such as nuclear fission or fusion, occurs.

    • The energy released by a nuclear reaction is millions of times greater than the energy released by a chemical reaction.

    • Different parts of the atom are used in chemical and nuclear reactions.

  • Conservation of Mass

    • When Lavoisier demonstrated the law of conservation of mass, he set the field of chemistry on its modern path.

    • Lavoisier also pioneered early experimentation on the biological phenomena of respiration and metabolism that contributed early milestones in the study of biochemistry, medicine, and even sports medicine.'

    • Antoine Lavoisier’s work led him to the conclusion that language terminology would be critical to communicate novel scientific ideas.

    • One of the questions that motivated Lavoisier was the mystery of exactly what happened when substances changed form.

    • When he determined the mass of the liquid mercury and gas, their combined masses were exactly the same as the mass of the red powder he had started with.

    • Lavoisier also established that the gas produced by heating mercury(II) oxide, which we call oxygen, was a component of air. He did this by heating mercury metal with air and saw that a portion of the air combined to give red mercury(II) oxide.

  • Writing Equations

    • Many words are needed to state all the important information.

    • Chemical Equation: a way to describe a chemical reaction using chemical formulas and other symbols.

    • On the left side of the equation are the reactants. On the right side of the equation are the products.

  • Unit Managers

    • Knowing the number of units of reactants enables chemists to add the correct amounts of reactants to a reaction.

    • Also, these units, or coefficients, tell them exactly how much product will form.

Section 2: Chemical Equations

  • Balanced Equations

    • Mercury metal forms when mercury oxide is heated. Because mercury is poisonous, this reaction is never performed in a classroom laboratory.

    • The formulas in a chemical equation must accurately represent the compounds that react.

    • Balanced Chemical Equation: The balancing process involves changing coefficients in a reaction

    • Finding out which coefficients to use to balance an equation is often a trial-and-error process

Section 3: Classifying Chemical Reactions

  • Types of Reactions

    • If you have ever observed something burning, you have observed a combustion reaction.

    • Combustion Reaction: occurs when a substance reacts with oxygen to produce energy in the form of heat and light.

      • Combustion reactions also produce one or more products that contain the elements in the reactants.

      • Many combustion reactions also will fit into other categories of reactions.

    • Synthesis Reaction: two or more substances combine to form another substance.

      • The generalized formula for this reaction type is as follows: A + B → AB.

    • Decomposition Reaction: occurs when one substance breaks down, or decomposes, into two or more substances.

      • The general formula for this type of reaction can be expressed as follows: AB → A + B.

      • Most decomposition reactions require the use of heat, light, or electricity.

      • Water decomposes into hydrogen and oxygen when an electric current is passed through it. A small amount of sulfuric acid is added to increase conductivity.

    • Single-Displacement Reaction: When one element replaces another element in a compound

      • Single-displacement reactions are described by the general equation A + BC → AC + B.

      • Copper in a wire replaces silver in silver nitrate, forming a blue-tinted solution of copper(II) nitrate.

      • Sometimes single-displacement reactions can cause problems.

      • Solid barium sulfate is formed from the reaction of two solutions.

    • A metal can replace any metal below it on the list but not above it.

    • Double-Displacement Reaction: the positive ion of one compound replaces the positive ion of the other to form two new compounds.

      • A double-displacement reaction takes place if a precipitate, water, or a gas forms when two ionic compounds in solution are combined.

      • A precipitate is an insoluble compound that comes out of solution during this type of reaction.

      • The generalized formula for this type of reaction is as follows: AB + CD → AD + CB.

    • One characteristic that is common to many chemical reactions is the tendency of the substances to lose or gain electrons.

    • Chemists use the term oxidation to describe the loss of electrons and the term reduction to describe the gain of electrons.

    • The cause and effect of oxidation and reduction can be taken one step further by describing the substances after the electron transfer.

    • The substance that gains an electron or electrons obviously becomes more negative, so we say it is reduced.

Section 4: Reaction Rates and Energy

  • Chemical Reactions and Energy

    • When its usefulness is over, a building is sometimes demolished using dynamite. Dynamite charges must be placed carefully so that the building collapses inward, where it cannot harm people or property.

    • All chemical reactions release or absorb energy. This energy can take many forms, such as heat, light, sound, or electricity.

    • According to the law of conservation of energy, energy cannot be created or destroyed, but can only change form.

    • In compounds, chemical potential energy is stored in chemical bonds between atoms.

  • Activation Energy: The minimum amount of energy needed to start a reaction.

    • In order to form new bonds, atoms have to be close together.

    • If there is not enough energy, the reaction will not start.

    • Activation energy, which differs from reaction to reaction, is required for both exothermic and endothermic reactions.

  • Endergonic Reactions

    • Sometimes a chemical reaction requires more energy to break bonds than is released when new ones are formed. These reactions are called endergonic reactions.

    • The energy absorbed can be in the form of light, heat, or electricity.

    • Endothermic Reaction: When the energy needed is in the form of heat

      • It also can describe physical changes.

      • Some reactions are so endothermic that they can cause water to freeze.

      • As an endothermic reaction happens, such as the reaction of barium hydroxide and ammonium chloride, energy from the surrounding environment is absorbed, causing a cooling effect. Here, the reaction absorbs so much heat that a drop of water freezes and the beaker holding the reaction sticks to the wood.

    • With an endothermic reaction, the chemical reaction will not take place unless energy is added.

    • With an endothermic reaction, the reactants have a lower energy level than the products. The reactants must overcome the activation energy barrier in order to form new products.

  • Exergonic Reactions

    • Chemical reactions that release energy are called exergonic reactions

      • In these reactions, less energy is required to break the original bonds than is released when new bonds are formed.

      • Glow sticks contain three different chemicals—an ester and a dye in the outer section and hydrogen peroxide in a center glass tube. Bending the stick breaks the tube and mixes the three components. The energy released is in the form of visible light.

    • Exothermic Reaction: When the energy given off in a reaction is primarily in the form of heat

      • Exothermic reactions provide most of the power used in homes and industries.

      • The energy diagram for an exothermic reaction is the reverse of an endothermic reaction. With an exothermic reaction, the products have less stored energy than the reactants.

      • In an exothermic reaction, molecules have enough energy to overcome the activation energy barrier. Energy is released with the formation of new products.

  • Chemical Reaction Rates

    • According to the kinetic theory of matter, atoms and molecules are always moving.

    • Rate of Reaction: the speed at which reactants are consumed and products are produced in a given reaction.

    • Reaction rate is important in the manufacturing industry because the faster the product can be made, the less it usually costs.

    • Energy is needed by atoms and molecules to break old bonds and to form new ones.

      • One way to increase the activation energy is to add heat or increase the temperature.

      • A chemical reaction will go faster at higher temperature and slower at lower temperature

    • The closer atoms and molecules are to each other, the greater the chance of collision. The amount of substance present in a certain volume is called its concentration.

      • Increasing the concentration of a substance increases the reaction rate.

    • Only atoms or molecules in the outer layer of a substance can collide with other reactants.

      • When a substance is finely divided, it has a larger surface area than when it was whole

      • Increasing the surface area increases the chance for collisions, which will increase the reaction rate.

    • Agitation or stirring is a physical process that allows reactants to mix.

      • A low stirring rate will slow the reaction due to fewer collisions.

      • Chemical reactions can be controlled by agitation.

    • Another way to influence the reaction rate is with pressure

      • By increasing the pressure of gases, molecules have less room to move about and the concentration of the reactants increases.

    • Catalyst: substance that speeds up a chemical reaction without being permanently changed itself.

      • When you add a catalyst to a reaction, the mass of the product that is formed remains the same, but it will form more rapidly.

      • A catalyst lowers the activation energy of the reaction.

    • Inhibitors: Substances that are used to slow down a chemical reaction

      • One thing to remember when thinking about catalysts and inhibitors is that they do not change the amount of product produced.

      • They only change the rate of production. Catalysts increase the rate and inhibitors decease the rate.

MK
homeHomeknowt breadcrumb
Science
knowt breadcrumb
Physical Science

Chapter 23: Chemical Reactions 

Section 1: Chemical Changes

  • Describing Chemical Reactions

    • Chemical Reaction: a change in which one or more substances are converted into new substances.

    • Reactants: The substances that react

    • Products: The new substances produced

    • When chemical reactions occur, new compounds form when bonds between atoms in the reactants break and new bonds form.

    • An atomic nucleus changes only when nuclear decay or a nuclear reaction, such as nuclear fission or fusion, occurs.

    • The energy released by a nuclear reaction is millions of times greater than the energy released by a chemical reaction.

    • Different parts of the atom are used in chemical and nuclear reactions.

  • Conservation of Mass

    • When Lavoisier demonstrated the law of conservation of mass, he set the field of chemistry on its modern path.

    • Lavoisier also pioneered early experimentation on the biological phenomena of respiration and metabolism that contributed early milestones in the study of biochemistry, medicine, and even sports medicine.'

    • Antoine Lavoisier’s work led him to the conclusion that language terminology would be critical to communicate novel scientific ideas.

    • One of the questions that motivated Lavoisier was the mystery of exactly what happened when substances changed form.

    • When he determined the mass of the liquid mercury and gas, their combined masses were exactly the same as the mass of the red powder he had started with.

    • Lavoisier also established that the gas produced by heating mercury(II) oxide, which we call oxygen, was a component of air. He did this by heating mercury metal with air and saw that a portion of the air combined to give red mercury(II) oxide.

  • Writing Equations

    • Many words are needed to state all the important information.

    • Chemical Equation: a way to describe a chemical reaction using chemical formulas and other symbols.

    • On the left side of the equation are the reactants. On the right side of the equation are the products.

  • Unit Managers

    • Knowing the number of units of reactants enables chemists to add the correct amounts of reactants to a reaction.

    • Also, these units, or coefficients, tell them exactly how much product will form.

Section 2: Chemical Equations

  • Balanced Equations

    • Mercury metal forms when mercury oxide is heated. Because mercury is poisonous, this reaction is never performed in a classroom laboratory.

    • The formulas in a chemical equation must accurately represent the compounds that react.

    • Balanced Chemical Equation: The balancing process involves changing coefficients in a reaction

    • Finding out which coefficients to use to balance an equation is often a trial-and-error process

Section 3: Classifying Chemical Reactions

  • Types of Reactions

    • If you have ever observed something burning, you have observed a combustion reaction.

    • Combustion Reaction: occurs when a substance reacts with oxygen to produce energy in the form of heat and light.

      • Combustion reactions also produce one or more products that contain the elements in the reactants.

      • Many combustion reactions also will fit into other categories of reactions.

    • Synthesis Reaction: two or more substances combine to form another substance.

      • The generalized formula for this reaction type is as follows: A + B → AB.

    • Decomposition Reaction: occurs when one substance breaks down, or decomposes, into two or more substances.

      • The general formula for this type of reaction can be expressed as follows: AB → A + B.

      • Most decomposition reactions require the use of heat, light, or electricity.

      • Water decomposes into hydrogen and oxygen when an electric current is passed through it. A small amount of sulfuric acid is added to increase conductivity.

    • Single-Displacement Reaction: When one element replaces another element in a compound

      • Single-displacement reactions are described by the general equation A + BC → AC + B.

      • Copper in a wire replaces silver in silver nitrate, forming a blue-tinted solution of copper(II) nitrate.

      • Sometimes single-displacement reactions can cause problems.

      • Solid barium sulfate is formed from the reaction of two solutions.

    • A metal can replace any metal below it on the list but not above it.

    • Double-Displacement Reaction: the positive ion of one compound replaces the positive ion of the other to form two new compounds.

      • A double-displacement reaction takes place if a precipitate, water, or a gas forms when two ionic compounds in solution are combined.

      • A precipitate is an insoluble compound that comes out of solution during this type of reaction.

      • The generalized formula for this type of reaction is as follows: AB + CD → AD + CB.

    • One characteristic that is common to many chemical reactions is the tendency of the substances to lose or gain electrons.

    • Chemists use the term oxidation to describe the loss of electrons and the term reduction to describe the gain of electrons.

    • The cause and effect of oxidation and reduction can be taken one step further by describing the substances after the electron transfer.

    • The substance that gains an electron or electrons obviously becomes more negative, so we say it is reduced.

Section 4: Reaction Rates and Energy

  • Chemical Reactions and Energy

    • When its usefulness is over, a building is sometimes demolished using dynamite. Dynamite charges must be placed carefully so that the building collapses inward, where it cannot harm people or property.

    • All chemical reactions release or absorb energy. This energy can take many forms, such as heat, light, sound, or electricity.

    • According to the law of conservation of energy, energy cannot be created or destroyed, but can only change form.

    • In compounds, chemical potential energy is stored in chemical bonds between atoms.

  • Activation Energy: The minimum amount of energy needed to start a reaction.

    • In order to form new bonds, atoms have to be close together.

    • If there is not enough energy, the reaction will not start.

    • Activation energy, which differs from reaction to reaction, is required for both exothermic and endothermic reactions.

  • Endergonic Reactions

    • Sometimes a chemical reaction requires more energy to break bonds than is released when new ones are formed. These reactions are called endergonic reactions.

    • The energy absorbed can be in the form of light, heat, or electricity.

    • Endothermic Reaction: When the energy needed is in the form of heat

      • It also can describe physical changes.

      • Some reactions are so endothermic that they can cause water to freeze.

      • As an endothermic reaction happens, such as the reaction of barium hydroxide and ammonium chloride, energy from the surrounding environment is absorbed, causing a cooling effect. Here, the reaction absorbs so much heat that a drop of water freezes and the beaker holding the reaction sticks to the wood.

    • With an endothermic reaction, the chemical reaction will not take place unless energy is added.

    • With an endothermic reaction, the reactants have a lower energy level than the products. The reactants must overcome the activation energy barrier in order to form new products.

  • Exergonic Reactions

    • Chemical reactions that release energy are called exergonic reactions

      • In these reactions, less energy is required to break the original bonds than is released when new bonds are formed.

      • Glow sticks contain three different chemicals—an ester and a dye in the outer section and hydrogen peroxide in a center glass tube. Bending the stick breaks the tube and mixes the three components. The energy released is in the form of visible light.

    • Exothermic Reaction: When the energy given off in a reaction is primarily in the form of heat

      • Exothermic reactions provide most of the power used in homes and industries.

      • The energy diagram for an exothermic reaction is the reverse of an endothermic reaction. With an exothermic reaction, the products have less stored energy than the reactants.

      • In an exothermic reaction, molecules have enough energy to overcome the activation energy barrier. Energy is released with the formation of new products.

  • Chemical Reaction Rates

    • According to the kinetic theory of matter, atoms and molecules are always moving.

    • Rate of Reaction: the speed at which reactants are consumed and products are produced in a given reaction.

    • Reaction rate is important in the manufacturing industry because the faster the product can be made, the less it usually costs.

    • Energy is needed by atoms and molecules to break old bonds and to form new ones.

      • One way to increase the activation energy is to add heat or increase the temperature.

      • A chemical reaction will go faster at higher temperature and slower at lower temperature

    • The closer atoms and molecules are to each other, the greater the chance of collision. The amount of substance present in a certain volume is called its concentration.

      • Increasing the concentration of a substance increases the reaction rate.

    • Only atoms or molecules in the outer layer of a substance can collide with other reactants.

      • When a substance is finely divided, it has a larger surface area than when it was whole

      • Increasing the surface area increases the chance for collisions, which will increase the reaction rate.

    • Agitation or stirring is a physical process that allows reactants to mix.

      • A low stirring rate will slow the reaction due to fewer collisions.

      • Chemical reactions can be controlled by agitation.

    • Another way to influence the reaction rate is with pressure

      • By increasing the pressure of gases, molecules have less room to move about and the concentration of the reactants increases.

    • Catalyst: substance that speeds up a chemical reaction without being permanently changed itself.

      • When you add a catalyst to a reaction, the mass of the product that is formed remains the same, but it will form more rapidly.

      • A catalyst lowers the activation energy of the reaction.

    • Inhibitors: Substances that are used to slow down a chemical reaction

      • One thing to remember when thinking about catalysts and inhibitors is that they do not change the amount of product produced.

      • They only change the rate of production. Catalysts increase the rate and inhibitors decease the rate.