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May week 1
[Learning Target: Describe how the strong force attracts nucleons. Relate binding energy and mass defect.
Predict the stability of a nucleus by considering factors such as nuclear size, binding energy, and the ratio of neutrons to protons in the nucleus.]
Do Now
P. 642. Define nucleon, nuclide.
Figure 1. Draw the element's symbol with its atomic number and mass number.
P. 643. Name the force of attraction between the nucleons when they are close to each other.
Explain figure 3. What are quarks?
P. 644. Define mass defect.
Write the formula for the binding energy ore a nucleus.
P. 645. Figure 5: Explain how binding energy is one indicator of nuclear stability.
P. 647. State some rules to help you predict nuclear stability. Only bold sentences.
P. 648: Define radioactivity.
Copy Table 1.
P. 654: Define nuclear fission.
Define chain reaction.
Define critical mass.
Explain Figure 11.
P. 656: Define nuclear fusion
Write the equation of the nuclear reaction in the sun. Explain the process.
Explain figure 13.
P. 657: List some proper ways to dispose the waste from nuclear power.
P. 663: Other uses for Nuclear Chemistry
What does a smoke detector contains?
What is the process used for detecting art forgeries? Explain figure 18.
P. 664: What are some of the uses of nuclear medicine?
P. 665: Copy table 3. Effect of whole-body exposure to a single dose of radiation.
P. 666: List some examples of the single and repeated exposure of nuclear radiation on the body.
[Learning Target: Describe how the strong force attracts nucleons. Relate binding energy and mass defect.
Predict the stability of a nucleus by considering factors such as nuclear size, binding energy, and the ratio of neutrons to protons in the nucleus.]
Do Now
P. 642. Define nucleon, nuclide.
Figure 1. Draw the element's symbol with its atomic number and mass number.
P. 643. Name the force of attraction between the nucleons when they are close to each other.
Explain figure 3. What are quarks?
P. 644. Define mass defect.
Write the formula for the binding energy ore a nucleus.
P. 645. Figure 5: Explain how binding energy is one indicator of nuclear stability.
P. 647. State some rules to help you predict nuclear stability. Only bold sentences.
P. 648: Define radioactivity.
Copy Table 1.
P. 654: Define nuclear fission.
Define chain reaction.
Define critical mass.
Explain Figure 11.
P. 656: Define nuclear fusion
Write the equation of the nuclear reaction in the sun. Explain the process.
Explain figure 13.
P. 657: List some proper ways to dispose the waste from nuclear power.
P. 663: Other uses for Nuclear Chemistry
What does a smoke detector contains?
What is the process used for detecting art forgeries? Explain figure 18.
P. 664: What are some of the uses of nuclear medicine?
P. 665: Copy table 3. Effect of whole-body exposure to a single dose of radiation.
P. 666: List some examples of the single and repeated exposure of nuclear radiation on the body.
May, Week 1
[Learning Target: Describe the nature of the bonds formed by carbon in alkanes, alkenes, alkynes and aromatic compounds, and cyclic compounds. Name simple hydrocarbons from their structural formulas. Name branched hydrocarbons from their
structural formulas.]
P. 680. Define hydrocarbons.
P. 681: Define alkanes (saturated hydrocarbons). Give 2 examples. What is the general formula for alkanes?
Define alkenes (unsaturated hydrocarbons). Give 2 examples. What is the general formula for alkenes?
Define alkynes (unsaturated hydrocarbons). Example in figure 4. What is the general formula for alkynes?
P. 682. Define aromatic hydrocarbons (cyclic hydrocarbons). Give an example.
Draw the three structural formulas of benzene C6H6,
Explain figure 5.
P. 687. Complete the sentence " The names of all alkanes ends with the suffix - ........
Understand how to name the straight-chain alkanes in table 3. Do not copy the table.
P. 688: Complete the sentence " The names of all alkenes ends with the suffix -.........
Complete the sentence " The names of all akynes ends with the suffix- ..........
Understand the names of the unsaturated hydrocarbon in figure 8.
P. 689. Understand the names of the organic compounds.
P. 690. Understand sample problem A. Do practice problem 1.
P. 691. Do practice problem 1.
P. 692: Understand sample problem B. Do practice problem 1.
P. 693: Summarize Table 5: Types of Molecular Models.
P. 694: Draw the two structural formula for Aspirin. Explain the difference.
P. 695: Section Review: Do 6, 7 8, 9 and 10.
P. 705. Do practice problem 38.
P. 706. Do practice problem 50, 51.
[Learning Target: Describe the nature of the bonds formed by carbon in alkanes, alkenes, alkynes and aromatic compounds, and cyclic compounds. Name simple hydrocarbons from their structural formulas. Name branched hydrocarbons from their
structural formulas.]
P. 680. Define hydrocarbons.
P. 681: Define alkanes (saturated hydrocarbons). Give 2 examples. What is the general formula for alkanes?
Define alkenes (unsaturated hydrocarbons). Give 2 examples. What is the general formula for alkenes?
Define alkynes (unsaturated hydrocarbons). Example in figure 4. What is the general formula for alkynes?
P. 682. Define aromatic hydrocarbons (cyclic hydrocarbons). Give an example.
Draw the three structural formulas of benzene C6H6,
Explain figure 5.
P. 687. Complete the sentence " The names of all alkanes ends with the suffix - ........
Understand how to name the straight-chain alkanes in table 3. Do not copy the table.
P. 688: Complete the sentence " The names of all alkenes ends with the suffix -.........
Complete the sentence " The names of all akynes ends with the suffix- ..........
Understand the names of the unsaturated hydrocarbon in figure 8.
P. 689. Understand the names of the organic compounds.
P. 690. Understand sample problem A. Do practice problem 1.
P. 691. Do practice problem 1.
P. 692: Understand sample problem B. Do practice problem 1.
P. 693: Summarize Table 5: Types of Molecular Models.
P. 694: Draw the two structural formula for Aspirin. Explain the difference.
P. 695: Section Review: Do 6, 7 8, 9 and 10.
P. 705. Do practice problem 38.
P. 706. Do practice problem 50, 51.
May Week 2.
[Learning Target: Describe the nature of the bonds formed by carbon in alkanes, alkenes, alkynes and aromatic compounds, and cyclic compounds. Name simple hydrocarbons from their structural formulas. Name branched hydrocarbons from their
structural formulas.]
Do Now
P. 696: Define substitution reaction.
Define addition reaction.
Write the reaction of methane with chlorine (substitution reaction)
P. 697: Write the hydrogenation reaction of oil to form fat.
Write the hydrogenation reaction of benzene.
In figure 10, describe how hydrogenation is used to make butter.
P. 698. Define polymer. Give an example reaction.
In figure 11, explain how plastic wrap is used.
P. 699. Define condensation reaction.
Define elimination reaction.
What is Nylon 66.
Write the condensation reaction between hexane-diamine and adipic acid to produce a polymer.
P. 700: What is PET, and what is it used for?
Write the reaction.
What is the common product for the elimination reaction?
Write the reaction for elimination of water from ethanol.
P. 701: What happens when we add concentrated sulfuric acid to sucrose (figure 14).
P. 702:Table 6. Understand the different recycling codes for plastic products. Which one is more environmental friendly?
P. 709: Answer Standardized Test Prep.
P. 704. Answer 20, 21.
P. 705. Answer 38, 40, 42, 43, 44, 45, 47.
P. 704: Answer 11, 12, 13, 14, 15, 16, 17.
[Learning Target: Describe the nature of the bonds formed by carbon in alkanes, alkenes, alkynes and aromatic compounds, and cyclic compounds. Name simple hydrocarbons from their structural formulas. Name branched hydrocarbons from their
structural formulas.]
Do Now
P. 696: Define substitution reaction.
Define addition reaction.
Write the reaction of methane with chlorine (substitution reaction)
P. 697: Write the hydrogenation reaction of oil to form fat.
Write the hydrogenation reaction of benzene.
In figure 10, describe how hydrogenation is used to make butter.
P. 698. Define polymer. Give an example reaction.
In figure 11, explain how plastic wrap is used.
P. 699. Define condensation reaction.
Define elimination reaction.
What is Nylon 66.
Write the condensation reaction between hexane-diamine and adipic acid to produce a polymer.
P. 700: What is PET, and what is it used for?
Write the reaction.
What is the common product for the elimination reaction?
Write the reaction for elimination of water from ethanol.
P. 701: What happens when we add concentrated sulfuric acid to sucrose (figure 14).
P. 702:Table 6. Understand the different recycling codes for plastic products. Which one is more environmental friendly?
P. 709: Answer Standardized Test Prep.
P. 704. Answer 20, 21.
P. 705. Answer 38, 40, 42, 43, 44, 45, 47.
P. 704: Answer 11, 12, 13, 14, 15, 16, 17.
May Week 3. Carbohydrates and Lipids
[Learning Target: Describe the structure of carbohydrates. Relate the structure of carbohydrates to their role in biological systems. Identify the reactions that lead to the formation and breakdown of carbohydrate polymers. Describe a property that all lipids share. Describe the general amino acid structure. Explain how amino acids form proteins through condensation reactions. Explain the significance of amino-acid side chains to the three-dimensional structure and function of a protein. Describe how enzymes work and how the structure and function of an enzyme is affected by changes in temperature and pH. Relate the structure of nucleic acids to their function as carriers of genetic information. Describe how DNA uses genetic code to control the synthesis of proteins. Describe important gene technologies and their significance.
Do Now
P. 712: Define carbohydrate, monosaccharide, disaccharide, polysaccharide ( give an example).
P. 713: List some of the many functions of carbohydrates.
Draw the structures of glucose and fructose.
P. 715: Copy table 1.
Define condensation reaction.
Define breakdown of carbohydrates.
P. 716: Define lipids. Give examples.
Draw the structure of lipids with the two regions (hydrophilic and hydrophobic).
P. 717: Define proteins.
Define amino acids.
P. 718: Define polypeptide, peptide bond. Give an example.
P. 719: Draw figure 6. List the four different kinds of interaction between side chains on a polypeptide molecule.
P. 720: Table 3. Draw and list the level of protein structure.
P. 721: Figure 7. Explain how amino acids substitution can affect shape.
P. 722: Define enzyme.
Draw figure 6. Explain how enzymes work.
P. 723: Define denature.
P. 725: Define nucleic acids.
Figure 9. Draw the four common nitrogenous bases of nucleic acids.
P. 726: Define DNA.
P. 727: How is the DNA's three dimensional structure?
What are the specific base pairing between the two strands of DNA?
P. 728: What is a DNA replication?
Define gene.
P. 729: Define genetic code.
P. 730: Define gene technology and list the different processes of gene technology.
P. 734: Define photosynthesis.
Explain and draw figure 16.
P. 735: Define chlorophyll.
Write the reaction of photosynthesis.
Why are carbohydrates important?
P. 736: Define respiration.
Write the general equation for respiration.
P. 737: Define ATP.
Write the reaction for hydrolysis of ATP.
Write the reactions for the two stages of cellular respiration.
P. 738: Why is ATP called the energy currency?
Copy table 4.
[Learning Target: Describe the structure of carbohydrates. Relate the structure of carbohydrates to their role in biological systems. Identify the reactions that lead to the formation and breakdown of carbohydrate polymers. Describe a property that all lipids share. Describe the general amino acid structure. Explain how amino acids form proteins through condensation reactions. Explain the significance of amino-acid side chains to the three-dimensional structure and function of a protein. Describe how enzymes work and how the structure and function of an enzyme is affected by changes in temperature and pH. Relate the structure of nucleic acids to their function as carriers of genetic information. Describe how DNA uses genetic code to control the synthesis of proteins. Describe important gene technologies and their significance.
Do Now
P. 712: Define carbohydrate, monosaccharide, disaccharide, polysaccharide ( give an example).
P. 713: List some of the many functions of carbohydrates.
Draw the structures of glucose and fructose.
P. 715: Copy table 1.
Define condensation reaction.
Define breakdown of carbohydrates.
P. 716: Define lipids. Give examples.
Draw the structure of lipids with the two regions (hydrophilic and hydrophobic).
P. 717: Define proteins.
Define amino acids.
P. 718: Define polypeptide, peptide bond. Give an example.
P. 719: Draw figure 6. List the four different kinds of interaction between side chains on a polypeptide molecule.
P. 720: Table 3. Draw and list the level of protein structure.
P. 721: Figure 7. Explain how amino acids substitution can affect shape.
P. 722: Define enzyme.
Draw figure 6. Explain how enzymes work.
P. 723: Define denature.
P. 725: Define nucleic acids.
Figure 9. Draw the four common nitrogenous bases of nucleic acids.
P. 726: Define DNA.
P. 727: How is the DNA's three dimensional structure?
What are the specific base pairing between the two strands of DNA?
P. 728: What is a DNA replication?
Define gene.
P. 729: Define genetic code.
P. 730: Define gene technology and list the different processes of gene technology.
P. 734: Define photosynthesis.
Explain and draw figure 16.
P. 735: Define chlorophyll.
Write the reaction of photosynthesis.
Why are carbohydrates important?
P. 736: Define respiration.
Write the general equation for respiration.
P. 737: Define ATP.
Write the reaction for hydrolysis of ATP.
Write the reactions for the two stages of cellular respiration.
P. 738: Why is ATP called the energy currency?
Copy table 4.
Oxidation, Reduction, Electrochemistry
Read, Take Notes and Check your Understanding.
P. 612: Define Electrochemistry
Explain figure 4
P. 613: Define voltage, electrochemical cell, electrodes, cathode.
Explain figure 5.
Write the cathodic reaction for the copper ion reduced to the atom.
P. 614: Define anode
Explain figure 6.
Write the anodic reaction for zinc atom oxidized to the ion.
P. 615: Write and explain the complete redox reaction for the cell in figure 7.
P. 616: Define galvanic cells
Explain figure 8.
P. 617: Define dry cell. Give an example.
Explain figure 9.
Write the equations at the anode and cathode.
P. 618-619. Define lead-acid batteries. Give an example
Explain figure 10.
Write the equations at the anode and cathode.
P. 619. Define dry cells. Give an example.
Explain figure 11.
Write the equations at the anode and cathode.
P. 620: Corrosion cells. Give an example.
Explain figure 12.
Write the equations at the anode and cathode.
P. 621: List 3 methods to prevent corrosion.
P. 622: What is a voltmeter?
Define standard electrode potential.
P. 627: Define electrolytic cell.
Define electrolysis.
Write the reaction for the electrolysis of water at the anode and cathode.
Explain figure 16.
P. 628: What is Dawns cell is used for?
P. 629: Give an example of the aluminum production by electrolysis.
P. 630: Define electroplating
Explain figure 19.
P. 631: Summarize benefits and concerns about electroplating.
Read, Take Notes and Check your Understanding.
P. 612: Define Electrochemistry
Explain figure 4
P. 613: Define voltage, electrochemical cell, electrodes, cathode.
Explain figure 5.
Write the cathodic reaction for the copper ion reduced to the atom.
P. 614: Define anode
Explain figure 6.
Write the anodic reaction for zinc atom oxidized to the ion.
P. 615: Write and explain the complete redox reaction for the cell in figure 7.
P. 616: Define galvanic cells
Explain figure 8.
P. 617: Define dry cell. Give an example.
Explain figure 9.
Write the equations at the anode and cathode.
P. 618-619. Define lead-acid batteries. Give an example
Explain figure 10.
Write the equations at the anode and cathode.
P. 619. Define dry cells. Give an example.
Explain figure 11.
Write the equations at the anode and cathode.
P. 620: Corrosion cells. Give an example.
Explain figure 12.
Write the equations at the anode and cathode.
P. 621: List 3 methods to prevent corrosion.
P. 622: What is a voltmeter?
Define standard electrode potential.
P. 627: Define electrolytic cell.
Define electrolysis.
Write the reaction for the electrolysis of water at the anode and cathode.
Explain figure 16.
P. 628: What is Dawns cell is used for?
P. 629: Give an example of the aluminum production by electrolysis.
P. 630: Define electroplating
Explain figure 19.
P. 631: Summarize benefits and concerns about electroplating.