1 / 38

Chapter 4 Reactions in Aqueous Solutions

Chapter 4 Reactions in Aqueous Solutions. Many chemical and almost all biological reactions occur in the aqueous medium Substances (solutes) that dissolve in water (solvent) can be divided into two categories: Electrolytes Non-Electrolytes. Three Major Types of Reactions.

talia
Télécharger la présentation

Chapter 4 Reactions in Aqueous Solutions

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Chapter 4Reactions in Aqueous Solutions • Many chemical and almost all biological reactions occur in the aqueous medium • Substances (solutes) that dissolve in water (solvent) can be divided into two categories: • Electrolytes • Non-Electrolytes

  2. Three Major Types of Reactions • Precipitation Reaction – the product an insoluble substance separates from the solution • Acid/Base Reactions – A proton transfer from an acid to a base • Oxidation/Reduction (Redox) “the bane of the AP Test” – Electrons are transferred from a reducing agent to an oxidizing agent

  3. Solution Stoichiometry • Quantitative studies with known concentrations (Molarity) of solutions • Gravimetric Analysis • Titrations

  4. General Properties of a Solution • Solution – a homogenous mixture of two or more substances • Solution may be gaseous (air), solid (alloy) or Liquid (salt water) • In this chapter we will deal only with aqueous solutions • Most common Solvent - Water

  5. Electrolytes versus Nonelectrolytes • Electrolytes – Ionic compounds that completely or partially dissociate in solution with the ability to pass electric current in solution • Acids/Bases will ionize in solution, therefore electricity can be conducted • Non-Electrolytes – Molecular compounds that do not dissociate in solution, therefore no electric current can be pass

  6. Ionic Compounds in Solution • Water is a great solvent for ionic compounds because it is polar, the positive end attracts the Negative Ion and vice versa

  7. Acids and Bases as Electrolytes • Some acid/bases competely dissociate in solution • HCl • HNO3 • H2SO4 • Ba(OH)2 • NaOH • While others only partially dissociate • CH3COOH • HF • HNO2 • HN3

  8. Writing Partial Dissociation Equations • Partial dissociation equations are written with a double arrow, indicating a reversible reaction • Write partial dissociation for CH3COOH

  9. Precipitation Reactions • A double replacement reaction (metathesis) in which a product is insoluble

  10. Solubility RulesIn water at 25 Degrees • All common compounds of Group I and ammonium ions are soluble. • All nitrates, acetates, and chlorates are soluble. • All binary compounds of the halogens (other than F) with metals are soluble, except those of Ag, Hg(I), and Pb. • All sulfates are soluble, except those of barium, strontium, calcium, lead, silver, and mercury (I). The latter three are slightly soluble. • Except for rule 1, carbonates, hydroxides, oxides, silicates, and phosphates are insoluble. • Sulfides are insoluble except for calcium, barium, strontium, magnesium, sodium, potassium, and ammonium.

  11. Soluble or Insoluble at 25 Degrees Celsius in Water • PbSO4 • BaCO3 • Li3PO4 • FeS • Ca(OH)2 • Co(NO3)3

  12. Net Ionic Equations • Write the correctly balanced equation and decide on state of each product • Write free state of all ions and insoluble product • Cancel out spectator ions – anyone not part of the reaction • Check charges and balancing in net ionic

  13. Practice Net IonicPredict, Balance and write net ionic • Lead Nitrate and Potassium Iodide • Barium Chloride and Sodium Sulfate • Potassium Phosphate and Calcium Nitrate • Aluminum Nitrate and Sodium Hydroxide

  14. Acid – Base Reactions • Acids react with metal such as Zn, Mg and Fe to produce hydrogen gas • Acids react with carbonates and bicarbonates to produce carbon dioxide gas, water and the salt

  15. Bronsted Acid and Bases • Bronsted Acid is a proton donor • Bronsted Base is a proton acceptor HCl (aq) H+(aq) + Cl-(aq) In water the H+ attracts to the water molecule producing the hydronium ion

  16. Monoprotic Acids • Each unit of acid yields one hydrogen ion upon ionization

  17. Diprotic Acids • Each unit of the acid gives up two hydrogen ions in two separate steps (they strip)

  18. Triprotic Acids • Yield three hydrogen ions in three separate steps (they strip)

  19. Bronsted Acid is a proton donorBronsted Base is a proton acceptor • Classify each of the following as an Bronsted acid or Bronsted base, explain your reasoning based on the definition • HBr • SO-24 • HI • HCO-3 • NO2

  20. Neutralization ReactionAcid and Base will form Salt and Water • Write the net ionic for the following • Hydrochloric acid and Sodium Hydroxide • Sulfuric acid and Aluminum Hydroxide

  21. Acid – Base Reactions Leading to Formation of a Gas • Certain Salts – Carbonates, bicarbonates, sulfites and sulfides react with acids to form gaseous products

  22. Oxidation Numbers • Oxidation Reaction – refers to half reaction that involves loss of electrons • Reduction reaction – refers to a half reaction that involves the gain of electrons • The extent of oxidation in a redox reaction must be equal to the extent of reduction; that is the number of electrons lost by a reducing agent must be equal to the number of electrons gained by an oxidizing agent

  23. The half-reactions of a redox reaction or oxidation-reduction reaction

  24. Oxidation Number • The number of charges the atom would have in a molecule if electrons are transfer completely

  25. The convention is that the cation is written first in a formula, followed by the anion. • For example, in NaH, the H is H-; in HCl, the H is H+. • The oxidation number of a free element is always 0. • The atoms in He and N2, for example, have oxidation numbers of 0. • The oxidation number of a monatomic ion equals the charge of the ion. • For example, the oxidation number of Na+ is +1; the oxidation number of N3- is -3. • The usual oxidation number of hydrogen is +1. • The oxidation number of hydrogen is -1 in compounds containing elements that are less electronegative than hydrogen, as in CaH2. • The oxidation number of oxygen in compounds is usually -2. • Exceptions include OF2, since F is more electronegative than O, and BaO2, due to the structure of the peroxide ion, which is [O-O]2-. • The oxidation number of a Group IA element in a compound is +1. • The oxidation number of a Group IIA element in a compound is +2. • The oxidation number of a Group VIIA element in a compound is -1, except when that element is combined with one having a higher electronegativity. • The oxidation number of Cl is -1 in HCl, but the oxidation number of Cl is +1 in HOCl. • The sum of the oxidation numbers of all of the atoms in a neutral compound is 0. • The sum of the oxidation numbers in a polyatomic ion is equal to the charge of the ion. • For example, the sum of the oxidation numbers for SO42- is -2.

  26. Assign oxidation numbers to all the elements in the following compounds • Na2O • HNO2 • Cr2O7-2 • PF3 • MnO4-

  27. Arrange the following species in order of increasing oxidation number of the sulfur atoms • H2S • SO2 • SO3 • S8 • H2SO4 • S-2 • HS-

  28. Concentration • Molarity = moles of solute/liters of solution • Example: How many grams of potassium dichromate are required to prepare a 125ml solution whose concentration is 1.83M

  29. Concentration • In a biochemical assay a chemist needs a to add 4.07g of glucose to a reaction mixture. Calculate the volume in milliliters the volume of a 3.16M glucose she should use

  30. Dilution of Solutions • The procedure of making a less concentrated solution from a high concentration solution • MiVi = MfVf

  31. Dilution Problem • Describe hou you would prepare 2.50 * 102 ml of a 2.25M H2SO4 solution, starting with a 7.41 M stock solution of H2SO4

  32. Dilution Problem #2 • How would you prepare a 200ml of a .866M KOH solution, starting with 5.07M stock solution

  33. Acid – Base Titrations • In a titration a solution of an accurately known concentration, called the standard is added gradually to another solution of unknown until reaction is neutralized (equivalence point) • Indicators are used to color the reaction when it is complete

  34. Titration Problem • In a titration experiment, a student finds that 25.46ml of a NaOH solution is needed to neutralize .6092g of KHP. What is the concentration of the NaOH solution?

  35. Titration Problem #2 • How many milliliters of a .836M NaOH solution is needed to neutralized 25ml of a .335M of H2SO4?

  36. Solution Stoichiometry When sodium chloride reacts with silver nitrate, silver chloride precipitates. What mass of silver chloride is produced from 150ml 3M of silver nitrate?

  37. When Magnesium chloride reacts with silver nitrate, silver chloride precipitates. What mass of silver chloride is produced from 4.5M in 250ml of silver nitrate? What is the name of the other product of the reaction?

More Related