220 likes | 527 Views
Solution Preparation and pH. Lab 7. Purpose pH and pH measurements Acids Bases Neutral solutions Preparing a solution from a solid Preparing a solution from a liquid (dilution) Today’s Experiment Safety Concerns Waste Next Assignment . Outline.
E N D
Purpose • pH and pH measurements • Acids • Bases • Neutral solutions • Preparing a solution from a solid • Preparing a solution from a liquid (dilution) • Today’s Experiment • Safety Concerns • Waste • Next Assignment Outline
The purpose of this lab is to provide students with the opportunity to engage in solution preparation. Students will also calibrate a pH probe and make pH measurements of solutions to demonstrate the pH differences between acids, bases and neutral solutions of equimolar proportions. Purpose
pH is an indication of the abundance of free H+ ions in solution – measured with a pH probe. • Definition: pH = – log [H+] • Measured on a scale that ranges from 0 to 14 • Acidic – pH less than 7 • Neutral – pH 7 • Basic – pH more than 7 pH
Strong acids completely dissociate in solution. Examples include H2SO4, HCl, and HNO3. • Weak acids dissociate partially in solution. Examples include CH3COOH and HCN. (Dissociation is the process by which a chemical combination breaks up into simpler constituents.) Acids
Because strong acids donate more hydrogen ions to the solution than weak acids, they have a lower pH at equimolar concentration. HCl H+(aq) + Cl-(aq) • For every 100 HCl compounds that go into solution, 100 H+ and 100 Cl- result. CH3COOH CH3COO-(aq) + H+(aq) • For every 100 CH3COOH molecules that go into solution, maybe 1 H+ and 1 CH3COO- result. 99 molecules remain intact as CH3COOH. • Which one is the strong acid? Acids
The actual degree of dissociation depends on the compound and is described by the Ka (pKa) of each compound. • We won’t be covering pKa in this lab. Degree of Dissociation
Strong bases are metal hydroxide salts that completely dissociate in solution. Examples include NaOH and KOH • Weak bases react with water to produce hydroxide ions to a small extent. Examples include NH4OH and C5H5N (pyridine) (Dissociation is the process by which a chemical combination breaks up into simpler constituents.) Bases
Because strong bases result in more hydroxide ions in solution than weak bases, they have a higher pH at equimolar concentration. NaOH(s) Na+(aq) + OH-(aq) • For every 100 NaOH compounds that go into solution, 100 Na+ and 100 OH- result. NH4OH NH4+(aq) + OH-(aq) • For every 100 NH4OH compounds that go into solution, maybe 1 NH4+ and 1 OH- result. 99 compounds remain intact as NH4OH. • Which one is the weak base? Bases
The actual degree of dissociation depends on the compound and is described by the Kb (pKb) of each compound. • We won’t be covering pKb in this lab. Degree of Dissociation
Under perfect conditions, these solutions have a pH of 7. • Why won’t we see this exact pH for our “neutral” solutions today? Neutral Solutions
When you are required to make a solution of accurate concentration, a volumetric flask is used. • We never make solutions of accurate concentration in: • Beakers • Graduated cylinders • Erlenmeyer flasks Solution Preparation
Determine the mass of the solid needed. You will need the following: • Molar mass of the solid • Total volume desired • Final concentration desired • Calculation: • Mass, g = [ ], mol/L x MM, g/mol x Vol, L • Remember the precision of your glassware! Solution Preparation from Solids
Make the solution: • Weigh out the appropriate mass of solid. • Place a small volume of distilled water in the volumetric flask. • Add the solid to the volumetric flask. • Add some more distilled water to the flask, stopper, and invert several times. • Add distilled water to the calibration line (fill to volume) using a medicine dropper, stopper, and invert several times. Solution Preparation from Solids
Determine the volume of stock solution needed. You will need the following: • Concentration of stock solution (M1) • Desired concentration of diluted solution (M2) • Desired volume of diluted solution (V2) • Calculation: • M1V1 = M2V2 • Remember the precision of your glassware! Solution Preparation from Liquids
Make the solution: • Obtain the appropriate volume of stock solution using a graduated cylinder. (Always add a few mL extra.) • Place a small volume of distilled water in a volumetric flask. • Use the appropriate pipet to transfer the correct volume of stock solution from the graduated cylinder to the volumetric flask. • Add some more distilled water to the flask, stopper, and invert several times. • Add distilled water to the calibration line (fill to volume) using a medicine dropper, stopper, and invert several times. Solution Preparation from Liquids
Make your solutions • Transfer your solutions to the 20 mL vials. • Calibrate your pH probe • Measure the pH of your known and unknown solutions. • Record your results and answer the questions in your manual. In today’s experiment you will…
Be careful! These probes are fragile. • An internal pH calibration is needed first to obtain a calibration curve that the computer can use to interpolate the correct pH. • When you report your pH measurements, remember to use the correct number of significant digits. (The number of digits depends on your calibration values.) • Remember to rinse and dry the probe before each transfer. This will prevent cross-contamination. When calibrating your probe…
Our pH probes respond slowly to “neutral” solutions. Allow additional stabilization time. • Weak acids and bases are registering slightly out of range. On the data sheet, identify one strong acid, one weak acid, one strong base, one weak base, and one “neutral” solution. Match the dH2O and unknowns as indicated. Points of Interest
Reagents: • HNO3 (1 N) / HCl (0.2 N) • NaOH / KOH • NH4OH • KHP • Na2SO4 • Eye Contact: • Irritating, burns, permanent eye damage, tearing, redness, pain, impaired vision, blindness • Skin Contact: • Irritating, redness, pain, soreness, severe skin burns, ulcers, stains, destruction, scaling, and blistering • Inhalation: • Breathing difficulties, pneumonia, pulmonary edema, coughing, choking, irritation of nose, throat, and respiratory tract, burns, and death • Ingestion: • Pain and burns of the mouth, throat, esophagus and gastrointestinal tract. Corrosive to mucous membranes, perforation of the esophagus and stomach, abdominal pain, nausea, vomiting, abnormal sensations of hands and feet, and general gastro-intestinal upset. Safety Concerns
All excess solid can go in the regular garbage. • Dispose waste solutions in the appropriate waste receptacles. • Acidic and basic solutions / waste need to be disposed in the acid/base waste container in the fume hood. • Solutions with a pH between 6 and 8 can be disposed down the drain. Waste
There will be no labs next week due to Spring Break • We will be doing skill evaluations in 2 weeks. • Carefully study pages 295 – 315. • Remember to bring your goggles and lab manual! • Your instructor will let you know when to submit your Lab 7 Report. Skill Evaluations – in 2 Weeks