Creado por annikasquires
hace más de 10 años
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Pregunta | Respuesta |
Solution | Homogenous mixiture in which the components are uniform, looks the same throughout Example: Salt Water |
Solvent | the dissolving medium in a solution present in the largest amount. Typically in a larger quantity than the solute Example Water. |
Solute | A substance dissolved in a solvent to form a solution Example : Sodium Chloride |
Aqueous solution | Solution with water as the solvent |
Ionic Substance | as an ionic substance dissolved in water the solute breaks apart into its ions. Example: sodium chloride will break apart into the sodium cation and the chloride anion |
Solubility | polar substance dissolve in polar substances non polar substances dissolve in non polar substances. Water dissolves both ionic and polar substances. Example: oil and water don't mix because oil is non polar, and water is non polar |
Saturated Solutions | A solution which contains as much solute as will dissolve at a given temperature Example: tea with one pack of sugar that dissolves throughly, but more packets than that will not |
Unsaturated | a Solution that contains less solute than will dissolve at a given temperature Example: unsweetened tea |
Supersaturated | A solution that contains more solute than will dissolve at a given temperature. This may occur if a solute is dissolved at a high temperature and solute beyond the saturation point remains solution. Example: tea with so much sweetener it is like diabetes in a bottle. |
Solubility Curve | Is used to find the saturation point of a solute at a given temperature |
Concentrated Solution | Describes a solution that has a relatively large amount of dissolved solute. Quantitative term |
Dilute Solution | Describes a solution that has a relatively small amount of dissolved solute. Qualitative term. more dilute has more solvent present it would be a clearer color when talking about water. |
Factors Affecting the Rate of Dissolution | Dissolution is the dissolving Process. Process is influenced by 1. Surface area: the greater the solvent-solute surface area interaction the faster the dissolution process 2. Stirring: provides continuous exposure of solvent 3. Temperature: Allow the solvent molecules to move faster. Most solids are generally more soluble at higher temperatures. |
Mass Percent | an expression of the mass of solute present and the given mass of solution mass of solute/ mass of solution *100= grams of solute/ grams of solute + grams of solvent * 100 |
Molarity (M) | Description of a solution in terms of concentration of the solution. Moles of soluter per volume of solution in liters. M=molarity= moles of solute/ liters of solution= mol/L |
Formalin | aqueous solutions of formaldehyde |
Standard Solution | concentrate is accurately known |
Stock Solution | is a concentrated solution that is often diluted to obtain a desired concentration |
Dilution | is the process of adding more solvent to a known solution to achieve a lesser concentration |
Dilution Process | The Dilution process should occur in a volumetric flask. To determine the volume of the needed of the standard solution in comparison to the volume desired of the dilute solution use: M1V1=M2V2 the moles of solute remain the same before and after a dilution |
Volumetric Flask |
Image:
volum.gif (image/gif)
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Steps to making a Solution (Example problem using if you are given 12 M HCl how much is needed to make 125 mL of 6.0 M HCl) | 1. use a volumetric pipette to measure 63 mL of 12 M HCl 2. Place the 12 M HCl (63 ml) into the volumetric flask. In this case the desired flask is 125 mL 3. Add water to the line 4. Shake it |
Molality | A method of describing solute concentration is molality (m) m=molality= moles of solute/kilograms of solvent= mol/kg |
Colligative Properties | A solution property that depends on the number of solute particles |
Boiling Point Elevation | Boiling Point of a substance is the temperature at which the vapor pressure of a liquid equals the atmospheric pressure. Adding a nonvolatile solute to a liquid decreases. More kinetic energy is required to raise the vapor pressure of the liquid which in turn elevates the boiling point of the solution above and the pure solvents |
Boiling Point Elevation Equation | DeltaTb= iKbm DeltaT= Change in the boiling temperature i= van't Hoff factor = # ions salt breaks into Kb= boiling point elevation constant m= molality concentration of the solution |
Freezing Point Depression | The presence of a solute interrupts the order of the solvent as it freezes this causes more kinetic energy to be withdrawn from a solution in comparison to a pure solvent which depresses the freezing point of the solution |
Freezing Point Depression | Depends on the concentration of the particles not the identity of the particles. Freezing point depression is calculated using: DeltaTf= iKfm DeltaTf= change in the freezing temperature i=Van't Hoff factor= # ions salt breaks into Kf= molal freezing point depression constant m= molal concentration of the solution |
PH Formula | PH=-Log [H+] |
Concentration (M) | [ ] All Measured using molarity |
pOH | pOH=-log [OH-] |
pH+pOH | 14 |
[H+] | Inverse log of -pH (on calculator inverse log looks like 10^ |
Acids | Contain an H+ ion Ex: HCl, H302 |
Bases | Contain OH- Ex. NaOH NH4OH |
Neutrals | Contain neither H+ or OH- or they contain both H+ and OH- in equal concentration Ex: H2O-> H+ OH- |
Brønsted- Lowry | Acids- proton H+ donor ex. HBR can donate the H+ Base- proton H+ acceptor ex. NH3 + H20 -> NH4+ plus OH- |
Conjugate acid- base pair under Brønsted Lowry | NH3 + H20 -> NH4+ plus OH- Base plus acid on one side of arrow -> conjugate acid plus conjugate base on the other side of the arrow |
Amphoteric | a substance that can behave as both an acid or a base ex. if H20 donates an H+ then OH- remains; in this case H20 is acting as an acid. if H20 accepts an H+ then H30 + forms , in this case H20 is acting as a base |
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