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Water, Water Everywhere

Explore the three states of water - liquid, vapor, and solid - and learn how chemistry provides a link between the macroscopic and microscopic world of matter. Understand the roles of chemistry in scientific studies and discover the scientific method. Dive into units and measurements, including the metric system and prefixes. Gain insights into mass, weight, and the importance of accurate measurements.

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Water, Water Everywhere

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  1. Water, Water Everywhere

  2. Water as Liquid - Rainwater

  3. Water Vapor (Steam)

  4. Snow and Snow Flakes

  5. Water as Solid - Iceberg

  6. The Three States of WaterMacroscopic and Microscopic Views

  7. Water Cycle

  8. Colors in Nature

  9. Chemical Reaction

  10. Where does Chemistry fit in? • Chemistry provides the links between the macroscopic world that we experience and the microscopic world of atoms and molecules. • It is relevant to all form of scientific studies.

  11. Roles of Chemistry

  12. The Central Science • Chemistry is the study of matter and the changes/reactions they undergo. • Chemistry is a central science. • It is essential in understanding both biological and non-biological worlds;

  13. What is Matter? • The materials of the universe  anything that has mass and occupies space

  14. What Type of Change? • Physical and Chemical; • Physical Changes: Processes that alter the states of substances, but not their fundamental compositions. • Chemical Changees: Processes that alter the fundamental compositions of substances and their identity.

  15. Study of Matter & Changes In chemistry you will study: • the existence of matter at macroscopic and microscopic levels; • the different states they can exist, • factors that determine their stability, and • their physical and chemical properties.

  16. Atoms vs. Molecules • Matter is composed of tiny particles called atoms. • Atom: smallest part of an element that is still that element. • Molecule: Two or more atoms joined and acting as a unit.

  17. Chemical Reaction • One substance becomes another substance(s), such that the fundamental compositions of products are different from those of reactants.

  18. Roles of Science • Science is not a just list of facts or knowledge; • Science is a framework for gaining and organizing knowledge/fact about matter, including changes they undergo;

  19. Roles of Scientists • Scientists continuously challenge our current beliefs about nature, and always: • asking questions about what we have already known; • Testing the fact/knowledge to confirm it or to gain new insight.

  20. The Process: Scientific Method

  21. The Scientific Method

  22. Fundamental Steps in Scientific Method • Identify the problems and collect information/data; • Develop a hypothesis based on available data; • Test the hypothesis (Design & perform experiments) • Collect and analyze more data to support hypothesis • Make a Conclusion: • Observations may become Law; • Hypotheses may become Theory.

  23. Terms in the Scientific Method • Hypothesis: a possible explanation for an observation. • Theory: a set of (tested) hypotheses that gives an overall explanation of certain natural phenomenon. • Scientific Law: a concise statement that summarizes repeatable observed (measurable) behavior.

  24. Units and Measurements Measurement • Quantitative observations consist of: • Number & Units (without unit, the value becomes meaningless. • Examples: • 65 kg (kg = kilogram; unit for mass) • 4800 km (km = kilometer; unit for distance) • 3.00 x 108 m/s (m/s = meter per second; unit for speed)

  25. Units and Measurements The Number System • Decimal Numbers: 384,400 0.08206 • Scientific Notations: 3.844 x 105 (but 384.4 x 103 is not) 8.206 x 10-2

  26. Meaning of 10n and 10-n • The exponent 10n : • if n = 0, 100 = 1; • if n > 0, 10n > 1; • Examples: 101 = 10; 102 = 100; 103 = 1,000; • The exponent 10-n : • if n > 1, 10-n < 1; • Examples: 10-1 = 0.1; 10-2 = 0.01; 10-3 = 0.001

  27. Units of Measurements • Units give meaning to numbers. Without UnitWith Units 384,400 ? 384,400 km (implies very far) 384,400 cm (not very far) 144 ? 144 eggs (implies quantity) 0.08206 ? 0.08206 L.atm/(K.mol) (No meaning)

  28. English Units Mass: ounce (oz.), pound (lb.), ton; Length: inches (in), feet (ft), yd, mi., etc; Volume: pt, qt, gall., in3, ft3,etc.; Area: acre, hectare, in2, ft2, yd2, mi2.

  29. Metric Units Mass: gram (g); kg, mg, mg, ng; Length: meter (m), cm, mm, km, mm, nm, pm; Area: cm2, m2, km2 Volume: L, mL, mL, dL, cm3, m3; (cm3 = mL)

  30. Fundamental SI Units Physical QuantityName of UnitAbbreviation Mass kilogram kg Length meter m Time second s Temperature Kelvin K Amount of substance mole mol Energy Joule J Electrical charge Coulomb C Electric current ampere A

  31. Prefixes in the Metric System • Prefix Symbol 10n Decimal Forms Giga G 109 1,000,000,000 Mega M 106 1,000,000 kilo k 103 1,000 deci d 10-1 0.1 centi c 10-2 0.01 milli m 10-3 0.001 micro m 10-6 0.000,001 nano n 10-9 0.000,000,001 pico p 10-12 0.000,000,000,001 —————————————————————

  32. Mass and Weight • Mass is a measure of quantity of substance; • Mass does not vary with condition or location. • Weight is a measure of the gravitational force exerted on an object; • Weight varies with location if the gravitational force changes.

  33. Errors in Measurements • Random errors • values have equal chances of being high or low; • magnitude of error varies from one measurement to another; • error may be minimize by taking the average of several measurements of the same kind;

  34. Errors in Measurements • Systematic errors • Errors due to faulty instruments; • reading is either higher or lower than the correct value by a fixed amount; • the magnitude of systematic error is the same, regardless of quantity measured; • For balances with systematic errors, weighing by difference can eliminate systematic errors.

  35. Accuracy and Precisionin Measurements • Accuracy The agreement of an experimental value with the “true” or accepted value; • Precision Degree of agreement among values of same measurements; (degree of repeatability)

  36. Accuracy and Precision

  37. Accuracy and Precision • Accuracy and degree of precision in a measurement is defined by the type of instrument used.

  38. Balances with Different Precisions Centigram Balance (precision: ± 0.01 g) Milligram Balance (precision: ± 0.001 g)

  39. Analytical Balance(precision: ± 0.0001 g)

  40. Significant Figures • Way of expressing measured values with degree of certainty; • For examples: • Mass of an object on a centigram balance = 2.51 g • Mass of same object on analytical balance = 2.5089 g Absolute error for centigram balance = 0.4%; Absolute error for analytical balance = 0.004%; Analytical balance gives mass with more significant figures (5) and more precise (a greater degree of certainty), compared with a centigram balance that gives 3 significant digits for the same mass.

  41. How many significant figures are in the following measurements?

  42. What is the Buret Reading shown in the Diagram? • Reading liquid volume in a buret; • Read at the bottom of meniscus; • Suppose meniscus is read as 20.15 mL: • Certain digits: 20.15 • Uncertain digit: 20.15

  43. What is the volume of liquid in the graduated cylinder?

  44. Rules for Counting Significant Figures • All nonzero integers are counted as significant figures Examples: 453.6 has 4 significant figures; 4.48 x 105 has 3 significant figures;

  45. Rules for Counting Significant Figures 2. Leading zeroes – zeroes that precede all nonzero digits are NOT counted as significant figures. Examples: 0.0821 has 3 significant figures 0.00055 has 2 significant figures

  46. Rules for Counting Significant Figures 3. Captive zeros – these are zeros between nonzero digits; they are always counted as significant figures. Examples: 1.079 has 4 significant figures 0.08206 has 4 significant figures

  47. Rules for Counting Significant Figures 4. Trailing zeroes – these are zeroes at the right end of the number. They are counted as significant figures if the number contains a decimal point, otherwise it is not counted. Examples: 208.0 has 4 significant figures; 2080. also has 4 significant figures, but 2080 has 3 significant figures;

  48. Rules for Counting Significant Figures 5. Exact numbers – these are numbers given by definition or obtained by counting. They have infinite number of significant figures; the value has no error. Examples: 1 yard = 36 inches; 1 inch = 2.54 cm (exactly); there are 24 eggs in the basket; this class has 60 students enrolled; (There are 35,600 spectators watching the A’s game at the Coliseum is not an exact number, because it is an estimate.)

  49. How many significant figures? • 0.00239 • 0.01950 • 1.00 x 10-3 • 100.40 • 168,000 • 0.082060 • One dime equals to 10 pennies • Express 1000 as a value with two significant figures.

  50. Rounding off Values in Calculations • In Multiplications and/or Divisions Round off the final answer so that it has the same number of significant figures as the value with the least significant figures. Examples: (a) 9.546 x 3.12 = 29.8 (round off from 29.78352) (b) 9.546/2.5 = 3.8 (round off from 3.8184) (c) (9.546 x 3.12)/2.5 = 12 (round off from 11.913408)

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