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Chapter 1 Introduction: Matter and Measurement

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1 Chapter 1 Introduction: Matter and Measurement
Lecture Presentation Chapter 1 Introduction: Matter and Measurement James F. Kirby Quinnipiac University Hamden, CT

2 Chemistry Chemistry is the study of the properties and behavior of matter. It is central to our fundamental understanding of many science-related fields.

3 Matter Matter is anything that has mass and takes up space.

4 Matter Atoms are the building blocks of matter.
Each element is made of a unique kind of atom. A compound is made of two or more different kinds of elements. Note: Balls of different colors are used to represent atoms of different elements. Attached balls represent connections between atoms that are seen in nature. These groups of atoms are called molecules.

5 Methods of Classification
State of Matter Composition of Matter

6 States of Matter The three states of matter are
solid. liquid. gas. In this figure, those states are ice, liquid water, and water vapor.

7 Classification of Matter Based on Composition
If you follow this scheme, you can determine how to classify any type of matter. Homogeneous mixture Heterogeneous mixture Element Compound Matter And Measurement

8 Classification of Matter—Substances
A substance has distinct properties and a composition that does not vary from sample to sample. The two types of substances are elements and compounds. An element is a substance which can not be decomposed to simpler substances. A compound is a substance which can be decomposed to simpler substances.

9 Compounds and Composition
Compounds have a definite composition. That means that the relative number of atoms of each element that makes up the compound is the same in any sample. This is The Law of Constant Composition (or The Law of Definite Proportions).

10 Classification of Matter—Mixtures
Mixtures exhibit the properties of the substances that make them up. Mixtures can vary in composition throughout a sample (heterogeneous) or can have the same composition throughout the sample (homogeneous). Another name for a homogeneous mixture is solution.

11 Types of Properties Physical Properties can be observed without changing a substance into another substance. Some examples include boiling point, density, mass, or volume. Chemical Properties can only be observed when a substance is changed into another substance. Some examples include flammability, corrosiveness, or reactivity with acid.

12 Types of Properties Intensive Properties are independent of the amount of the substance that is present. Examples include density, boiling point, or color. Extensive Properties depend upon the amount of the substance present. Examples include mass, volume, or energy.

13 Types of Changes Physical Changes are changes in matter that do not change the composition of a substance. Examples include changes of state, temperature, and volume. Chemical Changes result in new substances. Examples include combustion, oxidation, and decomposition.

14 Changes in State of Matter
Converting between the three states of matter is a physical change. When ice melts or water evaporates, there are still 2 H atoms and 1 O atom in each molecule.

15 Chemical Reactions (Chemical Change)
In the course of a chemical reaction, the reacting substances are converted to new substances. Here, the elements hydrogen and oxygen become water.

16 Separating Mixtures Mixtures can be separated based on physical properties of the components of the mixture. Some methods used are filtration. distillation. chromatography.

17 Filtration In filtration, solid substances are separated from liquids and solutions.

18 Distillation Distillation uses differences in the boiling points of substances to separate a homogeneous mixture into its components.

19 Chromatography This technique separates substances on the basis of differences in the ability of substances to adhere to the solid surface, in this case, dyes to paper.

20 Numbers and Chemistry Numbers play a major role in chemistry. Many topics are quantitative (have a numerical value). Concepts of numbers in science Units of measurement Quantities that are measured and calculated Uncertainty in measurement Significant figures Dimensional analysis

21 Units of Measurements—SI Units
Système International d’Unités (“The International System of Units”) A different base unit is used for each quantity.

22 Units of Measurement—Metric System
The base units used in the metric system Mass: gram (g) Length: meter (m) Time: second (s or sec) Temperature: degrees Celsius (oC) or Kelvins (K) Amount of a substance: mole (mol) Volume: cubic centimeter (cc or cm3) or liter (l)

23 Units of Measurement— Metric System Prefixes (p. 16)
Prefixes convert the base units into units that are appropriate for common usage or appropriate measure.

24 Mass and Length These are basic units we measure in science.
Mass is a measure of the amount of material in an object. SI uses the kilogram as the base unit. The metric system uses the gram as the base unit. Length is a measure of distance. The meter is the base unit.

25 Volume Note that volume is not a base unit for SI; it is derived from length (m × m × m = m3). The most commonly used metric units for volume are the liter (L) and the milliliter (mL). A liter is a cube 1 decimeter (dm) long on each side. A milliliter is a cube 1 centimeter (cm) long on each side, also called 1 cubic centimeter (cm × cm × cm = cm3).

26 Temperature In general usage, temperature is considered the “hotness and coldness” of an object that determines the direction of heat flow. Heat flows spontaneously from an object with a higher temperature to an object with a lower temperature.

27 Temperature In scientific measurements, the Celsius and Kelvin scales are most often used. The Celsius scale is based on the properties of water. 0 C is the freezing point of water. 100 C is the boiling point of water. The kelvin is the SI unit of temperature. It is based on the properties of gases. There are no negative Kelvin temperatures. The lowest possible temperature is called absolute zero (0 K). K = C

28 Temperature The Fahrenheit scale is not used in scientific measurements, but you hear about it in weather reports! The equations below allow for conversion between the Fahrenheit and Celsius scales: F = 9/5(C) + 32 C = 5/9(F − 32)

29 Density Density is a physical property of a substance.
It has units that are derived from the units for mass and volume. The most common units are g/mL or g/cm3. The density of gases is generally reported in g/L D = m/V

30 Numbers Encountered in Science
Exact numbers are counted or given by definition. For example, there are 12 eggs in 1 dozen. Inexact (or measured) numbers depend on how they were determined. Scientific instruments have limitations. Some balances measure to ±0.01 g; others measure to ±0.0001g.

31 Uncertainty in Measurements
Different measuring devices have different uses and different degrees of accuracy. All measured numbers have some degree of inaccuracy.

32 When recording a measurement, include all known digits, plus a final estimated digit.
For example, in the first ruler we know the ones place and could record 2. But we must also estimate one additional digit (the tenths place). So we might record 2.3. cm or 2.4 cm. What would be a correct measurment for the second ruler?

33 Accuracy versus Precision
Accuracy refers to the proximity of a measurement to the true value of a quantity. Precision refers to the proximity of several measurements to each other.

34 Significant Figures The term significant figures refers to digits that were measured. When rounding calculated numbers, we pay attention to significant figures so we do not overstate the accuracy of our answers.

35 Significant Figures All nonzero digits are significant.
Zeroes between two significant figures are themselves significant. Zeroes at the beginning of a number are never significant. Zeroes at the end of a number are significant if a decimal point is written in the number.

36 Practice: Determine how many sig figs are in each of these numbers
2.00 3000 670,000 3.0000 1.005 7.08 x 10-5 600.

37 Practice: Round each number to 2 sig figs
1) ) ) ) ) 235,478

38 Significant Figures When addition or subtraction is performed, answers are rounded to the least significant decimal place. When multiplication or division is performed, answers are rounded to the number of digits that corresponds to the least number of significant figures in any of the numbers used in the calculation.

39 Practice: Perform each calculation and report your answer with the correct number of sig figs
2.33 x x 2.1 (4.52 x 10¯4) ÷ (3.980 x 10¯6)

40 Dimensional Analysis We use dimensional analysis to convert one quantity to another. Most commonly, dimensional analysis utilizes conversion factors (e.g., 1 in. = 2.54 cm). We can set up a ratio of comparison for the equality either 1 in/2.54 cm or 2.54 cm/1 in. We use the ratio which allows us to change units (puts the units we have to cancel in the denominator).

41 The 3 Steps of Dimensional Analysis:
How many mL are in 1.63 L? 1. Change your given into a fraction by placing it over 1. 2. Write a conversion factor that has the unit you wish to get rid of in the denominator and the unit you want to end up with in the numerator.  1000 mL 1L 1.63 L 1

42 3. Multiply your given times the conversion factor
3. Multiply your given times the conversion factor. When you do this the unit in your given will cancel out leaving you with the unit you wish to convert to. Multiply the numerators together. Then multiply the denominators together Then divide the numerator by the denominator and adding the unit. Remember to report your answer with the correct amount of sig figs! 1L 1000 mL 1.63 L x = 1630 mL

43 2 Conversions Meters to miles Seconds to hours
The speed of sound in air is about 343 m/s. What is this speed in miles per hour? 1 mi = 1609 m 2 Conversions Meters to miles Seconds to hours 1 min = 60 s 1 hour = 60 min 343 m 1 mi 60 s 60 min = 767 mi/hr 1 s 1609 m 1 hr 1 min

44 More Sig Fig Rules…. Some measurements are exact - For example, there are exactly 100 cm in 1 meter, and exactly 60 minutes in 1 hour. These measurements have an infinite number of significant figures and should NOT be used to round your answer to the correct number of sig figs. Conversion factors that have both units in metric (examples: 1000 mL/1 L, 1 m/100 cm) or both units in the English System (examples: 5280 ft/ 1 mi., 1 gallon/ 4 quarts) should not be used in determining sig figs in your answer.

45 If you have conversion factors that have units in both metric and English, they generally are used to determine sig figs. Examples: 3.8 L / 1.0 gallon, 1.0 km/ 0.6 mi, inches/ 1.0 meter. As a general rule, it is usually (but not always) your given (what you start out with) that determines the number of sig figs in your answer. If you look at the example above where we converted 77.2 years to seconds, we rounded the answer to 3 sig figs because our given (77.2 years) has 3 sig figs.

46 Dimensional Analysis Practice
Convert 4 days into hours Convert 3.24 cm3 to m3 Convert 2.48 g/cm2 to cg/mm2


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