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- The period of the wave is the time it takes for one oscillation to take place, or for one complete wavelength to pass a reference point. This has SI units of seconds (s), because it’s simply a value in a unit of time.
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What is a measurement in chemistry?
What is the standard unit of length?
What units are used in chemistry?
What information does a measurement provide?
What is a metric unit used for?
What is the SI unit of length?
Length. The standard unit of length in both the SI and original metric systems is the meter (m). A meter was originally specified as 1/10,000,000 of the distance from the North Pole to the equator. It is now defined as the distance light in a vacuum travels in 1/299,792,458 of a second.
- Energy
The temperature of an object is a measure of its thermal...
- 1.4: Units of Measurement
To identify the basic units of measurement of the seven...
- Energy
Dec 28, 2020 · The frequency and period of a wave are two of the most important characteristics of any wave, whether it's a light wave or the sea waves lapping up on the shore. Frequency tells you the number of oscillations of something per unit of time, and period tells you the length of the oscillation.
To identify the basic units of measurement of the seven fundamental properties. Describe the names and abbreviations of the SI base units and the SI decimal prefixes. Define the liter and the metric ton in these units. Explain the meaning and use of unit dimensions; state the dimensions of volume.
- Section 1: Chemistry and Matter
- Section 2: How Scientists Study Chemistry
- Section 3: Scientific Notation
- 103 = 1000 104 = 10000 105 = 100000
- 579, 000, 000, 000
- Coefficient Is: 5.79
- How Many Positions Are there?
- 4 = 0.0001 10-5 = 0.00001
- Coefficient Will Be 6.42
- How Many positions?
What is Chemistry?
Everything around us is made up of chemicals. From the color that makes a rose so red to the gasoline that fills our cars and the silicon chips that power our computers and cell phones…Chemistry is everywhere! Understanding how chemical molecules form and interact to create complex structures enables us to harness the power of chemistry and use it, just like a toolbox, to create many of the modern advances that we see today. This includes advances in medicine, communication, transportation, b...
Physical vs. Chemical Properties
Part of understanding matter is being able to describe it. One way chemists describe matter is to assign different kinds of properties to different categories. The properties that chemists use to describe matter fall into two general categories. Physical properties are characteristics that describes matter, such as boiling point, melting point and color. Physical Changes, such as melting a solid into a liquid, do not alter the chemical structure of that matter. Chemical properties are charact...
Elements and Compounds
Any sample of matter that has the same physical and chemical properties throughout the sample is called a substance. There are two types of substances. A substance that cannot be broken down into chemically simpler components is an element. Aluminum, which is used in soda cans, is an element. A substance that can be broken down into chemically simpler components (because it has more than one element) is a compound. Water is a compound composed of the elements hydrogen and oxygen. Today, there...
The Scientific Method
How do scientists work? Generally, they follow a process called the scientific method. The scientific method is an organized procedure for learning answers to questions. To find the answer to a question (for example, “Why do birds fly toward Earth’s equator during the cold months?”), a scientist goes through the following steps, which are also illustrated in Figure 1.7. Figure 1.7 The General Steps of the Scientific Method.The steps may not be as clear-cut in real life as described here, but...
The study of chemistry can involve numbers that are very large. It can also involve numbers that are very small. Writing out such numbers and using them in their long form is problematic, because we would spend far too much time writing zeroes, and we would probably make a lot of mistakes! There is a solution to this problem. It is called scientifi...
As you can see, the power to which 10 is raised is equal to the number of zeroes that follow the 1. This will be helpful for determining which exponent to use when we express numbers using scientific notation. Let us take a very large number:
and express it using scientific notation. First, we find the coefficient, which is a number between 1 and 10 that will be multiplied by 10 raised to some power.
This number will be multiplied by 10 that is raised to some power. Now let us figure out what power that is. We can do this by counting the number of positions that stand between the end of the original number and the new position of the decimal point in our coefficient.
We can see that there are 11 positions between our decimal and the end of the original number. This means that our coefficient, 5.79, will be multiplied by 10 raised to the 11th power. Our number expressed in scientific notation is:
The number of spaces to the right of the decimal point for our 1 is equal to the number in the exponent that is behind the negative sign. This is useful to keep in mind when we express very small numbers in scientific notation. Here is a very small number:
This number will be multiplied by 10 raised to some power, which will be negative. Let us figure out the correct power. We can figure this out by counting how many positions stand between the decimal point in our coefficient and the decimal point in our original number.
There are 5 positions between our new decimal point and the decimal point in the original number, so our coefficient will be multiplied by 10 raised to the negative 5th power. Our number written in scientific notation is:
Units of measurement are used to describe features and properties of objects. For example, “length” is a property that can be described by the meter, a unit of measurement.
Every measurement provides three kinds of information: the size or magnitude of the measurement (a number); a standard of comparison for the measurement (a unit); and an indication of the uncertainty of the measurement.
In the United States, the metric system is used primarily in science and medicine. In the metric system, base units are used for length, mass, volume, time, temperature, energy, and the amount of substance. Later we will explain how to modify the base units with prefixes to express very large and small measurements.
