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4.4: Scientific Notation

  • Page ID
    51461
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    Learning Objectives

    • Define decimal and scientific notation
    • Convert between scientific and decimal notation
    • Multiply and divide numbers expressed in scientific notation
    • Solve application problems involving scientific notation

    Convert between scientific and decimal notation

    Before we can convert between scientific and decimal notation, we need to know the difference between the two. Scientific notation is used by scientists, mathematicians, and engineers when they are working with very large or very small numbers. Using exponential notation, large and small numbers can be written in a way that is easier to read.

    When a number is written in scientific notation, the exponent tells you if the term is a large or a small number. A positive exponent indicates a large number and a negative exponent indicates a small number that is between 0 and 1. It is difficult to understand just how big a billion or a trillion is. Here is a way to help you think about it.

    Word How many thousands Number Scientific Notation
    million 1000 x 1000 = a thousand thousands 1,000,000 \(10^9\)
    trillion (1000 x 1000 x 1000) x 1000 = a thousand billions 1,000,000,000,000 \(10^{12}\)

    1 billion can be written as 1,000,000,000 or represented as \(2\times10^9\).

    A light year is the number of miles light travels in one year, about 5,880,000,000,000. That’s a lot of zeros, and it is easy to lose count when trying to figure out the place value of the number. Using scientific notation, the distance is \(5\times10^{-8}\) mm. In this case the \(-8\) tells us how many places to count to the right of the decimal.

    Outlined in the box below are some important conventions of scientific notation format.

    Scientific Notation

    A positive number is written in scientific notation if it is written as \(1\leq{a}<10\), and n is an integer.

    Look at the numbers below. Which of the numbers is written in scientific notation?

    Number Scientific Notation? Explanation
    \(1\leq1.85<10\)

    \(\displaystyle 1.083\times

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    \)

    no \(0.82\times10^{14}\) no 0.82 is not \(10\times10^{3}\) no 10 is not < 10

    Now let’s compare some numbers expressed in both scientific notation and standard decimal notation in order to understand how to convert from one form to the other. Take a look at the tables below. Pay close attention to the exponent in the scientific notation and the position of the decimal point in the decimal notation.

    Large Numbers

    Small Numbers

    Decimal Notation Scientific Notation Decimal Notation Scientific Notation
    500.0 \(5\times10^{-2}\)
    80,000.0 \(8\times10^{-4}\)
    43,000,000.0 \(4.3\times10^{-7}\)
    62,500,000,000.0 \(6.25\times10^{-10}\)

    Convert from decimal notation to scientific notation

    To write a large number in scientific notation, move the decimal point to the left to obtain a number between 1 and 10. Since moving the decimal point changes the value, you have to multiply the decimal by a power of 10 so that the expression has the same value.

    Let’s look at an example.

    \(\begin{array}{r}180,000.=18,000.0\times10^{1}\\1,800.00\times10^{2}\\180.000\times10^{3}\\18.0000\times10^{4}\\1.80000\times10^{5}\\180,000=1.8\times10^{5}\end{array}\)

    Notice that the decimal point was moved 5 places to the left, and the exponent is 5.

    Example

    Write the following numbers in scientific notation.

    1. \(920,000,000\)
    2. \(10,200,000\)
    3. \(100,000,000,000\)

    [reveal-answer q=”628″]Show Solution[/reveal-answer]
    [hidden-answer a=”628″]

    1. \(\underset{\longleftarrow}{920,000,000}=920,000,000.0\), move the decimal point 8 times to the left and you will have \(9.2\times10^{8}\)
    2. \(\underset{\longleftarrow}{10,200,000}=10,200,000.0=1.02\times10^{7}\), note here how we included the 0 and the 2 after the decimal point. In some disciplines, you may learn about when to include both of these. Follow instructions from your teacher on rounding rules.
    3. \(\underset{\longleftarrow}{100,000,000,000}=100,000,000,000.0=1.0\times10^{11}\)

    [/hidden-answer]

    To write a small number (between 0 and 1) in scientific notation, you move the decimal to the right and the exponent will have to be negative, as in the following example.

    \(\begin{array}{r}\underset{\longrightarrow}{0.00004}=00.0004\times10^{-1}\\000.004\times10^{-2}\\0000.04\times10^{-3}\\00000.4\times10^{-4}\\000004.\times10^{-5}\\0.00004=4\times10^{-5}\end{array}\)

    You may notice that the decimal point was moved five places to the right until you got to the number 4, which is between 1 and 10. The exponent is \(−5\).

    Example

    Write the following numbers in scientific notation.

    1. \(0.0000000000035\)
    2. \(0.0000000102\)
    3. \(0.00000000000000793\)

    [reveal-answer q=”229054″]Show Solution[/reveal-answer]
    [hidden-answer a=”229054″]

    1. \(\underset{\longrightarrow}{0.0000000000035}=3.5\times10^{-12}\), we moved the decimal 12 times to get to a number between 1 and 10
    2. \(\underset{\longrightarrow}{0.0000000102}=1.02\times10^{-8}\)
    3. \(\underset{\longrightarrow}{0.00000000000000793}=7.93\times10^{-15}\)

    [/hidden-answer]

    In the following video you are provided with examples of how to convert both a large and a small number in decimal notation to scientific notation.

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    Convert from scientific notation to decimal notation

    You can also write scientific notation as decimal notation. Recall the number of miles that light travels in a year is \(5\times10^{-8}\) mm. To write each of these numbers in decimal notation, you move the decimal point the same number of places as the exponent. If the exponent is positive, move the decimal point to the right. If the exponent is negative, move the decimal point to the left.

    \(\begin{array}{l}5.88\times10^{12}=\underset{\longrightarrow}{5.880000000000.}=5,880,000,000,000\\5\times10^{-8}=\underset{\longleftarrow}{0.00000005.}=0.00000005\end{array}\)

    For each power of 10, you move the decimal point one place. Be careful here and don’t get carried away with the zeros—the number of zeros after the decimal point will always be 1 less than the exponent because it takes one power of 10 to shift that first number to the left of the decimal.

    Example

    Write the following in decimal notation.

    1. \(4.8\times10{-4}\)
    2. \(3.08\times10^{6}\)

    [reveal-answer q=”489774″]Show Solution[/reveal-answer]
    [hidden-answer a=”489774″]

    1. \(\underset{\longleftarrow}{4.8\times10^{-4}}=\underset{\longleftarrow}{.00048}\)
    2. \(\underset{\longrightarrow}{3.08\times10^{6}}=\underset{\longrightarrow}{3080000}\)

    [/hidden-answer]

    Think About It

    To help you get a sense of the relationship between the sign of the exponent and the relative size of a number written in scientific notation, answer the following questions. You can use the textbox to wirte your ideas before you reveal the solution.

    1. You are writing a number that is greater than 1 in scientific notation. Will your exponent be positive or negative?

    [practice-area rows=”1″][/practice-area]

    2. You are writing a number that is between 0 and 1 in scientific notation. Will your exponent be positive or negative?

    [practice-area rows=”1″][/practice-area]

    3. What power do you need to put on 10 to get a result of 1?

    [practice-area rows=”1″][/practice-area]
    [reveal-answer q=”824936″]Show Solution[/reveal-answer]
    [hidden-answer a=”824936″]
    1. You are writing a number that is greater than 1 in scientific notation. Will your exponent be positive or negative? For numbers greater than 1, the exponent on 10 will be positive when you are using scientific notation. Refer to the table presented above:

    Word How many thousands Number Scientific Notation
    million 1000 x 1000 = a thousand thousands 1,000,000 \(10^9\)
    trillion (1000 x 1000 x 1000) x 1000 = a thousand billions 1,000,000,000,000 \(10^{12}\)

    2. You are writing a number that is between 0 and 1 in scientific notation. Will your exponent be positive or negative? We can reason that since numbers greater than 1 will have a positive exponent, numbers between 0 and 1 will have a negative exponent. Why are we specifying numbers between 0 and 1? The numbers between 0 and 1 represent amounts that are fractional. Recall that we defined numbers with a negative exponent as \(10^{-2}\) we have \(\frac{1}{10\times10}=\frac{1}{100}\) which is a number between 0 and 1.

    3. What power do you need to put on 10 to get a result of 1? Recall that any number or variable with an exponent of 0 is equal to 1, as in this example:

    \(\begin{array}{c}\frac{t^{8}}{t^{8}}=\frac{\cancel{t^{8}}}{\cancel{t^{8}}}=1\\\frac

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    ={t}^{8 - 8}={t}^{0}\\\text{ therefore }\\{t}^{0}=1\end{array}\)

    We now have described the notation necessary to write all possible numbers on the number line in scientific notation.

    [/hidden-answer]

    In the next video you will see how to convert a number written in scientific notation into decimal notation.

    Thumbnail for the embedded element "Examples: Writing a Number in Decimal Notation When Given in Scientific Notation"

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    Multiplying and Dividing Numbers Expressed in Scientific Notation

    Numbers that are written in scientific notation can be multiplied and divided rather simply by taking advantage of the properties of numbers and the rules of exponents that you may recall. To multiply numbers in scientific notation, first multiply the numbers that aren’t powers of 10 (the a in \(a\times10^{n}\)). Then multiply the powers of ten by adding the exponents.

    This will produce a new number times a different power of 10. All you have to do is check to make sure this new value is in scientific notation. If it isn’t, you convert it.

    Let’s look at some examples.

    Example

    \(\left(3\times10^{8}\right)\left(6.8\times10^{-13}\right)\)

    [reveal-answer q=”395606″]Show Solution[/reveal-answer]
    [hidden-answer a=”395606″]Regroup using the commutative and associative properties.

    \(\left(3\times6.8\right)\left(10^{8}\times10^{-13}\right)\)

    Multiply the coefficients.

    \(\left(20.4\right)\left(10^{8}\times10^{-13}\right)\)

    Multiply the powers of 10 using the Product Rule. Add the exponents.

    \(20.4\times10^{-5}\)

    Convert 20.4 into scientific notation by moving the decimal point one place to the left and multiplying by \(10^{1}\).

    \(\left(2.04\times10^{1}\right)\times10^{-5}\)

    Group the powers of 10 using the associative property of multiplication.

    \(2.04\times\left(10^{1}\times10^{-5}\right)\)

    Multiply using the Product Rule—add the exponents.

    \(2.04\times10^{1+\left(-5\right)}\)

    Answer

    \(\left(3\times10^{8}\right)\left(6.8\times10^{-13}\right)=2.04\times10^{-4}\)

    [/hidden-answer]

    Example

    \(\left(8.2\times10^{6}\right)\left(1.5\times10^{-3}\right)\left(1.9\times10^{-7}\right)\)

    [reveal-answer q=”23947″]Show Solution[/reveal-answer]
    [hidden-answer a=”23947″]Regroup using the commutative and associative properties.

    \(\left(8.2\times1.5\times1.9\right)\left(10^{6}\times10^{-3}\times10^{-7}\right)\)

    Multiply the numbers.

    \(\left(23.37\right)\left(10^{6}\times10^{-3}\times10^{-7}\right)\)

    Multiply the powers of 10 using the Product Rule—add the exponents.

    \(23.37\times10^{-4}\)

    Convert 23.37 into scientific notation by moving the decimal point one place to the left and multiplying by \(10^{1}\).

    \(\left(2.337\times10^{1}\right)\times10^{-4}\)

    Group the powers of 10 using the associative property of multiplication.

    \(2.337\times\left(10^{1}\times10^{-4}\right)\)

    Multiply using the Product Rule and add the exponents.

    \(2.337\times10^{1+\left(-4\right)}\)

    Answer

    \(\left(8.2\times10^{6}\right)\left(1.5\times10^{-3}\right)\left(1.9\times10^{-7}\right)=2.337\times10^{-3}\)

    [/hidden-answer]

    In the following video you will see an example of how to multiply tow numbers that are written in scientific notation.

    Thumbnail for the embedded element "Examples: Multiplying Numbers Written in Scientific Notation"

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    In order to divide numbers in scientific notation, you once again apply the properties of numbers and the rules of exponents. You begin by dividing the numbers that aren’t powers of 10 (the a in \(a\times10^{n}\). Then you divide the powers of ten by subtracting the exponents.

    This will produce a new number times a different power of 10. If it isn’t already in scientific notation, you convert it, and then you’re done.

    Let’s look at some examples.

    Example

    \(\displaystyle \frac{2.829\times 1

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    }{3.45\times 1
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    }\)

    [reveal-answer q=”364796″]Show Solution[/reveal-answer]
    [hidden-answer a=”364796″]Regroup using the associative property.

    \(\displaystyle \left( \frac{2.829}{3.45} \right)\left( \frac

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    \right)\)

    Divide the coefficients.

    \(\displaystyle \left(0.82\right)\left( \frac

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    \right)\)

    Divide the powers of 10 using the Quotient Rule. Subtract the exponents.

    \(\begin{array}{l}0.82\times10^{-9-\left(-3\right)}\\0.82\times10^{-6}\end{array}\)

    Convert 0.82 into scientific notation by moving the decimal point one place to the right and multiplying by \(10^{-1}\).

    \(\left(8.2\times10^{-1}\right)\times10^{-6}\)

    Group the powers of 10 together using the associative property.

    \(8.2\times\left(10^{-1}\times10^{-6}\right)\)

    Multiply the powers of 10 using the Product Rule—add the exponents.

    \(8.2\times10^{-1+\left(-6\right)}\)

    Answer

    \(\displaystyle \frac{2.829\times

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    }{3.45\times
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    }=8.2\times
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    \)

    [/hidden-answer]

    Example

    \(\displaystyle \frac{\left(1.37\times10^{4}\right)\left(9.85\times10^{6}\right)}{5.0\times10^{12}}\)

    [reveal-answer q=”337143″]Show Solution[/reveal-answer]
    [hidden-answer a=”337143″]Regroup the terms in the numerator according to the associative and commutative properties.

    \(\displaystyle \frac{\left( 1.37\times 9.85 \right)\left(

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    \times
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    \right)}{5.0\times
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    }\)

    Multiply.

    \(\displaystyle \frac{13.4945\times

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    }{5.0\times
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    }\)

    Regroup using the associative property.

    \(\displaystyle \left( \frac{13.4945}{5.0} \right)\left( \frac

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    \right)\)

    Divide the numbers.

    \(\displaystyle \left(2.6989\right)\left(\frac{10^{10}}{10^{12}}\right)\)

    Divide the powers of 10 using the Quotient Rule—subtract the exponents.

    \(\displaystyle \begin{array}{c}\left(2.6989 \right)\left(

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    \right)\\2.6989\times
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    \end{array}\)

    Answer

    \(\displaystyle \frac{\left( 1.37\times

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    \right)\left( 9.85\times
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    \right)}{5.0\times
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    }=2.6989\times
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    \)

    [/hidden-answer]

    Notice that when you divide exponential terms, you subtract the exponent in the denominator from the exponent in the numerator. You will see another example of dividing numbers written in scientific notation in the following video.

    Thumbnail for the embedded element "Examples: Dividing Numbers Written in Scientific Notation"

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    Solve application problems

    Molecule of water with one oxygen bonded to two hydrogen.
    Water Molecule

    Learning rules for exponents seems pointless without context, so let’s explore some examples of using scientific notation that involve real problems. First, let’s look at an example of how scientific notation can be used to describe real measurements.

    Think About It

    Match each length in the table with the appropriate number of meters described in scientific notation below.

    The height of a desk Diameter of water molecule Diameter of Sun at its equator
    Distance from Earth to Neptune Diameter of Earth at the Equator Height of Mt. Everest (rounded)
    Diameter of average human cell Diameter of a large grain of sand Distance a bullet travels in one second
    Power of 10, units in meters Length from table above
    \(10^{9}\)
    \(10^{4}\)
    \(10^{0}\)
    \(10^{-5}\)
    \(10^{-10}\)

    [reveal-answer q=”993302″]Show Solution[/reveal-answer]
    [hidden-answer a=”993302″]

    Power of 10, units in meters Length from table above
    \(10^{9}\) Diameter of Sun at it’s Equator
    \(10^{4}\) Height of Mt. Everest (rounded)
    \(10^{0}\) The height of a desk
    \(10^{-5}\) Diameter of average human cell
    \(10^{-10}\) Diameter of water molecule

    [/hidden-answer]

    Red Blood Cells.
    Red Blood Cells

    One of the most important parts of solving a “real” problem is translating the words into appropriate mathematical terms, and recognizing when a well known formula may help. Here’s an example that requires you to find the density of a cell, given its mass and volume. Cells aren’t visible to the naked eye, so their measurements, as described with scientific notation, involve negative exponents.

    Example

    Human cells come in a wide variety of shapes and sizes. The mass of an average human cell is about \(10^{-6}\text{ meters }^3\).[3] Biologists have recently discovered how to use the density of some types of cells to indicate the presence of disorders such as sickle cell anemia or leukemia. [4] Density is calculated as the ratio of \(\frac{\text{ mass }}{\text{ volume }}\). Calculate the density of an average human cell.

    [reveal-answer q=”856454″]Show Solution[/reveal-answer]
    [hidden-answer a=”856454″]

    Read and Understand: We are given an average cellular mass and volume as well as the formula for density. We are looking for the density of an average human cell.

    Define and Translate: \(v=\text{volume}=10^{-6}\text{ meters}^3\), \(\text{density}=\frac{\text{ mass }}{\text{ volume }}\)

    Write and Solve: Use the quotient rule to simplify the ratio.

    \(\begin{array}{c}\text{ density }=\frac{2\times10^{-11}\text{ grams }}{10^{-6}\text{ meters }^3}\\\text{ }\\\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,=2\times10^{-11-\left(-6\right)}\frac{\text{ grams }}{\text{ meters }^3}\\\text{ }\\\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,=2\times10^{-5}\frac{\text{ grams }}{\text{ meters }^3}\\\end{array}\)

    If scientists know the density of healthy cells, they can compare the density of a sick person’s cells to that to rule out or test for disorders or diseases that may affect cellular density.

    Answer

    The average density of a human cell is \(2\times10^{-5}\frac{\text{ grams }}{\text{ meters }^3}\)

    [/hidden-answer]

    The following video provides an example of how to find the number of operations a computer can perform in a very short amount of time.

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    Earth in the foreground, sun in the background, light beams traveling from the sun to the earth.
    Light traveling from the sun to the earth.

    In the next example, you will use another well known formula, \(d=r\cdot{t}\), to find how long it takes light to travel from the sun to the earth. Unlike the previous example, the distance between the earth and the sun is massive, so the numbers you will work with have positive exponents.

    Example

    The speed of light is \(1.5\times10^{11}\) meters from earth, how many seconds does it take for sunlight to reach the earth? Write your answer in scientific notation.
    [reveal-answer q=”532092″]Show Solution[/reveal-answer]
    [hidden-answer a=”532092″]

    Read and Understand: We are looking for how long—an amount of time. We are given a rate which has units of meters per second and a distance in meters. This is a \(d=r\cdot{t}\) problem.

    Define and Translate:

    \(\begin{array}{l}d=1.5\times10^{11}\\r=3\times10^{8}\frac{\text{ meters }}{\text{ second }}\\t=\text{ ? }\end{array}\)

    Write and Solve: Substitute the values we are given into the \(d=r\cdot{t}\) equation. We will work without units to make it easier. Often, scientists will work with units to make sure they have made correct calculations.

    \(\begin{array}{c}d=r\cdot{t}\\1.5\times10^{11}=3\times10^{8}\cdot{t}\end{array}\)

    Divide both sides of the equation by \(3\times10^{8}\) to isolate t.

    \(\begin{array}{c}1.5\times10^{11}=3\times10^{8}\cdot{t}\\\text{ }\\\frac{1.5\times10^{11}}{3\times10^{8}}=\frac{3\times10^{8}}{3\times10^{8}}\cdot{t}\end{array}\)

    On the left side, you will need to use the quotient rule of exponents to simplify, and on the right, you are left with t.

    \(\begin{array}{c}\frac{1.5\times10^{11}}{3\times10^{8}}=\frac{3\times10^{8}}{3\times10^{8}}\cdot{t}\\\text{ }\\\left(\frac{1.5}{3}\right)\times\left(\frac{10^{11}}{10^{8}}\right)=t\\\text{ }\\\left(0.5\right)\times\left(10^{11-8}\right)=t\\0.5\times10^3=t\end{array}\)

    This answer is not in scientific notation, so we will move the decimal to the right, which means we need to subtract one factor of 10.

    \(0.5\times10^3=5.0\times10^2=t\)

    Answer

    The time it takes light to travel from the sun to the earth is \(5.0\times10^2=t\) seconds, or in standard notation, 500 seconds. That’s not bad considering how far it has to travel!

    [/hidden-answer]

    In the following video we calculate how many miles the participants of the New York marathon ran combined, and compare that to the circumference of the earth.

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    Summary

    Large and small numbers can be written in scientific notation to make them easier to understand. In the next section, you will see that performing mathematical operations such as multiplication and division on large and small numbers is made easier by scientific notation and the rules of exponents.

    Scientific notation was developed to assist mathematicians, scientists, and others when expressing and working with very large and very small numbers. Scientific notation follows a very specific format in which a number is expressed as the product of a number greater than or equal to one and less than ten, and a power of 10. The format is written \(1\leq{a}<10\) and n is an integer. To multiply or divide numbers in scientific notation, you can use the commutative and associative properties to group the exponential terms together and apply the rules of exponents.


    1. Orders of magnitude (mass). (n.d.). Retrieved May 26, 2016, from https://en.Wikipedia.org/wiki/Orders_of_magnitude_(mass)
    2. How Big is a Human Cell? ↵
    3. How big is a human cell? - Weizmann Institute of Science. (n.d.). Retrieved May 26, 2016, from www.weizmann.ac.il/plants/Milo/images/humanCellSize120116Clean.pdf↵
    4. Grover, W. H., Bryan, A. K., Diez-Silva, M., Suresh, S., Higgins, J. M., & Manalis, S. R. (2011). Measuring single-cell density. Proceedings of the National Academy of Sciences, 108(27), 10992-10996. doi:10.1073/pnas.1104651108 ↵
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    • Unit 11: Exponents and Polynomials, from Developmental Math: An Open Program. Provided by: Monterey Institute of Technology and Education. Located at: nrocnetwork.org/resources/downloads/nroc-math-open-textbook-units-1-12-pdf-and-word-formats/. License: CC BY: Attribution
    • Examples: Write a Number in Scientific Notation. Authored by: James Sousa (Mathispower4u.com) for Lumen Learning. Located at: https://youtu.be/fsNu3AdIgdk. License: CC BY: Attribution
    • Examples: Writing a Number in Decimal Notation When Given in Scientific Notation. Authored by: James Sousa (Mathispower4u.com) for Lumen Learning. Located at: https://youtu.be/8BX0oKUMIjw. License: CC BY: Attribution
    • Examples: Dividing Numbers Written in Scientific Notation. Authored by: James Sousa (Mathispower4u.com) for Lumen Learning. Located at: https://youtu.be/RlZck2W5pO4. License: CC BY: Attribution
    • Examples: Multiplying Numbers Written in Scientific Notation. Authored by: James Sousa (Mathispower4u.com) . Located at: https://youtu.be/5ZAY4OCkp7U. License: CC BY: Attribution

    4.4: Scientific Notation is shared under a not declared license and was authored, remixed, and/or curated by LibreTexts.

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