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Chapter 1: Problem 4

The density of lead is 11.3 \(\mathrm{g} / \mathrm{cm}^{3} .\) What is this value in kilograms per cubic meter?

Short Answer

Expert verified
The density of lead is 11,300 kg/m³.

Step by step solution

01

Convert Grams to Kilograms

The density given is in grams per cubic centimeter \(11.3\, \text{g/cm}^3\). To convert grams to kilograms, know that 1 gram is \(0.001\) kilograms. Therefore, \(11.3\, \text{g/cm}^3\) becomes \(11.3 \times 0.001 \) kilograms per cubic centimeter, which equals \(0.0113\, \text{kg/cm}^3\).
02

Convert Cubic Centimeters to Cubic Meters

Since 1 meter is 100 centimeters, \(1 \text{cm}^3\) equals \((1/100)^3 = 1/1,000,000\) cubic meters. Therefore, to convert from \(\text{kg/cm}^3\) to \(\text{kg/m}^3\), multiply the current value \(0.0113 \text{kg/cm}^3\) by \(1,000,000\) to get the density in \(\text{kg/m}^3\).
03

Calculate the Density in Kilograms per Cubic Meter

By multiplying \(0.0113 \text{kg/cm}^3\) by \(1,000,000\), the result is \(11,300 \text{kg/m}^3\), which is the density of lead in kilograms per cubic meter.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Unit Conversion
Unit conversion is the process of converting a measurement from one unit to another. This is essential when dealing with different systems of measurement. Understanding unit conversion helps in recognizing and comparing quantities that might otherwise seem unrelated.

In the given exercise, we began with a density in grams per cubic centimeter and needed to convert it to kilograms per cubic meter. This involved two key conversions: grams to kilograms and cubic centimeters to cubic meters.

To convert from grams to kilograms, remember that 1 gram equals 0.001 kilograms. When converting volumes, knowing that 1 cubic centimeter is equal to 0.000001 cubic meters is crucial. These conversion factors allow us to switch between units seamlessly.
  • For mass: Multiply grams by 0.001 to obtain kilograms.
  • For volume: Multiply cubic centimeters by 1,000,000 to obtain cubic meters.
By applying these conversions, you can change the units systematically to match the desired SI units.
Density Calculation
Density is a measure of how much mass is contained in a given volume. It is often expressed in units of mass per unit volume, like grams per cubic centimeter or kilograms per cubic meter.

In the context of the provided exercise, the density of lead is initially given as 11.3 grams per cubic centimeter. To better understand density, it's useful to imagine it as a comparison between how heavy something is and how much space it occupies. A higher density indicates a greater amount of mass packed into a specific space.

When converting density from one unit to another, such as to obtain it in kilograms per cubic meter, calculation adjustments are vital. Here, we first converted the mass units, then the volume units. Keep in mind that the value of the density will appear numerically larger when both the mass unit grows (as in kg) and the volume unit shrinks (as in \(m^3\)).
  • Start with the given density value.
  • Convert the mass unit (grams to kilograms).
  • Convert the volume unit (cubic centimeters to cubic meters).
  • Multiply the transformed value to find the new density.
SI Units
SI (International System of Units) is a globally standardized system of measurements, often used in scientific and technical fields. It allows for universal clarity and precision when sharing data and conducting experiments.

In density measurements, the SI unit for mass is the kilogram, and for volume, it is the cubic meter. Therefore, the SI unit for density is expressed in kilograms per cubic meter (\(\text{kg/m}^3\)).

Using SI units in calculations such as density conversion ensures consistency in scientific communication and helps eliminate confusion due to varying measurement systems. Whether you're an engineer designing materials or a chemist solving practical problems, understanding and utilizing SI units is crucial.
  • SI units simplify global communication and scientific sharing.
  • Kilograms and cubic meters are the SI units for mass and volume, respectively.
  • Densities in the SI unit have the format \(\text{kg/m}^3\).
By converting to SI units, you align your results with international standards, making sure your work is understood and respected worldwide.

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Most popular questions from this chapter

Getting Back. An explorer in the dense jungles of equatorial Africa leaves his hut. He takes 40 steps northeast, then 80 steps \(60^{\circ}\) north of west, then 50 steps due south. Assume his steps all have equal length. (a) Sketch, roughly to scale, the three vectors and their resultant, (b) Save the explorer from becoming hopelessly lost in the jungle by giving him the displacement, calculated using the method of components, that will return him to his hut.

Vector \(\vec{A}\) is 2.80 \(\mathrm{cm}\) long and is \(60.0^{\circ}\) above the \(x\) -axis in the first quadrant. Vector \(\vec{B}\) is 1.90 \(\mathrm{cm}^{2}\) long and is \(60.0^{\circ}\) below the \(x\) -axis in the fourth quadrant (Fig. 1.35\() .\) Use components to find the magnitude and direction of (a) \(\vec{A}+\vec{B}\) (b) \(\vec{A}-\vec{B} ;\) (c) \(\vec{B}-\vec{A}\) In each case, sketch the vector addition or subtraction and show that your numerical answers are in qualitative agreement with your sketch.

You are camping with two friends, Joe and Karl. Since all three of you like your privacy, you don't pitch your tents close together. Joe's tent is 21.0 \(\mathrm{m}\) from yours, in the direction \(23.0^{\circ}\) south of east. Karl's tent is 32.0 \(\mathrm{m}\) from yours, in the direction \(37.0^{\circ}\) north of east. What is the distance between Karl's tent and Joe's tent?

The most powerful engine available for the classic 1963 Chevrolet Corvette Sting Ray developed 360 horsepower and had a displacement of 327 cubic inches. Express this displacement in liters \((\mathrm{L})\) by using only the conversions \(1 \mathrm{L}=1000 \mathrm{cm}^{3}\) and \(1 \mathrm{in.}=2.54 \mathrm{cm} .\)

(a) Use vector components to prove that two vectors commute for both addition and the scalar product. (b) Prove that two vectors anticommute for the vector product; that is, prove that \(\overrightarrow{\boldsymbol{A}} \times \overrightarrow{\boldsymbol{B}}=-\overrightarrow{\boldsymbol{B}} \times \overrightarrow{\boldsymbol{A}}\).
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