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Chapter 1: Problem 18

Indicate whether each of the following is an exact number or a measured quantity subject to uncertainty. (a) the number of pages in this text (b) the number of days in the month of January (c) the area of a city lot (d) the distance between the centers of the atoms in a gold medal

Short Answer

Expert verified
(a) Exact number (b) Exact number (c) Measured quantity (d) Measured quantity

Step by step solution

01

Assessing The Number of Pages in the Text

The number of pages in a text is an exact count. We can simply flip through the pages and count them, so there is no uncertainty in this number.
02

Assessing The Number of Days in January

The number of days in January is exact as it's defined by the Gregorian calendar. Every January has specifically 31 days, so there is no uncertainty.
03

Assessing The Area of a City Lot

The area of a city lot is subject to measurement. Even though we can obtain a precise value from a blueprint, it is subject to uncertainty based on the accuracy of the measurement devices and techniques used. Therefore, it's a measured quantity.
04

Assessing The Distance Between Atomic Centers in a Gold Medal

The distance between the centers of the atoms in a gold medal is likely measured through scientific methods and devices and cannot be counted exactly. Therefore, it's a measured quantity and subject to uncertainty.

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Key Concepts

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

Uncertainty in Measurements
In the world of science, measurements are key to understanding and discovering new insights. However, there is always a degree of uncertainty in any measurement we take. This uncertainty arises because every measuring instrument has inherent limitations, which affects the precision of the measurement. Measurements are never exact; instead, they can only approximate true values within certain margins of error.
Instruments could be well-calibrated, but variations can still occur due to factors such as:
  • Human error in reading measurements
  • Instrumental errors due to faulty tools
  • Environmental influences like temperature fluctuations
This is why scientists often present measurements along with an uncertainty range or a possible error margin. By acknowledging uncertainty, scientists can more accurately convey the reliability and limitations of their data, leading to better scientific conclusions. Thus, when measuring anything from the area of a city lot to the atomic distances in substances, there is always some level of uncertainty involved.
Scientific Measurements
Scientific measurements help us interpret the natural world, especially in fields such as physics, chemistry, and biology. Science relies on standardized systems of units, like the metric system, to ensure that measurements are consistent and comparable. These measurements allow for reliable experiments and accurate data collection, helping scientists derive meaningful conclusions.

A key aspect of scientific measurements is the significant figures, which include all the digits that are known precisely plus one final digit that is estimated. The use of significant figures provides a way to communicate the precision of a measurement. For instance, while measuring the distance between the centers of atoms in a gold medal, scientists use advanced equipment capable of measuring values at a microscopic scale. Although the measurements are very precise, they are not exact and include an uncertainty aspect alongside them.
Such precision underscores the importance of scientific measurements in acquiring accurate data, allowing researchers to explore both macroscopic and microscopic worlds with confidence.
Exact Counts
Exact counts refer to quantities that are precisely known and are devoid of any uncertainty. These values are not derived from measurements but rather from the act of counting items, such as pages in a book or days in a month. Unlike measured quantities, no uncertainty is associated with exact counts because they deal with whole, indivisible units.
Examples of exact counts include:
  • The number of pages in a textbook. Simply count them, and you'll arrive at the exact number.
  • The number of students in a classroom. Counting each individual provides an exact figure.
  • The number of days in January, which is always 31 according to the calendar.
Exact counts are straightforward and simplify computations and logical conclusions as they provide a solid foundation without any need to account for variability or error.

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Most popular questions from this chapter

As mentioned on page \(13,\) the MCO was lost because of a mix-up in the units used to calculate the force needed to correct its trajectory. Ground-based computers generated the force correction file. On September \(29,1999,\) it was discovered that the forces reported by the ground-based computer for use in MCO navigation software were low by a factor of \(4.45 .\) The erroneous trajectory brought the MCO \(56 \mathrm{km}\) above the surface of Mars; the correct trajectory would have brought the MCO approximately \(250 \mathrm{km}\) above the surface. At \(250 \mathrm{km},\) the MCO would have successfully entered the desired elliptic orbit. The data contained in the force correction file were delivered in lb-sec instead of the required SI units of newton-sec for the MCO navigation software. The newton is the SI unit of force and is described in Appendix B. The British Engineering (gravitational) system uses a pound (lb) as a unit of force and \(\mathrm{ft} / \mathrm{s}^{2}\) as a unit of acceleration. In turn, the pound is defined as the pull of Earth on a unit of mass at a location where the acceleration due to gravity is \(32.174 \mathrm{ft} / \mathrm{s}^{2} .\) The unit of mass in this case is the slug, which is \(14.59 \mathrm{kg}\). Thus, BE unit of force \(=1\) pound \(=(\text { slug })\left(\mathrm{ft} / \mathrm{s}^{2}\right)\) Use this information to confirm that BE unit of force \(=4.45 \times\) SI unit of force 1 pound \(=4.45\) newton

A class of 84 students had a final grade distribution of 18\(\%\) A's, 25\(\%\) B's, 32\(\%\) C's, 13\(\%\) D's, 12\(\%\) F's. How many students received each grade?

A pycnometer (see Exercise 78 ) weighs 25.60 g empty and \(35.55 \mathrm{g}\) when filled with water at \(20^{\circ} \mathrm{C}\) The density of water at \(20^{\circ} \mathrm{C}\) is \(0.9982 \mathrm{g} / \mathrm{mL}\). When \(10.20 \mathrm{g}\) lead is placed in the pycnometer and the pycnometer is again filled with water at \(20^{\circ} \mathrm{C}\), the total mass is \(44.83 \mathrm{g}\). What is the density of the lead in grams per cubic centimeter?

We want to mark off a thermometer in both Celsius and Fahrenheit temperatures. On the Celsius scale, the lowest temperature mark is at \(-10^{\circ} \mathrm{C},\) and the highest temperature mark is at \(50^{\circ} \mathrm{C} .\) What are the equivalent Fahrenheit temperatures?

Perform the following conversions from non-SI to SI units. (Use information from the inside back cover, as needed.) (a) 68.4 in. \(=\)________cm (b) \(94 \mathrm{ft}=\)________m (c) \(1.42 \mathrm{lb}=\)________g (d) \(248 \mathrm{lb}=\)________kg (e) \(1.85 \mathrm{gal}=\)________dm\(^3\) (f) \(3.72 \mathrm{qt}=\)________mL
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