Back-of-the-Envelope Physics
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About this ebook
Physicists use “back-of-the-envelope” estimates to check whether or not an idea could possibly be right. In many cases, the approximate solution is all that is needed. This compilation of 101 examples of back-of-the-envelope calculations celebrates a quantitative approach to solving physics problems. Drawing on a lifetime of physics research and nearly three decades as the editor of The Physics Teacher, Clifford Swartz—a winner of two awards from the American Association of Physics Teachers—provides simple, approximate solutions to physics problems that span a broad range of topics. What note do you get when you blow across the top of a Coke bottle? Could you lose weight on a diet of ice cubes? How can a fakir lie on a bed of nails without getting hurt? Does draining water in the northern hemisphere really swirl in a different direction than its counterpart below the equator?
In each case, only a few lines of arithmetic and a few natural constants solve a problem to within a few percent. Covering such subjects as astronomy, magnetism, optics, sound, heat, mechanics, waves, and electricity, this book provides a rich source of material for teachers and anyone interested in the physics of everyday life.
“This is a book that will help make the study of physics fun and relevant.” —Mark P. Silverman, author of Waves and Grains: Reflections on Light and Learning
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Back-of-the-Envelope Physics - Clifford Swartz
Chapter
1
Force and Pressure
BED OF NAILS
Before making a bed of nails, every fakir should calculate the spacing of nails required for a comfortable night’s sleep. Begin by testing the nails to be used. Press a nail into convenient flesh with a force meter and measure the threshold force for pain.
If the threshold for pain is 10–1 N/nail, and if the fakir has a mass of 70 kg, then
If the affected area when lying on the bed of nails is 2 m x 30 cm = 6x10³ cm², and if all the nails act uniformly, then the area supported by each nail is
For comfort, the spacing should be 1 nail/cm. Try it out carefully before settling down for the night.
SIMPLE THUMBTACK
Most practical simple machines provide an impedance match between our soft hands and some hard or awkwardly shaped device. For instance, although there is some mechanical advantage in most screwdrivers, it is also important to have a handle that fits comfortably in the hand. The same is true for doorknobs and tweezers.
Consider the thumbtack as a simple machine. The diameter of the head of a typical thumbtack is 1.3 cm. The tack comes to a sharp point with indeterminate diameter, but it is about 0.03 cm. The ratio of areas is
The force you exert with your thumb (at the head!) is the same as the force exerted by the point. But the pressure is greater by a factor of about 2000. Of course, as soon as the point enters the material, the friction along the shaft of the tack increases. For a tack being pushed into wood, the friction would be large but necessary in order to keep the tack stuck, but to accomplish this we would need another simple machine, namely a hammer. A hammer exploits the impulse product of force and time. (See Fatal Impulse
later in this chapter.)
HORSEPOWER
In some English prisons long ago, inmates were required to walk on a treadmill that served as a power source to grind corn. How much power can a human provide?
Astandard experiment in introductory physics classes has students measure the power they produce by running upstairs. To average out the demands on their bodies, have them run up three flights of stairs, avertical distance of about 30 feet. (The height of school floors may vary.) A reasonable running time for a 65 kg young person might be 10 s.
Since 1 horsepower = 746 W, our hypothetical student was able for a short time to have an output of almost 1 hp. This is a popular exercise for students, but few can exert one horsepower for more than a few seconds. On the other hand, no horse could run up three flights of stairs.
Chinning is another popular exercise in strength tests. For a full chin-up, the body must rise about 55 cm. The work done in a chin-up is
W = (65 kg)(10 N/kg)(0.55 m) = 360 J.
It would take about one horsepower to do two chin-ups per second, an unlikely feat.
BUOYANCY IN AIR
Does your bathroom scale lie because you are being buoyed up by the air? Since most people can just about float in fresh water, the density of a human body must be about the same as that of water—1000 kg/m³. A human weighing 220 lb has a mass of 100 kg, and therefore a volume of 0.1 m³. The density of air is 1.3 kg/m³, so a human is buoyed up by the weight of 0.13 kg, which is a force of 1.3 N, or 0.29 lb. The weight that this heavy human reads on a bathroom scale is about one-third pound lighter than his actual weight.
The buoyancy on an object in air is ρa gV, where ρa is the density of air, and V is the volume of the object. The relative effect is
where ρo is the density of the object.
For brass, such as the weights on a balance, ρo = 9000 kg/m³, and the relative buoyancy effect is 0.01%. Some chemical balances are so sensitive that the air buoyancy must be taken into account.
HOW DENSE IS THE OCEAN?
In a first approximation to find the pressure in the atmosphere (see Height of Atmosphere), we assumed that the density of the air was a constant. That certainly isn’t true, but the assumption yielded the right order of magnitude for the height of the atmosphere.
How about the density of seawater in the ocean? Let’s find the pressure at great depths, and then calculate the density. Assuming constant density, the pressure is
P = P0 + (weight density) x (depth).
P0 is atmospheric pressure, which is insignificant. (In terms of equivalent pressure head,
it is only 10 m.)
The maximum recorded ocean depth is about 10 km in the Marianas Trench, east of the Philippines. The pressure at that depth is
P = (1 x 10⁴ N/m³)(1 x 10⁴ m) = 1 x 10⁸ N/m² = 1000 atm.
To find the change in density of water at this pressure, use the bulk modulus of water, which is
The minus sign accounts for the fact that as the pressure increases, the volume decreases.
The fractional change in volume is equal to the fractional change in density.
At that extreme depth, the water density has increased by only 5%. For most purposes, our assumption of constant density in calculating pressure in water is good enough. To look for greater accuracy would require taking into account other factors, such as salinity and temperature.
WASHBOWLS AND CORIOLIS FORCE
Legend has it that washbowls in the Northern Hemisphere drain counterclockwise and in the Southern Hemisphere clockwise. This behavior is supposed to be due to the Coriolis effect, which does indeed cause atmospheric hurricanes to turn counterclockwise in the Northern Hemisphere,
To find out if washbowls act the same as hurricanes, put in the numbers. Coriolis force is
The rotational velocity, ω, of the rotating reference frame (the Earth) is
A reasonable radial velocity for draining water in a washbowl is 1 m/s. For the component of perpendicular to the draining water, assume a factor of ½. Now compare the Coriolis acceleration with the gravitational acceleration.
The Coriolis acceleration is smaller than the gravitational acceleration by a factor of about 10⁵. Experiments done at M.I.T. confirm that the legend is wrong, except in the case of very elaborate procedures that control the symmetry of the bowl and the drainage and the establishment of noncirculating water before the drainage begins. The precision experiment in which the Coriolis force was detected was described by Ascher Shapiro in the December 15, 1962, edition of Nature, volume 196, page 1080.
POINTS OF CONTACT
In many cases, to a first approximation, dry sliding friction is independent of the surface area involved. That’s strange! Dry friction is caused by breaking the small welds between surface features, and by plowing through the uneven surface. Why shouldn’t friction depend on the number of these contact points, and thus the surface area? In fact, it does, but very few surface points are actually in contact—as we shall see.
Consider a 1kg steel block sliding on steel. Even polished steel is pitted and mountainous on the atomic level. The force of repulsion at points in contact is 5 x 10–9 N/atom (see Binding Force of Atoms). The force per atom times the number of atoms in contact must equal the weight of the l kg block that is being supported.
(5 x 10–9 N/atom) x # of atoms = 10 N
# of atoms = 2 x 10⁹.
Each atom with a diameter of 2 x 10–10 m covers an area of 4 x 10–20 m². The area covered by the supporting atoms is
(2 x 10⁹ atoms) x (4 x 10–20 m²/atom)
= 8 x 10–11 m² = 8 x 10–7 cm².
The 1 kg steel block has a volume of . If the block is cubic, it will be 5 cm on each side and have a face area of 25 cm². However, only 8 x 10–7 cm² is in actual contact.
Even if the block were 25 cm x 5 cm x 1 cm and placed so that the apparent area of contact were 125 cm², or 5 cm², the actual contact area would still be 8 x 10–7 cm².
ATMOSPHERIC FORCE
Everyone likes to see things squash. A standard physics demonstration is to create a vacuum in a rectangular metal can. As the air pressure in the metal can is reduced, the can collapses. The friendly atmosphere in which we are all submerged can create enormous unbalanced forces on surfaces that have a vacuum on one side. The atmospheric pressure is only 14.7 lb/in² = 1 x 10⁵ N/m², but the total force exerted is the pressure times the area.
A typical one-gallon can has a height of 24 cm and width of 15 cm. The area of one side is (24 cm) x (15 cm) = 360 cm² = 3.6 x 10–2 m². The force exerted on that side is (1 x 10⁵ N/m²) (3.6 x 10–2 m²) = 3.6 x 10³ N.
Let’s convert that value into more familiar units. A person with a mass of 100 kg weighs 980 N, which is only about one-fourth of the atmospheric force on the can. That person is heavy but could stand on the gallon can without collapsing it. Another way to view the magnitude of the atmospheric force on the can is this: 1000 kg weighs 1 metric tonne or 2200 lb or 9.8 x 10³ N. The atmospheric force on the can is
Air pressure can exert much larger forces. It can (and does) support cars and heavy trucks (see, the next section, Weighing Your Car
). In some particle accelerator laboratories with huge beam-deflecting magnets that must be positioned very precisely, the magnets are floated into place. The bottom of the magnet frame is made slightly concave, and there is a rubber flange around the outer edge. Compressed air is piped into the hollow region at a gauge pressure of one or two atmospheres. The heavy magnet rises up a few millimeters and can then be delicately maneuvered.
The bottom of a 10-ton magnet might be 1 m x 2 m. The area is 2 m². If the gauge pressure (pressure above atmospheric) is 1 atm (half that in a car tire), the