Mean free path /
Collision cross section / l-σ relation
In this section,
Feynman discusses the mean free path, the collision cross section, and the l-σ relation that connects them. These
ideas resolve a paradox in kinetic theory of gases: if gas molecules move
at high speeds, why do gases mix and diffuse slowly? The answer is that molecules
do not travel unimpeded in straight lines, but they undergo incessant collisions
in a chaotic random walk. The concept of mean free path was introduced by
Clausius in his 1858 paper On the mean lengths of the paths described by the
separate molecules of gaseous bodies, where he provided the first
quantitative description of the average distance traveled by a molecule between
successive collisions.
1. Mean free path
“If we say that the average
time between collisions is τ, and that the molecules have a mean
velocity v, we can expect that the average distance between
collisions, which we shall call l, is just the product
of τ and v. This distance between collisions is usually called
the mean free path:
Mean
free path l = τv (Feynman et al., 1963).”
A Comprehensive
Definition of Mean Free Path
The mean
free path (l) is the
average distance a particle travels between successive collisions in a dilute
gas. It is a statistical quantity that links the microscopic collisions to
macroscopic transport phenomena such as diffusion, viscosity, and thermal
conductivity.
Kinematic
Perspective: It is the product of the particle's mean speed (v) and the mean
collision time (t), l(v) = v
t(v), which is directly related to the Maxwellian speeds.
Geometric
Perspective: For identical hard-spheres with diameter (d) and number
density (n), the collision cross section is s = pd^2. Under the
stationary target assumption, the mean free path is l =1/ns—it is inversely
proportional to both number density and collision cross-section.
Statistical Perspective: The collision-free
distances follow an exponential distribution, P(x)=(1/l)e^{-x/l], where P(x) is
the probability that a particle travels a distance x. Thus, most particles
travel less than l, while relatively
fewer travel longer without any collision.
Thermodynamic
Perspective: the mean free path also depends on the macroscopic states, e.g., at
constant pressure, l = kT/(Ö2)sp, so increasing the
temperature increases the mean free path.
Thus, the mean free path is more than a
simple average distance between collisions. It is a unifying parameter that connects
the kinematics of particle motion, the geometry of molecular encounters, the
statistics of random collisions, and the thermodynamic state of the gas.
The Stationary-Target model
Feynman’s formula is
based on a simplifying assumption: all scattered molecules (targets) are
treated as if they were stationary relative to the moving molecule. In reality,
every molecule is moving with a high speed. What determines the collision rate
is therefore not the speed of a single molecule relative to the laboratory, but
the relative speed between pairs of molecules.
Suppose two identical
molecules have velocity vectors v1 and v2, the
relative velocity is
vrel = v1
- v2
The mean-square relative speed is
<vrel2>
= <(v1 - v2)2>
Expanding the
squares gives,
<vrel2>
= <v12> + <v22>
- 2<v1·v2>
In thermal equilibrium, the velocities of different molecules are
uncorrelated, so <v1·v2> = 0
Since the molecules are identical,
<v12>
= <v22> = <v2> Þ <vrel2> = 2<v2>.
Taking the square root gives the mean relative speed
vrel = (Ö2)v
where (v) denotes the corresponding root-mean-square molecular
speed.
Physically, this
means that collisions occur Ö2 times more
frequently than predicted by the stationary-target model because every moving
molecule contributes to the relative motion.
Note: In the audio
recording (15 min: 45 sec) of this lecture, Feynman says something like: “Let’s say the nuclides are standing still…”, but
this assumption is not included by the editors. The stationary-target model is
intended as a simplification rather than an accurate derivation.
2. Collision cross
section
“By ‘collision cross
section’ we mean the area within which the center of our particle must be
located if it is to collide with a particular molecule. (Feynman et al.,
1963).”
The collision cross
section, usually denoted by s, is a measure of
the probability that two particles will collide or interact when they approach
one another. Although it has the dimensions of an area, it should not always be
interpreted as the particle's actual physical size. In the classical
hard-sphere model, the collision cross-section is a fixed geometric area, which
is independent of direction of approach. However, in Maxwell’s (1867) kinetic
theory, the force between molecules is assumed to vary inversely as the fifth
power of their separation. Under this assumption, the collision cross-section
is no longer constant but varies inversely with the relative speed of the
molecules. In general,
the collision cross‑section is not a single, immutable number but
a dynamical quantity—an effective interaction area that depends on the
forces, speeds, and nature of the particles involved. It is the fundamental
parameter that governs how frequently particles scatter, how far they travel
between collisions, and ultimately how gases conduct heat, diffuse, and flow.
“If molecules were little
spheres (a classical picture) we would expect that σc=π(r1+r2)2,
where r1 and r2 are the radii of the
two colliding objects (Feynman et al., 1963).”
A Feynman-Style Explanation of the Collision Cross
Section
Imagine
a large male dancer standing in the middle of a crowded dance floor. Let
us say he has a radius R. Moving through the crowd is a smaller female
dancer with radius r. Both are free to move, but to keep things
simple, let us freeze the large dancer and let only the smaller one move.
Now the question
is: When do they “collide”?
A casual observer might
say, "When her elbow touches his belly." But for a physicist, that’s
sloppy thinking. We can ignore the complicated shapes of bodies and keep track
of their centers. At the instant the two dancers just graze one
another—when her shoulder just brushes his arm—the distance between their
centers is neither R nor r. It is the sum: R + r.
Why? Her center is one r away from her edge, and his center is one R away
from his edge. When the two surfaces just touch, the centers must be
separated by the sum of their radii.
Now comes the
clever trick.
Keeping track of
two moving objects with finite size is inconvenient. So we cheat. We shrink the
smaller dancer down to a mathematical point. Of course, doing that would change
the physics—however, we can transfer the smaller dancer’s radius to the larger
dancer.
Mathematically, the
larger dancer acquires an effective radius R+r.
In other words, we
can idealize the female dancer as a point zipping around, and the male dancer
becomes am inflated stationary target. She will collide with him if her center
ever reaches a circle of radius R+r centered on him.
What's the
collision cross-section then?
It is simply the
area of that inflated target—the area of a circle with radius (R+r):
s = p(R+r)2
What does it mean?
The collision cross
section is determined not by the size of either particle alone, but by the
combined radius of both particles. Collisions depend on how close the centers
of the particles can approach, not simply on the so-called physical size of one
particle.
However, this is
only the beginning. One may modify the explanation or analogy to include, for
example, the interaction forces, relative speeds, and quantum effects.
3. l-σ relation
“… if we write it as σcn0l=1.
(43.12). This formula can be thought of as saying that there should be one
collision, on the average, when the particle goes through a distance l in
which the scattering molecules could just cover the total area. In
a cylindrical volume of length l and a base of unit area, there
are n0l scatterers; if each one has an area σc the
total area covered is n0lσc, which is just one unit
of area (Feynman et al., 1963).”
According to Feynman,
the formula σnl = 1 can be
visualized as follows: a particle traveling a distance l sweeps
out a cylindrical volume of cross-sectional area σ. On the average, this cylinder
contains exactly one scattering target, so one collision is expected over that
distance. However, this formula rests on a hidden assumption:
the scattering molecules are treated as stationary targets, which is not
realistic. For a gas of identical molecules obeying the Maxwell-Boltzmann
distribution, the average relative speed of two colliding molecules exceeds the
mean molecular speed by a factor of Ö2. This correction results
in l = 1/(Ö2)nσ, which implies: nlσ = 1/Ö2 » 0.707, not 1. Thus, the relation nlσ = 1 is an approximation—a
pedagogical device for grasping the scaling behavior, but not the exact
statistical result. It is also known as the l-s relation, which
expresses the inverse proportionality between the mean free path and the
collision cross‑section: larger cross‑section, shorter path; smaller cross‑section,
longer path. Its true value lies not in numerical precision but in the physical
intuition it provides.
Real-World Nuance:
It's Not Just Physical Size!
The l-σ relation provides a
simple geometric picture of molecular collisions, allowing the concept of mean
free path intuitively accessible. However, its simplicity comes at the cost of
accuracy. Here are some key limitations.
1. Charged
Particles: Attractive forces can pull particles together from distances far larger
than their physical dimensions, effectively increasing the collision cross
section, whereas repulsive forces can deflect particles before they come close,
shrinking it.
2. Speed Dependence: At high relative speeds,
particles zip past one another so quickly that they barely have time to feel
the force—the effective cross‑section shrinks. At low speeds, they interact for
longer periods, allowing attractive or repulsive forces to exert a greater
influence and thereby modifying the collision probability.
3. Quantum
Effects: At atomic and subatomic scales, the de Broglie wavelength of a
particle can become effectively larger, diffraction and interference effects then
alter the effective cross‑section in ways that have nothing to do with physical size.
Thus, while the
geometric picture provides a useful starting point, the collision cross section
is essentially a measure of interaction probability, shaped by interaction
forces, relative motion, and, in many cases, quantum mechanics. Thus, the mean
free path is ultimately determined not simply by geometry, but by the
underlying physics governing particle interactions.
Key Takeaways:
1. Mean Free Path: The Average
Distance Between Collisions
The mean free path is
the average distance a particle travels between successive collisions. It is
not the distance traveled by every particle, but rather the statistical average
of many randomly distributed free-flight distances.
2. Collision Cross
Section: The Effective Interaction Area
The collision cross
section measures the probability that two particles will collide or interact.
Although it has units of area, it should generally be interpreted as an
effective interaction area rather than the particle’s “actual” geometric size.
For ideal hard spheres, the cross-section is simply a geometric area, but for
real molecules or ions, it depends on interaction force, relatively velocity,
and quantum effects.
3. The l-σ Relation: Geometry Meets
Probability
The formula nlσ =
1 means that, on average, a particle traveling a distance
In short, the
collision cross section tells us how large a target a particle presents, while
the mean free path tells us how far a particle typically moves before hitting another.
Increasing the number density of particles or enlarging their effective
collision cross section increases the collision frequency and shortens the mean
free path. This simple idea forms the microscopic foundation of diffusion, electrical
conduction, viscosity, and many other transport phenomena.
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A Real-Life
Application: The Science of Fart Odor Transport The Source: Chemistry
and Transport Physics The characteristic
odor flatulence arises from volatile sulfur compounds, such as hydrogen sulfide
and methanethiol. Although these compounds make up only a tiny fraction of
the gas mixture, the human nose is remarkably sensitive to them. Once release, the
odor molecules undergo a multi-stage process:
Together,
advection, convection, and diffusion result in how quickly the odor spreads. Why Distance
Matters There is no sharp
boundary beyond which an odor suddenly vanishes—the concentration decreases
continuously as the molecules disperse. The farther one
stands from the source, the more the odor has been diluted by mixing with the
air. Consequently, fewer odor molecules reach the olfactory receptors in the
nose, reducing the probability that the smell exceeds the human detection
threshold. Ventilation, air
currents, room geometry, humidity, and temperature all affect the diffusion
rate. In a poorly ventilated room, an odor may linger for several minutes;
with good airflow, it dissipates in seconds. The Probabilistic
Nature of Smell Detecting an odor
is fundamentally a probabilistic process. At high
concentrations, a large number of odor molecules reach the nose every second,
making detection almost certain. As the concentration falls, fewer molecules
arrive, and the likelihood of detecting the smell decreases. Eventually the
concentration drops below the detection threshold, and the odor becomes
imperceptible, even though a small number of molecules may still be present. Practical
Takeaways To minimize
significant olfactory exposure:
Conclusion The next time a
social situation requires a scientific description of “safety distance,” you
can respond with a blend of statistical mechanics and social grace: “Please maintain
a radius of about three meters—or roughly two exponential decay lengths from
the source—to guarantee negligible odor.” However, Feynman
might have concluded it as follows: The molecules
don’t know whether they’re carrying perfumes or unhealthy fumes—they
simply obey the laws of physics. |
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The Moral of the Lesson: Mean Free Path and COVID‑19 The concept of mean
free path provides a useful way of thinking about the spread of airborne
diseases such as COVID-19. In this context, however, the idea appears in two
different forms (Fernández-Terán et al., 2020). At the microscopic level, it
describes how far virus-laden aerosols travel before colliding with another air
molecule. At the macroscopic level, it serves as an analogy for the distance
traveled by individuals in a crowd before encountering an infected person. 1. Safe
Distancing: Dilution of Aerosol Concentration An infected individual
continuously emits viral-laden aerosols through breathing, speaking, or
sneezing. These aerosols are initially most concentrated near the source. As
they spread through diffusion, gravitational settling, and ventilation, their
concentration decreases (sometimes exponentially) with distance from the
source. By increasing the physical separation between individuals, the
aerosol concentration is effectively lowered. Statistically, a lower
concentration means fewer virus-containing aerosols enter the breathing zone
of an individual and therefore a lower probability of inhaling an infectious dose. 2. Wearing a
Mask: Increasing the Probability of Collisions A mask is not a
simple sieve. It is a complex three‑dimensional network of microscopic fibers
that acts as a highly efficient particle filter. From the perspective of an
incoming viral aerosol, the fibers form a dense array of collision
targets. Without a mask: The
air is equivalent to a low density of solid obstacles, allowing aerosols to
move relatively unobstructed into the respiratory tract. With a mask: The probability
of an aerosol encountering and adhering to a fiber increases dramatically.
The result is a substantial reduction in the number of virus-laden aerosols
that penetrate the filter and reach the lungs. 3. The Selection
of Masks The effectiveness
of a mask can be intuitively understood through the formula σnl = 1: σ is the “effective” collision
cross-section. n is the fiber
number density (or density of collision targets). l is the mean free
path. A useful analogy:
increasing the number density of collision targets and their effective cross
section reduces the distance a particle can move before an interaction
occurs. This is why effective respirators (e.g., N95) fulfil the formula by
combining a dense fiber network with suitable material to enhance aerosol
capture. The goal is not to eliminate all aerosol motion but to maximize the
chance that viral aerosols are intercepted before reaching the respiratory
system. Conclusion: COVID-19 transmission
is not solely a problem for epidemiologists—it is also a problem in transport
physics. By understanding the mean free path and collision cross-section, we
can design effective interventions: safe distancing lengthens the total path
particles must travel and masks reduce mean free path. Together, they lower
the probability that viral aerosols complete their journey from one person to
another. A Note on COVID‑19
and Long-Term Health Risks Researchers
continue to investigate the long-term consequences of SARS‑CoV‑2 infection,
which extend beyond the acute respiratory phase to encompass potential
effects on the cardiovascular, neurological, and respiratory systems (Tanrıverdi,
2024). Emerging evidence has also raised questions about possible links
between COVID‑19 and cancer development. However, it is important to
emphasize that current evidence remains preliminary, and no definitive causal
relationship between COVID-19 and can cancer has been established. The field
is still emerging, and further research is needed to clarify the underlying
mechanisms and quantify long-term risks. This reinforces the importance of
understanding aerosol transport: reducing exposure to viral droplets is not
just about acute infection, but potentially about long‑term health
consequences. |
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Richard P.
Feynman To Yetta Farber, MARCH 30, 1982
Dear Yetta, Naturally I
could never understand why the girls I went out with in Ithaca wouldn’t go
out with me again. At last I find out—it was my brown leather jacket! So often, was I
thus frustrated by pretty girls (like you) that I came out to California.
Since the weather was so much better I threw away my leather jacket and at
last found someone who would go out with me more than once—so I married her. I always thought
that the girls in California were more tolerant—but now I know the inner
workings of the phenomenon. Physics is much easier to understand. Your former
date, Richard
P. Feynman Feynman’s
humorous letter about his brown leather jacket provides a valuable lesson in
transport phenomena. The tragedy of Feynman’s dating life in Ithaca, New
York, is not a charming anecdote—it is a real-world lesson in transport
theory, molecular diffusion, and the physics of dating. The Moral of the
Lesson: Feynman’s Jacket Odor and the Mean Free Path 1. The Source: A
Reservoir of Odor Molecules A well-worn
leather jacket can act as a reservoir of volatile organic molecules (sweat,
bacteria, and skin oils…). These molecules continuously evaporate from the
jacket, creating a region of elevated odor around the jacket. 2. The Mean Free
Path In short, the diffusion
is slow and the mean free path is tiny.
3. Why Proximity
Matters The concentration
of odor molecules decreases with distance from the source. At a distance:
When Feynman first met someone, he was standing far enough away that the flux
of odor molecules reaching the girl’s nose was negligibly small. The
"collision cross-section" of her olfactory receptors didn’t get
enough molecules to trigger a warning. During a date:
Once in close proximity—sitting across a table or walking side by side—the
separation distance decreased and the exposure time increased. Under these
conditions, enough odor molecules could diffuse to the olfactory receptors to
confirm the jacket as a source. A Reflection: The
Hidden Variable The most amusing
aspect of Feynman’s story is that he initially searched for the explanation
in the wrong place. He thought the difference lay between the women of Ithaca
and those of California. Eventually, he discovered that the “unknown”
variable was neither geography nor human psychology, but his jacket. This is
a lesson familiar to every physicist: when observations disagree with
expectations, look for a hidden variable before constructing a new theory. The Ultimate
Takeaway In physics, as in
dating, proximity changes everything. Thanks to a short
mean free path, diffusion is inherently slow. A localized hazard—whether odor
molecules, viral aerosols, or any other unwanted transport—can remain
completely undetectable at a distance. The flux across a short distance could
be surprisingly fast; you cannot rely on the sluggishness of diffusion to
protect you. To lower the
hazard rate of an undesirable transport process, do not rely on slow
diffusion to save you—change the boundary conditions by eliminating the
source at the boundary. And, for heaven’s sake, throw away the jacket or at
least give it a generous spray of perfume. |
Review Questions:
1. Explain why the stationary-target
assumption is introduced when deriving the classical expression for the mean
free path.
2. How would you
explain the expression for the collision cross‑section of two different molecules?
3. How would you explain the physical meaning of the l-s relation and its limitations?
References:
Clausius, R.
(1858). On the mean lengths of the paths described by the separate molecules of
gaseous bodies. Philosophical Magazine, 15(101), 417–424.
Fernández-Terán,
R., Sucre-Rosales, E., Echevarría, L., & Hernández, F. E. (2020). Social
distancing during the COVID-19 pandemic: an analogy to explain collision
cross-sections in chemical kinetics. Journal of Chemical Education, 97(12),
4540-4544.
Feynman,
R. P. (2005). Perfectly
reasonable deviations from the Beaten track: The letters of Richard P. Feynman (M. Feynman, ed.). New York: Basic Books.
Feynman,
R. P., Leighton, R. B., & Sands, M. (1963). The Feynman Lectures on
Physics, Vol I: Mainly
mechanics, radiation, and heat. Reading, MA: Addison-Wesley.
Maxwell,
J. C. (1867). On the dynamical theory of gases. Philosophical Transactions
of the Royal Society of London, 157, pp. 49-88.
Tanrıverdi, Ö.,
Alkan, A., Karaoglu, T., Kitaplı, S., & Yildiz, A. (2024). COVID-19 and
carcinogenesis: exploring the hidden links. Cureus, 16(8),
e68303.