THE SOUTHWORTH PLANETARIUM
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43.6667° N 70.2667° W Altitude: 10 feet below sea level Founded
January 1970
2021-2022: CXXXVII
"You can't depend on your eyes when your imagination is out of focus."
-Mark Twain
THE DAILY ASTRONOMER
Wednesday, June 15, 2022
The Law of Bode
Today's astronomical morsel, Mr Meeus, involves a nifty little number trick
that will enable even the most hopeless math phobe to use numbers to
approximate average planet distances from the Sun. We call this trick
"Bode's Law," and it does involve mathematics, in the same way that
clicking a mouse requires physical exertion. It is as simple in its
application as it is eerie in its accuracy.
We first introduce a term
ASTRONOMICAL UNIT
the average separation distance between Earth and the Sun. This
distance is equal to 149.5 million kilometers, or about 93 million miles.
We can approximate most of the planets' distances now by first writing the
numbers 0 followed by 3. Then double each number until reaching 192
0 3 6 12 24 48 96 192
Next, we add 4 to each number
4 7 10 16 28 52 100 196
Finally, we simply divide each number by 10
0.4 0.7 1.0 1.6 2.8 5.2 10.0 19.6
The first value (0.4) is close to Mercury's average distance from the Sun
in astronomical units. The actual value is 0.39
The second value (0.7) is close to Venus' average distance from the Sun.
The true value is 0.72.
The third value, 1.0, is equal to Earth's average distance (in AU) from the
Sun.
We can perhaps now see the progression. The value 1.6 is close to Mars'
average distance from the Sun of 1.52.
What is at 2.8, you ask?
The asteroid belt!
At 5.2? That is the exact value of Jupiter's average distance from the
Sun.
10.0? Saturn's average distance from the Sun is 9.52 AU.
19.6? Uranus' average AU distance from the Sun is 19.2
Now, this numerology trick is all the more remarkable when we study its
history. We refer to this relation as "Bode's Law" because German
astronomer Johann Bode (1747-1826) included this relation as a footnote in
his 1772 work "Manual for Knowing the Starry Sky." At that time, neither
Uranus nor bodies now known as the asteroids within the Main Asteroid Belt
had yet been discovered. William Herschel discovered Uranus in 1781.
Piazzi discovered Ceres, the largest asteroid, on January 1, 1801.
The law is sometimes called "The Titius-Bode Law" because in 1766 Johann
Titrius (1729-1796) had developed the relation based on calculations
performed by Genevan scientist Charles Bonnett (1720-1793). Bode based
his own sequence on those previous computations.
*Johann Bode: the German astronomer for whom*
*the Bode's Law is named. Even though this numerical*
*relation is no longer seriously regarded, it has retained the*
*name "Law." *
Initially, most astronomers did not take this Law seriously. Even when
William Herschel discovered Uranus in 1781 at approximately the position
predicted by Bode's Law, most assumed the relation was merely coincidental.
However, when Giuseppe Piazzi (1746-1826) discovered Ceres in the
region around 2.8 AU from the Sun, Bode's Law came into vogue. It
remained a revered law until Johannes Gale and Heinrich d'Arrest discovered
Neptune in September 1846. Neptune's average distance is about 30.1 AU.
Bode's Law predicted the next planet should be around 38.8 AU from the
Sun. (Ironically, this approximation is close to Pluto's average distance
of 39.5 AU.)
Even though Bode's Law was relegated to the dust bin, it hasn't been
entirely forgotten because it offers us a simple way to remember the
average distances of most planets. Most would dismiss Bode's Law as a
lucky guess, but, what a guess!
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