The Drake Equation | Astronomy 801: Planets, Stars, Galaxies, and the Universe (2024)

Additional reading from www.astronomynotes.com

The individual terms are:

$N$ = number of civilizations in the Milky Way Galaxy that are capable of producing signals that we can detect on Earth
$R*$ = the rate at which stars capable of supporting life form in our Galaxy
$f_{p}$ = the fraction of those stars that have a planet or planets
$n_{e}$ = the average number of planets per planetary system that have an environment that can support life
$f_{l}$ = the fraction of those planets that can support life on which life actually develops
$f_{i}$ = the fraction of those planets with life where intelligent life develops
$f_{c}$ = the fraction of those intelligent civilizations that develop technology for communication
$L$ = the average lifetime of those civilizations that develop technology for communication

Several of these terms have values that we can estimate with some degree of accuracy. For example, we can estimate $R *$ from our observations of star forming regions in the Galaxy. That number appears to be very close to 1 star per year. Also, from our observations of stars with protoplanetary disks and with extrasolar planets, we think that $f_{p}$ is likely 1 or close to 1, too. The rest of the values in the equation require you to either extrapolate using limited information or outright guess.

For $n_{e}$ , we can use the Solar System as a guide. The Earth is in the CHZ. Venus and Mars are either close or in the CHZ depending on the model used. Europa, Ganymede, and Titan are outside of the CHZ, but may have environments that can support life. So, in the Solar System there is definitely one, and maybe more than one, planet (or moon) capable of supporting life. What we still do not know is if our Solar System is common or rare. If it is common, you might estimate say 2 objects per Solar System for $n_{e}$ . For $f_{l}$ , you have to make an educated guess. Scientists studying the origin of life think that, given the right conditions (temperature, presence of water, etc.), life may develop on every Earth-like world, or $f_{l} = 1$ . However, that may be too optimistic, so you might expect that 1 in 10, 1 in 100, or 1 in 1,000,000 develop life. However, if you think that Earth is alone in this regard, it might be as low as 1 in 100,000,000,000. The arguments for assigning values for $f_{i}$ and $f_{c}$ are identical. If you are optimistic, you would assign $f_{i}$ or $f_{c} = 1$ . If you are pessimistic, you would assign $f_{i}$ or $f_{c} = 1$ in 100,000,000,000, or anywhere in between.

The final term, L, is the lifetime of an intelligent, communicating civilization. How do you estimate this value? If you consider Earth, we have only had the technology to communicate using light (e.g., radio or TV) for about 100 years. To estimate L, though, you have to decide how long our civilization will retain this capability. Will civilization end because of war, disease, or some other catastrophe in a few generations? If not, will our civilization last as long as the Sun remains on the Main Sequence? Your estimate may be anywhere from 1,000 years to 5,000,000,000 years. If you fill in values of 1 for all of the parameters for R* through $f_{c}$ , then the equation simplifies to N = L. So, in the optimistic case, your estimate for N will be equal to your estimate for the lifetime of a typical intelligent, communicating civilization.

Try this!

At PBS, they have a Drake equation calculator where you can put in values for these numbers to determine how many civilizations may be found in the Milky Way.

Fill in values for a pessimistic case and determine N.
Fill in values for your best guesses and determine N.

How do these compare to the case where every parameter is 1? What do you think might be the range of the total number of intelligent, communicating civilizations in the Milky Way?

Given the extent of the Milky Way, if the number N is small, the expected distance between Earth and any communicating civilization will be large. If N is large, the average separation between Earth and any communicating civilization may be small.

The Drake Equation | Astronomy 801: Planets, Stars, Galaxies, and the Universe (2024)

FAQs

What is the Drake equation for star formation? ›

R_∗ = 1 yr⁻¹ (1 star formed per year, on the average over the life of the galaxy; this was regarded as conservative) f_p = 0.2 to 0.5 (one fifth to one half of all stars formed will have planets) n_e = 1 to 5 (stars with planets will have between 1 and 5 planets capable of developing life)

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What does the drake equation estimate in Quizlet? ›

What is the Drake Equation? a way of estimating the number of advanced civilizations in our galaxy right now.

Are we alone in the universe? ›

Observations from the ground and from space have confirmed thousands of planets beyond our solar system. Our galaxy likely holds trillions. But so far, we have no evidence of life beyond Earth.

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How big is the universe? ›

The proper distance—the distance as would be measured at a specific time, including the present—between Earth and the edge of the observable universe is 46 billion light-years (14 billion parsecs), making the diameter of the observable universe about 93 billion light-years (28 billion parsecs).

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Can the Drake equation be solved? ›

While the Drake Equation cannot be “solved” or even accurately calculated, it retains considerable utility for discussions about extraterrestrial life and intelligence. And that, after all, was the reason for its invention.

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Why can't the Drake equation be solved? ›

It can't actually be used to calculate anything because the values of most of the terms are unknown. We have a better handle on a few of them than we did when Drake proposed it, but there are still too many that are totally unknown.

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How many planets can support life in the universe? ›

Scientists estimate there could be 60 billion planets in the Milky Way alone within habitable zones capable of supporting life. Considering the vast number of galaxies, researchers estimate about 50 sextillion potentially habitable planets in the universe, making Earth one of many candidates for hosting life.

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What is the star formation rate? ›

For example, it is thought, though still debated, that the Milky Way had several bursts of star formation in the past and the current star formation rate is around one solar mass per year. Most measurements of the star formation history assume that star formation occurred in one burst at a constant rate over 100 Myr.

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What does the factor L in the Drake equation depend on? ›

L = the average lifetime of those civilizations that develop technology for communication.