deletions | additions       diff --git a/Box.tex b/Box.tex  index 093a0b1..fd2b16c 100644  --- a/Box.tex  +++ b/Box.tex 
...
$f_l$ \textbf{How likely is the emergence of life}?   If life was impossible nobody would know it. Similarly the fact that we exist on Earth can not be used to draw conclusions on how probable is life in the Universe. Even if this probability was extremely low and life existed only on one planet in the Universe we would necessarily be on that planet.   The cool thing is that, statistically speaking, finding just another place where life can be supported changes everything. Finding traces of life (even fossil) on Mars or on one of the moons of Saturn or Jupiter would change completely the picture, as it would demonstrate that the emergence of life (biogenesis) does not require extremely unlikely conditions. \\  For the time being an interesting argument that is used to constrain $f_l$ is the rapidity of biogenesis on Earth. That is how long it took for life to emerge once the conditions at the surface of our planet were "stable" enough. The argument is the following: imagine biogenesis as a lottery, the appearence of life corresponds to winning such lottery. Now if life is very unlikely, then to win the lottery one has to play many times. That is one requires a very long time before the conditions are just right. If on the other hand winning the lottery is relatively easy (many winning tickets, or if you want many different combinations of the environmental conditions can lead to life) one needs to play just a few times before winning. It turns out that biogenesis on Earth was fairly rapid. rapid compared to geological times.  Using a conservative upper limit of 600 million years constrains the probability of biogenesis in terrestrial planets older than 1 billion years to be greater than $13\%$ \cite{Lineweaver_Davis_2002}. \\ $f_l \ge 0.13$