How quickly does a chick embryo grow? Remember that the way any embryo develops is by repeated cell division. It starts off as a single cell which spilts into two. Each of those two cells then splits into two, and so on. We have illustrated this schematically with a square box representing the initial egg cell
We can very efficiently describe the way the number of cells grows
if we use some mathematical notation.
Let's denote the number of times division has occured by the letter t,
and let's denote the total number of cells by N(t).
Thus N(1) denotes the number of cells after 1 division;
so N(1)=2. Similarly, N(2)=2x2=4, N(3)=2x2x2=8, etc.
A more compact way to write 2x2x2 is as 2^{3};
2x2x2x2 is 2^{4} and so on.
With this convenient notation, we can write
In mathematical language, N(t) is an exponential function of t.
In the graph next to the cell division simulation, we have plotted N(t) for t=1,2,3,.... We can join up the dots to get a smooth curve, from which we can read off values for 2^{t} corresponding to any value for t, whole number or not. (Later we will see a more precise way to define 2^{t} for any value of t.)
In the exponential function N(t)=2^{t}, the number 2 is called the base of the exponential. We can change this base and get other functions of t, all of which are called exponentials. For example, using base 3, we get the exponential function 3^{t}.
The graphs of exponential functions are shown in this demonstration.
You can change the base of the exponential (denoted by b)
by using the slider at the top.
Notice that the graphs extend into the region where t is negative.
This doesn't make much sense if t represents the number of times
that a chick egg has divided.
Mathematically, however, we can make sense of it as follows.
For the exponential with base b,
i.e. for the function b^{t}, we use the rule that
This rule tells us how to compute b^{t} for negative values of t. With this rule it is still true that b^{t+1} = b b^{t}. 

If you experiment with a few different choices for the base, you will notice that the graphs of all the exponential functions have a few things in common:
1. The graphs all pass through the same point when t=0
2. Going off to one direction (left or right), the value of the function (the height of the curve) grows very rapidly, but going off to the other direction, the value decays slowly towards zero, getting ever closer to the horizontal axis but never actually reaching it.
Notice that for some choices of base b, the value increases when we move to the left and decays to the right, while for other choices of b, the value increases to the right and decays to the left. See if you can figure out what determines which alternative applies to a given exponential function.
3. There is a third, more subtle, property shared by all the exponential functions. To understand what this is, we need to look at the straight lines tangent to the graphs. In particular, we need to look at the directions of these tangent lines, as measured by their slopes.
Select a point on the graph by clicking on it.
The demonstration shows the tangent line to the graph at the selected point.
The three numbers shown at the bottom of the demonstration are


Notice that along a given curve, while the first two numbers change,
the third one remains the same no matter which point you select!
This is the third special property of exponentials:
If you explore this property of exponentials in more detail, you will notice that this constant of proportionality changes depending on the base of the exponential. For instance, for the exponential to base 2 the constant is .693147, while for the exponential to base 3 the constant is 1.0986.
This prompts the following question:
The answer to this question is YES! This base, for which the exponential function has slope equal to its value, is traditionally denoted by the letter e. This number e has many wonderful properties. You can explore the graph of the exponential function e^{t}, and verify that it has slope equal to value by clicking the e button in the demonstration above.