Revision 5ac751ba-7bd5-483e-ab96-bd307acd846d

First of all, I'm not sure this is exactly the correct answer based on two issues, which I will highlight as they appear.

The first observation is...
>! that a domino is divided into two parts by exactly one line.

This means

>! The pizza is not sliced into standard "triangular" sectors, but rather it is sliced by a chord.  
>! As shown here:  
>! [![enter image description here][1]][1]

Now we can find

>! the angle of each section using the formula $\theta = \frac{s}{r}$ where $s$ is the arclength and $r$ is the radius.  
>!  
>! First couple: $\theta_1 = \frac{54.97\ \rm{cm}}{18\ \rm{cm}} = 3.0539\ \rm{rad}$  
>! Second couple: $\theta_2 = \frac{16.49\ \rm{cm}}{18\ \rm{cm}} = 0.9161\ \rm{rad}$  
>! Third couple: $\theta_3 = \frac{5.49\ \rm{cm}}{18\ \rm{cm}} = 0.3050\ \rm{rad}$  

Now we calculate

>! the area of these slices, using the formula $A = \frac{r^2}{2}(\theta-\sin\theta)$.  
>!  
>! First couple: $A_1 = \frac{(18\ \rm{cm})^2}{2}(3.0539-\sin3.0539) = 486.09\ \rm{cm}^2$  
>! Second couple: $A_2 = \frac{(18\ \rm{cm})^2}{2}(0.9161-\sin0.9161) = 145.82\ \rm{cm}^2$  
>! Third couple: $A_3 = \frac{(18\ \rm{cm})^2}{2}(0.3050-\sin0.3050) = 48.55\ \rm{cm}^2$  
>!  
>! Note that while $\theta$ is found in radians, the $\sin$ function is evaluated as though its argument is in degrees. This is the first major issue; I only initially considered this by a mistake in my calculator settings. Regardless, I think this path notable because scaling our pizzas to the unit circle, we get  
>!  
>! First couple: $A_1 = \frac{1}{2}(3.0539-\sin3.0539) = 1.5003$  
>! Second couple: $A_2 = \frac{1}{2}(0.9161-\sin0.9161) = 0.45006$  
>! Third couple: $A_3 = \frac{1}{2}(0.3050-\sin0.3050) = 0.14983$  
>!  
>! Which are all extremely close to a ratio of small integers. Unfortunately, I had no luck trying to construct them using numbers given the couples' constraints (eg. consecutive odd).

However,

>! Looking back at the sector area in $\rm{cm}^2$, we find a rather simple means of constructing the area from two numbers:  
>!  
>! Shift the smaller of the numbers one place to the left, then add.
>!  
>! This works for each of the given couples:  
>! First couple: $\{44,46\}\Rightarrow 440+46 = 486\approx486.09\ \rm{cm}^2$  
>! Second couple: $\{13,15\}\Rightarrow 130+15 = 145\approx145.82\ \rm{cm}^2$  
>! Third couple: $\{4,9\}\Rightarrow 40+9 = 49\approx48.55\ \rm{cm}^2$  
>!  
>! Note the second major issue--the first couple uses numbers which are outside the given allowable range of $[1,25]$.

With a function for determining the arclength identified, we can now find the arclength for the first two primes.

>! $\{2,3\}\Rightarrow 20+3 = 23\ \rm{cm}^2$  
>!  
>! Solving $23\ \rm{cm}^2=\frac{(18\ \rm{cm})^2}{2}(\theta-\sin\theta)$:  
>! $\theta = 0.1445\ \rm{rad}$  
>!  
>! $s = r\theta = (18\ \rm{cm})0.1445 = 2.60\ \rm{cm}$

Therefore, the first two prime numbers share a slice with an arclength of

>! 2.60 centimeters



  [1]: https://i.sstatic.net/HtZ8Z.png