Let's look at the science.
Six months on a small battery?
We'll need one with low self discharge characteristics and high capacity.
A 3.6 V LI-Ion might do the trick.
Checking out the Small Battery Companies website, we could use a Prismatic Li-Ion
14 mm x 34 mm x 47 mm that has 1800 mAh. That is about the size you mention.
Let's use a high effeciency buck boost DCDC converter to suck every ounce of juice of it.
So let's assume an average of 90% effeciency, but using a DC/DC converter we can probably discharge below the recommended voltage and get more out.
In six months there are 0.5*365.25*24 hours = 4383 hours.
(1.800 Ah/4383 hours)*0.9 = 369 μA average.
Picking an XBee module at random, let's assume your tranciever takes 45 mA at 250 kbit/s.
Let's assume you have 1k byte of data to send and receive every minute.
2 * 1024 * 8 bits = 16384 bits. = 66 ms * 60 = 3.96 seconds per hour (or 0.0011 hours)
So we need to wake up for 3.96 seconds every hour and take 45 mA, the rest of the time we sleep and take 1 μA (for the radio), let's ignore the CPU for now.
((1-0.0011) * 1 μA) + (0.0011 * 0.045 A) = 50 μAh (50 μA averaged over 1 hour)
This looks promising, we've still got more than 300 μA to play with.
I don't know what Arduino you are using, but looking at the datasheet for an ATMega168A we have 0.75 μA in power down mode and 200 μA in active mode, CPU vendoes love to quote impossible figures, so let's assume more. Let's assume 1 μA in power down and 1 mA in active.
((1-0.0011) * 1 μA) + (0.0011 * 1 mA) = 2 μAh (2 μA averages over 1 hour)
So, assuming you don't spend all your power budget on the CPU, spend a lot of time getting the other components as effecient as possible and don't use LEDs, it might just work.