I'm having difficulty with a problem in my Calculus III course. The problem text is as follows:
My initial thought was that the sequence must converge to 1, because as k gets infinitely large, 1/k will approach 0 and thus the whole thing will approach k^0 or 1. However, the answer key says that the sequence diverges. I guess that's because k factorial somehow grows so unbelievably fast as to overcome the exponent going to 0? In any case, I tried another line of reasoning to reason out why the sequence might diverge. I know that for any b > 1 and sufficiently large k, the following holds true:
\(\displaystyle b^k<k!\)
So, then I believe I'm justified in making this next step:
\(\displaystyle \left(b^k\right)^{\frac{1}{k}}<\left(k!\right)^{{1} \over {k}}\)
\(\displaystyle b<\left(k!\right)^{\frac{1}{k}}\)
But I don't know where to go from here. Is that the entirety of my proof? Because as k approaches infinity, it will still be bigger than any arbitrary constant b I could possibly pick? I'm quite confused. Any help would be appreciated.
My initial thought was that the sequence must converge to 1, because as k gets infinitely large, 1/k will approach 0 and thus the whole thing will approach k^0 or 1. However, the answer key says that the sequence diverges. I guess that's because k factorial somehow grows so unbelievably fast as to overcome the exponent going to 0? In any case, I tried another line of reasoning to reason out why the sequence might diverge. I know that for any b > 1 and sufficiently large k, the following holds true:
\(\displaystyle b^k<k!\)
So, then I believe I'm justified in making this next step:
\(\displaystyle \left(b^k\right)^{\frac{1}{k}}<\left(k!\right)^{{1} \over {k}}\)
\(\displaystyle b<\left(k!\right)^{\frac{1}{k}}\)
But I don't know where to go from here. Is that the entirety of my proof? Because as k approaches infinity, it will still be bigger than any arbitrary constant b I could possibly pick? I'm quite confused. Any help would be appreciated.