Here is an extended hint for proving 2 (an almost complete proof is in the Update below). If $3^s$ base 2 is periodic, then you can represent it as $u(1+2^m+2^{2m}+...+2^{(t-1)m})=u\frac{2^{tm}-1}{2^m-1}$ for some numbers $u,m,t$. Therefore if $q_n(x)$ denotes the $n$-th <a href="http://en.wikipedia.org/wiki/Cyclotomic_polynomial">cyclotomic polynomial</a>, then $q_{tm}(2)$ must be a power of 3 (as a divisor of $3^s$). But it looks like $q_n(2)$ is never 0 modulo 9 (this should be possible to prove rigorously but I do not have time). Hence $q_{tm}(2)$ must be equal to 3 or 1 which gives a bound on $s$. 

<b> Update</b> Since $2^m-1=0 \mod 9$ only when $m=0 \mod 6$. it is enough to consider $q_{6k}(2)$. Since $2^3=-1 \mod 9$, we only need remainders of cyclotomic polynomials modulo $x^3+1$ with coefficients modulo 9. Here are all 50 of them  $$ \begin{array}{l} 1,3,{x}^{2},8x,8{x}^{2},1+8x,5+5{x}^{2},x+1,x+8,x+8
{x}^{2},\\\ 4x+5{x}^{2},{x}^{2}+1,1+8{x}^{2}+8x,2+3x+2{x}^{2},
2+5x+4{x}^{2},2+8x+{x}^{2},2+{x}^{2}+7x,\\\ 2+2{x}^{2}+8x,2+6
{x}^{2}+7x,3+x+8{x}^{2},3+5x+3{x}^{2},\\\ 3+6x+2{x}^{2},3+2
{x}^{2}+7x,4+6x+3{x}^{2},4+7x+4{x}^{2},4+2{x}^{2}+5x,4
+3{x}^{2}+5x,\\\ 4+4{x}^{2}+6x,5+2x+7{x}^{2},5+4x+4{x}^{2}
,5+4{x}^{2}+5x, \\\ 6+2x+6{x}^{2}, \\\ 6+4x+5{x}^{2},6+7x+2{x}^{
2},6+5{x}^{2}+3x,6+6{x}^{2}+4x,\\\ 6+7{x}^{2}+3x,7+2x+6{x}
^{2},7+4x+7{x}^{2},\\\ 7+6{x}^{2}+3x,8+2x+7{x}^{2},8+6x+8{
x}^{2},8+8x+{x}^{2},
\\\ 8+7{x}^{2}+x,8+8{x}^{2}+2x,{x}^{2}+x+1,{x}
^{2}+8x+1 \end{array}$$ None of these polynomials become 0 when evaluated at $2 \mod 9$. 

As for the last claim about the size of $q_{mt}(2)$: every root of the cyclotomic polynomial is on the unit circle, so the values at 2 grow with the degree. 

This almost completes the proof of 2 (one needs to show that the set of 50 polynomials is complete, but that can be done by induction).