As the title suggests, the puzzle here is making the number 103 by using exactly four 0s and the following operations:
The solution is slightly difficult, but it shouldn't be too hard for you crazy puzzlers. Have fun!
As rand al’thor points out in the solution built upon here, there must be a way to formulate a $\small 3$ with only two $\small 0 \kern1mu$s. How promising that...
...$~~ 3 = \sqrt{10-1 \, \small\raise.3ex\strut} ~$...
...uses only two $\small 1$s.
And how convenient that
$\small \surd$ and
$ \small \% $
can combine to scale
$\small 1 $ by any positive power of
$ \small 0.1 \,$.
 
So (with ever fewer operations,
at 18 15 14) ...
$\require{begingroup}\begingroup{} \def \@ #1{{ \sqrt { #1 \, \scriptsize\raise.4ex\strut } }}{} \def \sp {{ \kern 3mu \% }}{} \def \fpp {{ \small \kern 2mu \% \kern1mu \% }}{} \def \fp {{ \small \kern 2mu \% \! \raise.4ex\strut }}{} \def \p {{ \scriptsize \kern 1mu \% }}{} \def \E { ~~ \equiv ~~ }{} \def \= { ~~ = ~~ }{} \def \- { \, - \, }{} \kern 5em \small\begin{align}{}\normalsize { 0! + \@{\@ { 0!\fp }\sp \- 0! \fpp } \over 0!\fp }{} &\= { 1 + \@{ \@ { 1\p \! } \sp \- 1 \p\p } \over 1 \p }{}\\[3ex] &\= { 1 + \@{ \@{ .01 \! } \sp \- 1 \p\p } \over 1 \p }{}\\[2ex] &\= { 1 + \@{ .1 \p \- 1 \p\p } \over 1 \p }{}\\[2ex] &\= { 1 + \@{ .001 - .0001 } \over .01 }{}\\[2ex] &\= { 1 + \@{ .0009 } \over .01 }{}\\[2ex] &\= { 1 + .03 \over .01 }{}\\[2ex] &\E \normalsize 103{}\end{align}\endgroup$
Initial solution.
More operations but also more symmetry.
$\begingroup \displaystyle \kern6em{} \def \@ #1{{ \sqrt { #1 \, } }}{} \def \fp {{ \small \kern 2mu \% \raise.4ex\strut }}{} \def \p {{ \small \kern 1mu \% }}{} { 0! + \@{ \@{ 0!\fp\p\p } \, - \, \@{ 0!\fp\p\p\p } } \over 0!\fp }{}\endgroup$
Backpuzzle.
How about $\boldsymbol{.4}$ with only 3 (three) $\small 0 \kern1mu$s
and just 11 operations?
$\begingroup{} \def \@ #1{{ \sqrt { #1 \scriptsize\raise.4ex\strut } }}{} \def \fp {{ \small \kern 2mu \% \scriptsize\raise.9ex\strut }}{} \def \p {{ \scriptsize \kern 1mu \% }}{} \kern 5em \small\begin{align}{}\normalsize \sqrt { 0!\fp } + \sqrt {\sqrt{ 0!\fp } - 0!\fp \, }{} & ~~ = ~~\@ { 1\p } + \@ { \@ { 1\p } - 1\p \, }{}\\[2ex] & ~~ = ~~ \@ { .01 } + \@ { \@ { .01 } - .01 \, }{}\\[2ex] & ~~ = ~~ \@ { .01 } + \@ { .1 - .01 \, }{}\\[2ex] & ~~ = ~~ \@{ .01 } + \@ { .09 }{}\\[2ex] & ~~ = ~~ .1 + .3{}\\[2ex] & ~~\equiv ~~ \normalsize .4{}\end{align}\endgroup$
$\large($And a ${0! \over 0!\%\%\%}$ more thanks to rand al’thor for fixing up $\scriptsize\sqrt{\%\%\%\%\,\tiny\raise1ex\strut}$ from the initial solution! $\large)$
My intended answer:
$103 = \frac{\sqrt{\sqrt{0!\%}\,- \,0!\%}\,\% + \sqrt{0!\%}}{\sqrt{0!\%}\,\%}$
(The strategy used isn't too far off from humn's answer)
Incomplete answer
I can do it using five zeroes:
$\Big(0!+(0!)\%+(0!)\%+(0!)\%\Big)\div(0!)\% = 103.$
In order to reduce this to four, all we need to do is
find a way to construct the number $3$ using only two zeroes,
because then the final solution will be
$(0!+3\%)\div(0!)\% = 103.$
Will this work(I know it may be a cheating, but thought of giving this). Most important or unimportant it is with five zeros (if in case op changes his/her mind to have with 5 zeros, then I am ready with my solution after @Rand)
$$(0!)0(0!)+0!+0!=103$$
0 / 0! = 103, right? – Jodrell Mar 21 '17 at 12:15