What mass of $"potassium chlorate"$ is necessary to generate a $5.5*g$ mass of oxygen gas?

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Answer 1 · 2017-12-21T20:43:17

Look at the stoichiometric equation....

$KClO_3(s) + Delta stackrel(MnO_2)rarrKCl(s) + 3/2O_2(g)$

A little $Mn(+IV)$ salt is usually added to catalyze the reaction....

We require $5.5*g$ dioxygen gas....a molar quantity of $(5.5*g)/(32.0*g*mol^-1)=0.0172*mol$ , and note that this is in respect to dioxygen gas....

And so we need $2/3*"equiv"$ with respect to the chlorate....i.e. $2/3xx0.0172*molxx122.55*g*mol^-1=14.0*g$

Answer 2 · 2017-12-21T21:24:45

$=14.04gKClO_3$

Write and balance the equation
$2KClO_3->2KCl+3O_2$
First thing to do is to find the molar masses of the involved compounds. In this case, $O_2$ and $KClO_3$ . Refer to the periodic table for the elements' atomic masses.
$O_2=(32g)/(mol)$
$KClO_3=(122.5g)/(mol)$
Given the mass of $O_2$ , as convention, convert $"mass"(m)$ to $"moles"(eta)$ as basis for the usual series of conversions.
$=5.5cancel(gO_2)xx(1molO_2)/(32cancel(gO_2))$
$=0.1719molO_2$
Now, since the target is the $mKCl)_3$ , use $etaO_2$ as basis with reference to the balanced equation for the mole ratio to find the $etaKClO_3$ ;i.e.,
$=0.1719cancel(molO_2)xx(2molKClO_3)/(3cancel(molO_2))$
$=0.1146molKClO_3$
Finally, find $mKClO_3$ through the relationship obtainable from the molar mass of $KClO_3$ ; that is, $1molKClO_3-=122.5gKClO_3$ . Hence,
$=0.1146cancel(molKClO_3)xx(122.5gKClO_3)/(1cancel(molKClO_3))$
$=14.04gKClO_3$
Therefore, $5.5gO_2$ is produced in the decomposition of $14.04gKClO_3$ .

What mass of "potassium chlorate""potassium chlorate" is necessary to generate a 5.5*g5.5*g mass of oxygen gas?