Answer:
The answer is 16 years.
Explanation:
The formula for calculating the value of an investment that is compounded annually is given by:
[tex]V(n)=(1+R)^nP[/tex]
Where:
[tex]n[/tex] is the number of years the investment is compounded,
[tex]R[/tex] is the annual interest rate,
[tex]P[/tex] is the principal investment.
We know the following:
[tex]25000=(1+0.06)^n \times 10000[/tex]
And we want to clear the value n from the equation.
The problem can be resolved as follows.
First step: divide each member of the equation by [tex]10,000[/tex]:
[tex]\frac{ 25000}{10000}=(1+0.06)^n \times \frac{ 10000}{10000}[/tex]
[tex]2.5=(1.06)^n[/tex]
Second step: apply logarithms to both members of the equation:
[tex]log(2.5)=log (1.06)^n[/tex]
Third step: apply the logarithmic property [tex]logA^n=n.logA[/tex] in the second member of the equation:
[tex]log(2.5)=n.log (1.06)[/tex]
Fourth step: divide both members of the equation by [tex]log1.06[/tex]
[tex]\frac{log(2.50)}{log (1.06)} =n[/tex]
[tex]n= 15.7252[/tex]
We can round up the number and conclude that it will take 16 years for $10,000 invested today in bonds that pay 6% interest compounded annually, to grow to $25,000.
