Respuesta :
Answer:
Differential equation: [tex]\frac{dQ}{dt} = rQ = -0.0025Q[/tex]
Solution of diff equation: [tex]Q(t) = Ke^{-0.0025t}[/tex]
6.3% of the ozone in the atmosphere now will decay in the next 27 years.
Step-by-step explanation:
The amount of ozone in the atmosphere may be found by the following differential equation:
[tex]\frac{dQ}{dt} = rQ[/tex]
In which r is the constant of proportionality and Q is the amount of ozone. A positive value of r means that the amount of ozone in the atmosphere is going to increase, while a negative value means it is going to decrease.
Solving the differential equation:
We integrate both sides of the differential equation and apply the exponential function. So:
[tex]\frac{dQ}{dt} = rQ[/tex]
[tex]\frac{dQ}{Q} = r dt[/tex]
Integrating both sides
[tex]\ln{Q} = rt + K[/tex]
Applying the exponential:
[tex]Q(t) = Ke^{rt}[/tex]
In which K is the initial amount of ozone.
So
[tex]Q(t) = Ke^{-0.0025t}[/tex]
If this rate continues, approximately what percent of the ozone in the atmosphere now will decay in the next 27 years?
This K-Q(27).
[tex]Q(27) = Ke^{-0.0025*27} = 0.9347K[/tex]
K - 0.9347K = 0.0653.
6.3% of the ozone in the atmosphere now will decay in the next 27 years.
