Answers:
a) [tex]T=7.04(10)^{-10} s[/tex]
b) [tex]5.11(10)^{12} cycles[/tex]
c) [tex]2.06(10)^{26} cycles[/tex]
d) 46000 s
Explanation:
We know the maser radiowave has a frequency [tex]f[/tex] of [tex]1,420,405,751.786 cycles/s[/tex]
In addition we know there is an inverse relation between frequency and time [tex]T[/tex]:
[tex]f=\frac{1}{T}[/tex] (1)
Isolating [tex]T[/tex]: [tex]T=\frac{1}{f}[/tex] (2)
[tex]T=\frac{1}{1,420,405,751.786 cycles/s}[/tex] (3)
[tex]T=7.04(10)^{-10} s[/tex] (4) This is the time for 1 cycle
If [tex]1h=3600s[/tex] and we already know the amount of cycles per second [tex]1,420,405,751.786 cycles/s[/tex], then:
[tex]1,420,405,751.786 \frac{cycles}{s}(3600s)=5.11(10)^{12} cycles[/tex] This is the number of cycles in an hour
Firstly, we have to convert this from years to seconds:
[tex]4.6(10)^{9} years \frac{365 days}{1 year} \frac{24 h}{1 day} \frac{3600 s}{1 h}=1.45(10)^{17} s[/tex]
Now we have to multiply this value for the frequency of the maser radiowave:
[tex]1,420,405,751.786 cycles/s (1.45(10)^{17} s)=2.06(10)^{26} cycles[/tex] This is the number of cycles in the age of the Earth
If we have 1 second out for every 100,000 years, then:
[tex]4.6(10)^{9} years \frac{1 s}{100,000 years}=46000 s[/tex]
This means the maser would be 46000 s off after a time interval equal to the age of the earth
