1. [tex]7.95\cdot 10^6 J[/tex]
The total energy given to the cells during one pulse is given by:
[tex]E=Pt[/tex]
where
P is the average power of the pulse
t is the duration of the pulse
In this problem,
[tex]P=1.59\cdot 10^{12}W[/tex]
[tex]t=5.0 ns = 5.0\cdot 10^{-9} s[/tex]
Substituting,
[tex]E=(1.59\cdot 10^{12}W)(5.0 \cdot 10^{-6}s)=7.95\cdot 10^6 J[/tex]
2. [tex]1.26\cdot 10^{21}W/m^2[/tex]
The energy found at point (1) is the energy delivered to 100 cells. The radius of each cell is
[tex]r=\frac{4.0\mu m}{2}=2.0 \mu m = 2.0\cdot 10^{-6}m[/tex]
So the area of each cell is
[tex]A=\pi r^2 = \pi (2.0 \cdot 10^{-6}m)^2=1.26\cdot 10^{-11} m^2[/tex]
The energy is spread over 100 cells, so the total area of the cells is
[tex]A=100 (1.26\cdot 10^{-11} m^2)=1.26\cdot 10^{-9} m^2[/tex]
And so the intensity delivered is
[tex]I=\frac{P}{A}=\frac{1.59\cdot 10^{12}W}{1.26\cdot 10^{-9} m^2}=1.26\cdot 10^{21}W/m^2[/tex]
3. [tex]9.74\cdot 10^{11} V/m[/tex]
The average intensity of an electromagnetic wave is related to the maximum value of the electric field by
[tex]I=\frac{1}{2}c\epsilon_0 E^2[/tex]
where
c is the speed of light
[tex]\epsilon_0[/tex] is the vacuum permittivity
E is the amplitude of the electric field
Solving the formula for E, we find:
[tex]E=\sqrt{\frac{2I}{c\epsilon_0}}=\sqrt{\frac{2(1.26\cdot 10^{21} W/m^2)}{(3\cdot 10^8 m/s)(8.85\cdot 10^{-12}F/m)}}=9.74\cdot 10^{11} V/m[/tex]
4. 3247 T
The magnetic field amplitude is related to the electric field amplitude by
[tex]E=cB[/tex]
where
E is the electric field amplitude
c is the speed of light
B is the magnetic field
Solving the equation for B and substituting the value of E that we found at point 3, we find
[tex]B=\frac{E}{c}=\frac{9.74\cdot 10^{11} V/m}{3\cdot 10^8 m/s}=3247 T[/tex]
