Respuesta :
Answer:
a: [tex]\rm -2.689\times 10^{-8}\ s.[/tex]
b: [tex]\rm \left ( \Delta s \right )^2=-25[/tex], for both the frames.
Explanation:
In the reference frame of a person which is at rest with respect to the ground,
The space interval of the event of explosion of two objects, [tex]\rm \Delta x = 5.0\ m.[/tex]
The objects explode simlultaneously in this frame, therefore, the time interval of the event, [tex]\rm \Delta t = 0\ s.[/tex]
The other person is moving with the speed of 0.85 times the speed of light with respect to the ground.
[tex]\rm v = 0.85\ c.[/tex]
Let the space and time intervals of the same event in the moving person's frame be [tex]\rm \Delta x'[/tex] and [tex]\rm \Delta t'[/tex] respectively.
Then, according to the Lorentz transformation of the space-time coordinates, the coordinates of the same event in the moving person's frame is given by
[tex]\rm \Delta t'=\gamma \left (\Delta t-\dfrac{v\Delta x }{c^2} \right ).\\\Delta x'=\gamma (\Delta x-v\Delta t).\\\\where,\\\\\gamma = \dfrac{1}{\sqrt{1-\dfrac{v^2}{c^2}}}.\\\\\text{ c is the speed of light in vacuum, having value = }3\times 10^8\ m/s.[/tex]
(a):
According to the Lorentz tramsfomation, the time interval of the event of explosion of the two objects in this moving person's frame is given by
[tex]\rm \Delta t'=\dfrac{1}{\sqrt{1-\dfrac{v^2}{c^2}}}\left( \Delta t-\dfrac{v\Delta x}{c^2}\right )\\=\dfrac{1}{\sqrt{1-\dfrac{(0.85\ c)^2}{c^2}}}\left( 0-\dfrac{0.85\ c\times 5.0}{c^2}\right )\\=1.898\times \left (-\dfrac{0.85\times 5.0}{3\times 10^8} \right )\\=-2.689\times 10^{-8}\ s.[/tex]
The negative time interval indicates that the second object exploded first in this frame.
The two explposions are not simultaneous in this frame.
(b):
For the reference frame of the person which is at rest with respect to the ground:
[tex]\rm \left (c\Delta t \right )^2=\left (c\cdot 0\right )^2=0\\\left (\Delta x \right )^2=5.0^2=25.\\\Rightarrow \left (\Delta s \right )^2=0-25=-25.[/tex]
For the reference frame of the person which is moving with speed v with respect to the ground:
[tex]\rm \Delta x'=\dfrac{1}{\sqrt{1-\dfrac{v^2}{c^2}}}\left( \Delta x-v\Delta t\right ) \\=1.898\times (5-0)\\=9.49\ m.[/tex]
[tex]\rm \left (c\Delta t' \right )^2=\left (3\times 10^8\times 2.689\times 10^{-8}\right )^2=65.06\\\left (\Delta x' \right )^2=9.49^2=90.06.\\\Rightarrow \left (\Delta s' \right )^2=65.06-90.06=-25.[/tex]
Thus, it is clear that the value of [tex]\left (\Delta s \right )^2[/tex] for both the frames are equal.
