Initial velocity v = 86.6 m / s
angle ,theta = 63.7 degrees
(A). the horizontal component of the shell's initial velocity = v cos 63.7 = 38.36 m / s
vertical component of shells' initial velocity = v sin 63.7 = 77.63 m / s
(B). time taken to reach maximu height t = v sin (theta ) / g
= 7.922 s
(C). Maximum height H = ( v sin(theta) )^ 2/ 2g
= 307.5 m
(D). Required distance = v^ 2 *sin2(theta) / g
= 607.9 m
(E). Horizontal component of accleraton = 0
vertical component of accleration = g = 9.8 m / s^ 2
(F). horizontal component of velocity at required point = v cos (theta ) = 38.36 m / s
vertical compoent of velocity at required point = 0
Answer:
orbital 3 also called orbital f
Explanation:
In the resolution of the Schrödinger equation for the three-dimensional hydrogen atom with spherical coordinates three constants appear, which are related, these constants are called quantum numbers.
The first one is the number n called the main quantum number and its value ranges from to infinity
The second number is called the orbital quantum number (l) and has values from zero to n-1
The third number corresponds to the magnetic orbital quantum number and thymus values from –l to l
Let us apply to our case, state (5, 3, 0) corresponds to a state in period 5 of
the quantum number, with orbital 3 also called orbital f and with magnetic number 0 that e spherical
There are three answers, the impulse is equal to the change in momentum of the system. The dimensions of these quantities are the same, namely mass times velocity. You can think of impulse as kind of the "net effect" that a force has in changing the state of motion of a system.
Make prediction about what will happen certain circumstances
The Specific Heat Capacity of silver is 230 J/kgK, melting point is 961.8 C so the difference is 941.8K. Now we simply do q=230J/kgK*16.5kg*941.8K and that is 3 574 131 J
