An experimenter's diary reads as follows: ''a charged particle is projected in a magnetic feld of `(7.0 veci - 3.0 vecj )X 10^(-3)` T. The acceleraation of the particle is found to be `(sqrare veci +7.0 vec j) X10 ^(-6) ms^(-2)'. The number to the left of `vec i` in the last expression was not readable. What can this number be?

A particle moves with a tangential acceleration a_(t)=vec(a).hat(v) where vec(a)=(5hat(i)) m//s^(2) . If the speed of the particle is zero at x=0 , then find v (in m//s ) at x=4.9 m .

V_(x) is the velocity of a particle of a particle moving along the x- axis as shown. If x=2.0m at t=1.0s , what is the position of the particle at t=6.0s ?

The position vector of a particle is determined by the expression vec r = 3t^2 hat i+ 4t^2 hat j + 7 hat k . The displacement traversed in first 10 seconds is :

The number of solutions of the equation 3sin^(2)x-7sinx+2=0 in [0,5pi] are …………

Match the following A particle is projected with initial speed u-25/3 m/s as shown, here acceleration vector is given as a_(x)= 2t hat(i) m//s^(2), a_(y) = -10hat(j) m//s^(2)

The position of a particle is given by vec r= 3.0 t hat i - 2.0 t^2 hat j + 4.0 hat k m , wher (t) in seconds and the coefficients have the proper units for vec r to be in metres. Find the vec v and vec a of the particle ?

The position of a particle is given by vec r= 3.0 t hat i - 2.0 t^2 hat j + 4.0 hat k m , wher (t) in seconds and the coefficients have the proper units for vec r to be in metres. what is the magnitude of the velocity of particle at t=2 sec ?

A particle moves form x = 0 to x = 2 m on X - axis under the effect of a force vec(F)x = (4x^(3) -3x^(2)+2x) hat(i) newton . The work done on the particle is

When a particle is restricted to move aong x axis between x =0 and x = a , where a is of nanometer dimension. Its energy can take only certain specific values. The allowed energies of the particle moving in such a restricted region, correspond to the formation of standing waves with nodes at its ends x = 0 and x = a . The wavelength of this standing wave is realated to the linear momentum p of the particle according to the de Breogile relation. The energy of the particl e of mass m is reelated to its linear momentum as E = (p^(2))/(2m) . Thus, the energy of the particle can be denoted by a quantum number 'n' taking values 1,2,3,"......." ( n=1 , called the ground state) corresponding to the number of loop in the standing wave. Use the model decribed above to answer the following three questions for a particle moving in the line x = 0 to x =a . Take h = 6.6 xx 10^(-34) J s and e = 1.6 xx 10^(-19) C . If the mass of the particle is m = 1.0 xx 10^(-30) kg and a = 6.6 nm , the energy of the particle in its ground state is closet to

A particle starts from the origin at t=0 s with a velocity of 10.0hatjm//s and moves in the x-y plane with a constant acceleration of (8.0hati+2.0hatj) " m s"^(-2) (a) At what time is the x - coordinate of the speed of the particle at the time ?