An electron projectes with velocity `vecv=v_(0)hati` in the electric field `vecE=E_(0)hatj`. There the path followed by the electron `E_(0)`.

An electron is moving with an initial velocity vecv=v_(0)hati and is in a magnetic field vecB=B_(0)hatj . Then it's de-Broglie wavelength

An electron is moving with an initial velocity vecv=v_(0)hati and is in a magnetic field vecB=B_(0)hatj . Then it's de-Broglie wavelength

An electron (mass m) with an initial velocity vecv=v_(0)hati is in an electric field vecE=E_(0)hatj . If lambda_(0)=h//mv_(0) . It's de-broglie wavelength at time t is given by

An electron (mass m ) with initival velocity vecv = v_(0) hati + v_(0) hatj is the an electric field vecE = - E_(0)hatk . It lambda_(0) is initial de - Broglie wavelength of electron, its de-Broglie wave length at time t is given by :

An electron is moving initially with velocity v_o hati+v_ohatj in uniform electric field vec E=-E_0 hatk . If initial wavelength of electron is lambda_0 and mass of electron is m. Find wavelength of electron as a function of time.

An electron is projected with velocity v_(0) in a unifrom electric field E perpendicular to the field Again it is projectced with velocity v_(0) perpendicular to a unifrom magnetic field B . if r_(1) is initial radius of curvature just after entering in the electric field and r_(2) is initial radius of curvature just after entering in magnetic field then the ratio r_(1)//r_(2) is equal to .

An electron of mass m with an initial velocity vec(v) = v_(0) hat (i) (v_(0) gt 0) enters an electric field vec(E ) =- E_(0) hat (j) (E_(0) = constant gt 0) at t = 0 . If lambda_(0) is its de - Broglie wavelength initially, then its de - Broglie wavelength at time t is

An electron (mass m) with initial velocity vecv = v_0 hati + 2v_0 hatj is in an electric field vecE = E_0 hatk . If lamda_0 is initial de-Broglie wavelength of electron, its de-Broglie wave length at time t is given by :

A proton is projected with velocity vecV=2hati in a regionn where magnetic field vecB=(hati+3hatj+4hatk)muT and electric field vecE=10hatimuV//m . Then find out the net acceleration of proton:

An electron (mass m) with initial velocity bar(v) = -v_(0)hati + 3v_(0)hatk is in an electric field hatE = = 2E_(0)hatj . If lamda_(0) is initial de-Broglie wavelength of electron, its de-Broglie wave length at time t is given by :