Problems 53interacting with a static electromagnetic field is given byH=
∑N
i=1(pi−qiA(ri)/c)^2
2 mi+
∑N
i=1qiφ(ri) +N∑− 1
i=1∑N
j=i+1qiqj
|ri−rj|,
whereA(r) andφ(r) are the vector and scalar potentials of the field, respec-
tively, andcis the speed of light. In terms of these quantities, the electric and
magnetic components of the electromagnetic field,E(r) andB(r) are given
by
E(r) =−∇φ(r), B(r) =∇×A(r).
It is assumed that, although the particles are charged, they do not interact
with each other, i.e. an ideal gas in an electromagnetic field. If the density is
low enough, this is not an unreasonable assumption, as the interaction with
the field will dominate over the Coulomb interaction.a. Derive Hamilton’s equations for this system, and determine the force on
each particle in terms of the electric and magnetic fieldsE(r) andB(r),
respectively. This contribution to the force due to the field is knownas
theLorentz force. Express the equations of motion in Newtonian form.b. SupposeN= 1, that the electric field is zero everywhere (E= 0), and
that the magnetic field is a constant in thezdirection,B= (0, 0 ,B). For
this case, solve the equations of motion for an arbitrary initial condition
and describe the motion that results.1.14 Prove that the energy in eqn. (1.11.46) is conserved making useof eqn.
(1.11.47) for the torques.∗1.15 (For amusement only): Consider a system with coordinateq, momentump,
and Hamiltonian
H=pn
n+
qn
n,
wherenis an integer larger than 2. Show that if the energyEof the system
is chosen such thatnE=mn, wheremis a positive integer, then no phase
space trajectory can ever pass through a point for whichpandqare both
positive integers.