357 lines
No EOL
16 KiB
Text
357 lines
No EOL
16 KiB
Text
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§18
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Scattering
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51
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For a sphere originally at rest, X = n-202 in all cases, and substitution in (1) gives
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do2 = a2|cos 02 do2.
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PROBLEM 2. Express the effective cross-section (Problem 1) as a function of the energy E
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lost by a scattered particle.
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SOLUTION. The energy lost by a particle of mass M1 is equal to that gained by the sphere of
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mass M2. From (17.5) and (17.7), € = E2' = [2m22m2/(m1+m2)2] voo2 sin21x = Emax sin21x,
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whence de = 1 mex sin X dx; substituting in (1), Problem 1, we have do = na2 de/emax. The
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scattered particles are uniformly distributed with respect to € in the range from zero to
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Emax.
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PROBLEM 3. Find the effective cross-section as a function of the velocity Uoo for particles
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scattered in a field U -rrn.
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SOLUTION. According to (10.3), if the potential energy is a homogeneous function of order
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k = -n, then similar paths are such that p ~v-2/n, or p = Voo-2/nf(x), the angles of deflec-
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tion X being equal for similar paths. Substitution in (18.6) gives do ~ Voo-4/n do.
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PROBLEM 4. Determine the effective cross-section for a particle to "fall" to the centre of
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a field U = -a/r2.
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SOLUTION. The particles which "fall" to the centre are those for which 2a > mp20002 (see
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(14.11)), i.e. for which the impact parameter does not exceed Pmax = (2a/mvoo). The
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effective cross-section is therefore o = Pmax2 = 2na/mvo².
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PROBLEM 5. The same as Problem 4, but for a field U = -a/rn (n 2, a > 0).
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SOLUTION. The effective potential energy Ueff = depends on r in the
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manner shown in Fig. 20. Its maximum value is
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Ueff
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U0
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FIG. 20
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The particles which "fall" to the centre are those for which U0 < E. The condition U0 = E
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gives Pmax, whence
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=
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PROBLEM 6. Determine the effective cross-section for particles of mass m1 to strike a sphere
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of mass m2 and radius R to which they are attracted in accordance with Newton's law.
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SOLUTION. The condition for a particle to reach the sphere is that rmin < R, where r'min
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is the point on the path which is nearest to the centre of the sphere. The greatest possible
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value of P is given by rmin = R; this is equivalent to Ueff(R) = E or
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= , where a = ymim2 (2 being the gravitational constant) and we have put m 22 M1 on
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the assumption that m2 > M1. Solving for pmax2, we finally obtain o = mR2(1+2ym2/Rvv3).
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52
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Collisions Between Particles
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§18
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When
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Voo
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8 the effective cross-section tends, of course, to the geometrical cross-section
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of the sphere.
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PROBLEM 7. Deduce the form of a scattering field U(r), given the effective cross-section
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as a function of the angle of scattering for a given energy E. It is assumed that U(r) decreases
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monotonically with r (a repulsive field), with U(0) > E and U(00) = 0 (O. B. FIRSOV 1953).
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SOLUTION. Integration of do with respect to the scattering angle gives, according to the
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formula
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(1)
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the square of the impact parameter, so that p(x) (and therefore x(p)) is known.
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We put
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s=1/r,
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=1/p2,
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[[1-(U|E)]
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(2)
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Then formulae (18.1), (18.2) become
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1/
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(3)
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where so(x) is the root of the equation xw2(so)-so2 = 0.
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Equation (3) is an integral equation for the function w(s), and may be solved by a method
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similar to that used in $12. Dividing both sides of (3) by (a-x) and integrating with respect
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to x from zero to a, we find
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so(a)
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dx ds
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so(a)
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ds
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or, integrating by parts on the left-hand side,
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This relation is differentiated with respect to a, and then so(a) is replaced by s simply;
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accordingly a is replaced by s2/w2, and the result is, in differential form,
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=
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(11/20)
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or
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dx
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This equation can be integrated immediately if the order of integration on the right-hand
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side is inverted. Since for S = 0 (i.e. r oo) we must have W = 1 (i.e. U = 0), we have,
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§19
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Rutherford's formula
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53
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on returning to the original variables r and P, the following two equivalent forms of the final
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result:
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=====
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(dx/dp)
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(4)
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This formula determines implicitly the function w(r) (and therefore U(r)) for all r > rmin,
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i.e. in the range of r which can be reached by a scattered particle of given energy E.
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§19. Rutherford's formula
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One of the most important applications of the formulae derived above is
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to the scattering of charged particles in a Coulomb field. Putting in (18.4)
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U = a/r and effecting the elementary integration, we obtain
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whence p2 = (a2/m2voo4) tan2oo, or, putting 00 = 1(-) from (18.1),
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p2 =
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(19.1)
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Differentiating this expression with respect to X and substituting in (18.7)
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or (18.8) gives
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do = (a/v2cosxdx/sin31
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(19.2)
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or
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do =
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(19.3)
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This is Rutherford's formula. It may be noted that the effective cross-section
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is independent of the sign of a, so that the result is equally valid for repulsive
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and attractive Coulomb fields.
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Formula (19.3) gives the effective cross-section in the frame of reference
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in which the centre of mass of the colliding particles is at rest. The trans-
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formation to the laboratory system is effected by means of formulae (17.4).
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For particles initially at rest we substitute X = 77 - 202 in (19.2) and obtain
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do2 = 2n(a/mvoo2)2 sin de2/cos302
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=
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(19.4)
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The same transformation for the incident particles leads, in general, to a very
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complex formula, and we shall merely note two particular cases.
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If the mass M2 of the scattering particle is large compared with the mass
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M1 of the scattered particle, then X 2 O1 and m 22 M1, SO that
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do1 = = (a/4E1)2do1/sin4301
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(19.5)
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where E1 = 1M1U..02 is the energy of the incident particle.
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54
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Collisions Between Particles
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§ 19
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If the masses of the two particles are equal (m1 = M2, m = 1M1), then by
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(17.9) X = 201, and substitution in (19.2) gives
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do1 = 2(/E1)2 cos 01 d01/sin³01
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=
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(19.6)
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If the particles are entirely identical, that which was initially at rest cannot
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be distinguished after the collision. The total effective cross-section for all
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particles is obtained by adding do1 and do2, and replacing A1 and O2 by their
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common value 0:
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do
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=
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do.
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(19.7)
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Let us return to the general formula (19.2) and use it to determine the
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distribution of the scattered particles with respect to the energy lost in the
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collision. When the masses of the scattered (m1) and scattering (m2) particles
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are arbitrary, the velocity acquired by the latter is given in terms of the angle
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of scattering in the C system by V2' = [2m1/(m1+m2)]%"00 sin 1x; see (17.5).
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The energy acquired by M2 and lost by M1 is therefore E = 1M2U2'2
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= (2m2/m2)/0002 sin21x. Expressing sin 1x in terms of E and substituting
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in (19.2), we obtain
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do = de/e2.
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(19.8)
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This is the required formula: it gives the effective cross-section as a function
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of the energy loss E, which takes values from zero to Emax = 2m2voo2/m2.
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PROBLEMS
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PROBLEM 1. Find the effective cross-section for scattering in a field U = a/r2 (a > 0).
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SOLUTION. The angle of deflection is
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The effective cross-section is
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do
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sin
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PROBLEM 2. Find the effective cross-section for scattering by a spherical "potential well"
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of radius a and "depth" U0 (i.e. a field with U = 0 for r > a and U = - U0 for r < a).
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SOLUTION. The particle moves in a straight line which is "refracted" on entering and leav- -
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ing the well. According to §7, Problem, the angle of incidence a and the angle of refraction
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B (Fig. 21) are such that sin x/sin B = n, where n = W(1+2U0/mVo2). The angle of deflection
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is X = 2(a-B). Hence
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=
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Eliminating a from this equation and the relation a sin a p, which is evident from the
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diagram, we find the relation between P and X:
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cos
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1x
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§20
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Small-angle scattering
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55
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Finally, differentiating, we have the effective cross-section
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cos
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do.
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The angle X varies from zero (for p=0) to Xmax (for P = a), where cos 1xmax = 1/n.
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The total effective cross-section, obtained by integrating do over all angles within the cone
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Xmax, is, of course, equal to the geometrical cross-section 2
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a
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to
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a
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FIG. 21
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§20. Small-angle scattering
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The calculation of the effective cross-section is much simplified if only
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those collisions are considered for which the impact parameter is large, so
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that the field U is weak and the angles of deflection are small. The calculation
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can be carried out in the laboratory system, and the centre-of-mass system
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need not be used.
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We take the x-axis in the direction of the initial momentum of the scattered
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particle M1, and the xy-plane in the plane of scattering. Denoting by P1' the
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momentum of the particle after scattering, we evidently have sin 01 = P1y'/P1'.
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For small deflections, sin 01 may be approximately replaced by 01, and P1' in
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the denominator by the initial momentum P1 = MIUoo:
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(20.1)
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Next, since Py = Fy, the total increment of momentum in the y-direction is
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(20.2)
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The
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force Fy = - JULY (dU/dr)dr/dy = (dU/dr)y/r.
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Since the integral (20.2) already contains the small quantity U, it can be
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calculated, in the same approximation, by assuming that the particle is not
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deflected at all from its initial path, i.e. that it moves in a straight line y = p
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with uniform velocity Voo. Thus we put in (20.2) Fy = - (dU/dr)p/r,
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dt = dx/voo. The result is
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56
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Collisions Between Particles
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§20
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Finally, we change the integration over x to one over r. Since, for a straight
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path, r2 = x2+p2, when x varies from - 00 to + 80, r varies from 8 to P
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and back. The integral over x therefore becomes twice the integral over r
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from p to 80, and dx = r dr/v(r2-p2). The angle of scattering O1 is thus
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given byt
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(20.3)
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and this is the form of the function 01(p) for small deflections. The effective
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cross-section for scattering (in the L system) is obtained from (18.8) with 01
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instead of X, where sin 01 may now be replaced by A1:
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(20.4)
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PROBLEMS
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PROBLEM 1. Derive formula (20.3) from (18.4).
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SOLUTION. In order to avoid spurious divergences, we write (18.4) in the form
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PO
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and take as the upper limit some large finite quantity R, afterwards taking the value as R
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00.
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Since U is small, we expand the square root in powers of U, and approximately replace
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rmin by p:
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dr
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The first integral tends to 1/11 as R 00. The second integral is integrated by parts, giving
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=
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This is equivalent to (20.3).
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PROBLEM 2. Determine the effective cross-section for small-angle scattering in a field
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U=a/m(n) 0).
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t If the above derivation is applied in the C system, the expression obtained for X is the
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same with m in place of M1, in accordance with the fact that the small angles 01 and X are
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related by (see (17.4)) 01 = m2x/(m1 +m2).
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§20
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Small-angle scattering
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57
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SOLUTION. From (20.3) we have
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dr
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The substitution p2/r2 = U converts the integral to a beta function, which can be expressed
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in terms of gamma functions:
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Expressing P in terms of 01 and substituting in (20.4), we obtain
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do1.
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3
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CHAPTER V
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SMALL OSCILLATIONS
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$21. Free oscillations in one dimension
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A VERY common form of motion of mechanical systems is what are called
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small oscillations of a system about a position of stable equilibrium. We shall
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consider first of all the simplest case, that of a system with only one degree
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of freedom.
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Stable equilibrium corresponds to a position of the system in which its
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potential energy U(q) is a minimum. A movement away from this position
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results in the setting up of a force - dU/dq which tends to return the system
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to equilibrium. Let the equilibrium value of the generalised co-ordinate
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q be 90. For small deviations from the equilibrium position, it is sufficient
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to retain the first non-vanishing term in the expansion of the difference
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U(q) - U(90) in powers of q-qo. In general this is the second-order term:
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U(q) - U(q0) 112 1k(q-90)2, where k is a positive coefficient, the value of the
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second derivative U"(q) for q = 90. We shall measure the potential energy
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from its minimum value, i.e. put U(qo) = 0, and use the symbol
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x = q-90
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(21.1)
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for the deviation of the co-ordinate from its equilibrium value. Thus
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U(x) = .
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(21.2)
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The kinetic energy of a system with one degree of freedom is in general
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of the form 1a(q)q2 = 1a(q)x2. In the same approximation, it is sufficient to
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replace the function a(q) by its value at q = qo. Putting for brevity a(go) = m,
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we have the following expression for the Lagrangian of a system executing
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small oscillations in one dimension:
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L = 1mx2-1kx2.
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(21.3)
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The corresponding equation of motion is
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m+kx=0,
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(21.4)
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or
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w2x=0,
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(21.5)
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where
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w= ((k/m).
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(21.6)
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+ It should be noticed that m is the mass only if x is the Cartesian co-ordinate.
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+ Such a system is often called a one-dimensional oscillator.
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58
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§21
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Free oscillations in one dimension
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59
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Two independent solutions of the linear differential equation (21.5) are
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cos wt and sin wt, and its general solution is therefore
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COS wt +C2 sin wt.
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(21.7)
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This expression can also be written
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x = a cos(wt + a).
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(21.8)
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Since cos(wt+a) = cos wt cos a - sin wt sin a, a comparison with (21.7)
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shows that the arbitrary constants a and a are related to C1 and C2 by
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tan a = - C2/C1.
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(21.9)
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Thus, near a position of stable equilibrium, a system executes harmonic
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oscillations. The coefficient a of the periodic factor in (21.8) is called the
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amplitude of the oscillations, and the argument of the cosine is their phase;
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a is the initial value of the phase, and evidently depends on the choice of
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the origin of time. The quantity w is called the angular frequency of the oscil-
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lations; in theoretical physics, however, it is usually called simply the fre-
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quency, and we shall use this name henceforward.
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The frequency is a fundamental characteristic of the oscillations, and is
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independent of the initial conditions of the motion. According to formula
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(21.6) it is entirely determined by the properties of the mechanical system
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itself. It should be emphasised, however, that this property of the frequency
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depends on the assumption that the oscillations are small, and ceases to hold
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in higher approximations. Mathematically, it depends on the fact that the
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potential energy is a quadratic function of the co-ordinate.
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The energy of a system executing small oscillations is E =
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= 1m(x2+w2x2) or, substituting (21.8),
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E =
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(21.10)
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It is proportional to the square of the amplitude.
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The time dependence of the co-ordinate of an oscillating system is often
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conveniently represented as the real part of a complex expression:
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x = re[A exp(iwt)],
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(21.11)
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where A is a complex constant; putting
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A = a exp(ix),
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(21.12)
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we return to the expression (21.8). The constant A is called the complex
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amplitude; its modulus is the ordinary amplitude, and its argument is the
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initial phase.
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The use of exponential factors is mathematically simpler than that of
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trigonometrical ones because they are unchanged in form by differentiation.
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t It therefore does not hold good if the function U(x) has at x = 0 a minimum of
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higher order, i.e. U ~ xn with n > 2; see §11, Problem 2(a).
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60
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Small Oscillations
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§21
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So long as all the operations concerned are linear (addition, multiplication
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by constants, differentiation, integration), we may omit the sign re through-
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out and take the real part of the final result.
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PROBLEMS
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PROBLEM 1. Express the amplitude and initial phase of the oscillations in terms of the
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initial co-ordinate xo and velocity vo.
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SOLUTION. a = (xx2+002/w2), tan a = -vo/wxo.
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PROBLEM 2. Find the ratio of frequencies w and w' of the oscillations of two diatomic
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molecules consisting of atoms of different isotopes, the masses of the atoms being M1, m2 and
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'M1', m2'.
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SOLUTION. Since the atoms of the isotopes interact in the same way, we have k = k'.
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The coefficients m in the kinetic energies of the molecules are their reduced masses. Accord-
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ing to (21.6) we therefore have
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PROBLEM 3. Find the frequency of oscillations of a particle of mass m which is free to
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move along a line and is attached to a spring whose other end is fixed at a point A (Fig. 22)
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at a distance l from the line. A force F is required to extend the spring to length l.
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A
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X
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FIG. 22
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SOLUTION. The potential energy of the spring is (to within higher-order terms) equal to
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the force F multiplied by the extension Sl of the spring. For x < l we have 81 = (12++2) -
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=
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x2/21, so that U = Fx2/21. Since the kinetic energy is 1mx2, we have = V(F/ml).
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PROBLEM 4. The same as Problem 3, but for a particle of mass m moving on a circle of
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radius r (Fig. 23).
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m
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&
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FIG. 23 |