fundamentals of nuclear engineeringnuclear engineering module 6: neutron diffusion dr. john h....
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Fundamentals of Nuclear Engineering
Module 6: Neutron Diffusion
Dr. John H. Bickel
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Objectives:1. Understand how Neutron Diffusion explains reactor
neutron flux distribution2. Understand origin, limitations of Neutron Diffusion from:
• Boltzmann Transport Equation, • Ficke’s Law
3. Solution of One-Group Neutron Diffusion Equation for: • Cubical, • Cylindrical geometries (via separation of variables technique)
4. Identify Eigenvalues of Neutron Diffusion Equation (Buckling, Diffusion Length) related to physical properties
5. Understand refinements from Multi-Group Diffusion Model applied to Reflectors, flux depression near strong neutron absorbers, and sources
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Boltzmann’s Transport Equation• Originates from Statistical MechanicsStatistical Mechanics
• Used to understand kinetic theory of gasses
• Full equation expressed as integral-differential equation
• In simplest terms it is a conservation equationconservation equation
∫ ∫∫∫ •−Σ−=V
cVV
dAntvrJrdtvrvtvrNrdtrSrdtvrNdtd rr
),,(),,(),,(),(),,( 333
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Boltzmann’s Transport Equation
• First simplification: Apply Divergence TheoremApply Divergence Theorem
• Remove volume integration:
• Divergence of Local Neutron Current is simplified by making “Diffusion Approximation”
• Alternate solution approach is via Monte Carlo Method• Diffusion Approximation is based upon Fick’sFick’s LawLaw
∫∫ •∇=•V
rdtvrJdAntvrJ 3),,(),,(rrrr
),,(),,(),,(),(),,( tvrJtvrvtvrNtrStvrNdtd
c
rr•∇−Σ−=
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Diffusion Approximation Assumes:• Uniform relatively infinite medium thus: Σc(r) ~ Σc
• No strong “point” neutron sources in medium
• Scattering collisions in Laboratory Frame of Reference are isotropic, thus: dσs/dΩ ~ σs/4π
• Neutron flux Φ(r) is slowly varying function of position (no discontinuities, small dΦ/dr and higher terms)
• Neutron flux Φ(r) is independent of time
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Diffusion Approximation to Neutron Transport• Expression for neutron streaming loss becomes
• Term: Σs / 3Σt2 = D - diffusion coefficient – assumed to be assumed to be
spatially constantspatially constant
• Common approximation: D ~ 1/ [3 Σs(1- 2/3A)]
• Neutron transport equation becomes:
φφφ 2222 33
∇−=∇ΣΣ
−=∇•∇ΣΣ
−=•∇ DJt
s
t
srrr
)()()()(
)()()()()(
2
2
rDrrrS
rDrvrNrSdt
rdN
c
c
φφ
φ
∇+Σ−=
∇+Σ−=
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Diffusion Approximation to Neutron Transport
• Neutrons are mono energetic and physical properties are averages
• D(E) ~ D - for some energy rangesome energy range
• Σt (E) ~ Σt - for some energy rangesome energy range
• Σc(E) ~ Σc - for some energy rangesome energy range
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What is Meant for: “some energy range”some energy range”• From previous lectures: • Effect of resonance scattering and absorption we know is complexcomplex
• Using “single values” to represent Σs(E) or Σc(E) is hard to believe• Once neutrons pile up in thermal region use of thermal averaged values
would seem reasonable• Analytical technique is to break up energy spectrum into numerous energy
groups and compute average values of key parameters• As an example an averaged capture cross section for energies between Ei
and Ej would be:
• This implies multiple onemultiple one--speed diffusion equations, speed diffusion equations, with multiple constantsmultiple constants
∫
∫ Σ
=Σj
i
j
i
E
E
E
Ec
ijc
dEE
dEEE
)(
)()(
,
φ
φ
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Steady State Neutron Diffusion
• In steady state, diffusion equation is balance between source (+) vs. capture and diffusion (-)
• Types of neutron sources S(r) could be:• (α,n) reaction type source (Pu-Be, or Am-Be) • Neutrons produced via (n,f) chain fission reaction and
thus proportional to flux: Φ(r)S(r) = Σc(r) k Φ(r)
• - where “k” is multiplication factor•• More to come on multiplication factors More to come on multiplication factors -- laterlater
)()()()( 2 rDrrrS c φφ ∇−Σ=
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Diffusion from Point Neutron Source
• In spherical geometry, Laplacian operator becomes:
• Diffusion equation becomes after rearranging:
• Making change of variables: y(r) = r Φ(r), above expression simplifies to:
drrd
rdrrdr )(2)()( 2
22 φφφ +=∇
DSr
Ddrrd
rdrrd oc −=
Σ−+ )()(2)(
2
2
φφφ
DSry
Ddrryd oc −=
Σ− )()(
2
2
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Diffusion from Point Neutron Source• Solution: Define L2 = D / Σc - then y(r) = A e-r/L + B er/L
• Changing back to flux: Φ(r) = y(r) / r
• General solution: Φ(r) = A e-r/L/ r + B er/L/ r
• Specific solution uses Boundary Conditions:(i) Φ(r) → 0, as r →∞ - thus B = 0(ii) As r → 0, no captureno capture, J = - D dΦ(r)/dr = So/4πr2
- D dΦ(r)/dr = (DA / L r) e-r/L + (DA / r2 ) e-r/L = So/4πr2
• Canceling r2 this is: (DA r/ L) e-r/L + (DA) e-r/L = So/4π
• Taking limit r → 0, shows: A = So/ 4πD
• Thus: Φ(r) = Soe-r/L / 4πrD
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Diffusion from Point Neutron Source• Neutron source submerged
in water emits 106 thermal neutrons/sec
• Σs =3.45cm-1,Σc =0.022cm-1
• D =1/ Σs(1-2/3) = 0.87cm
• L = (D / Σc)1/2 = 6.287
CAUTION: CAUTION: we assumed we assumed thermal neutron sourcethermal neutron source..
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Neutron Diffusion in Different Geometries
• Laplacian operator for different geometries:
• Rectangular: ∂2Φ/ ∂x2+ ∂2Φ/ ∂y2+ ∂2Φ/ ∂z2 - (Σc/D)Φ = - S/D
• Cylindrical: ∂2Φ/ ∂r2+(1/r) ∂Φ/ ∂r+ ∂2Φ/ ∂z2 - (Σc/D)Φ = - S/D
• Spherical: ∂2Φ/ ∂r2 +(2/r) ∂Φ/ ∂r - (Σc/D)Φ = - S/D
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Cubical Reactor Geometry:
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Separation of Variables Solution of 3-D Neutron Diffusion Equation
• Rectangular geometry: a · b · c• Assume flux vanishes at edges: (±a/2, ±b/2, ±c/2)
∂2Φ/ ∂x2+ ∂2Φ/ ∂y2+ ∂2Φ/ ∂z2 - (Σc/D)Φ = - S/D• Assume neutron source is: S = ΣckΦ• Assume: Φ(x,y,z) = F(x)G(y)H(z) Equation becomes:
G(y)H(z) ∂2F/ ∂x2+ F(x)H(z) ∂2G/ ∂y2+ F(x)G(y) ∂2H/ ∂z2
= (Σc/D)(1-k) F(x)G(y)H(z)
• Dividing out: F(x)G(y)H(z) from both sides yields:
(∂2F/ ∂x2)/F(x)+ (∂2G/ ∂y2)/G(y)+ (∂2H/ ∂z2)/H(z) = (Σc/D)(1-k)
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• Given boundary conditions: F(±a/2) = 0, F(x) = cos(xπ/a)
• Similarly: G(y) = cos(yπ/b), H(z) = cos(zπ/c)
(∂2F/∂x2)/ F(x) = - (π/a)2
(∂2G/∂y2)/ G(y) = - (π/b)2
(∂2H/∂z2)/ H(z) = - (π/c)2
• Overall equation satisfies: [(π/a)2+(π/b)2+(π/c)2] = (Σc/D)(1-k)
• Define Geometrical BucklingGeometrical Buckling: B2 = [(π/a)2+(π/b)2+(π/c)2]
• B2 is Eigenvalue of Helmholz-type equation: ∇2Φ + B2Φ = 0
Separation of Variables Solution of 3-D Neutron Diffusion Equation
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Rectangular Flux Profile: Φ(x,y,z) = F(x)G(y)H(z)
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Cylindrical Reactor Geometry:
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• Separation of variables in cylindrical geometry proceeds in similar fashion
• Cylindrical dimensions: radius = R, Height = H• Assume flux vanishes at: (R, ±H/2)
∂2Φ/ ∂r2+(1/r) ∂Φ/ ∂r+ ∂2Φ/ ∂z2 - (Σc/D)Φ = - S/D• Assume: Φ(r,z) = F(r)G(z) - equation becomes:
[∂2F/ ∂r2+(1/r) ∂F/ ∂r] G(z) + F(r) ∂2G/ ∂z2
= - (Σc/D)(1-k) F(r)G(z)• Dividing out F(r)G(z) from both sides yields:
[∂2F/ ∂r2+(1/r) ∂F/ ∂r]/ F(r) + [∂2G/ ∂z2]/G(z) = - (Σc/D)(1-k)
Separation of Variables Solution of 3-D Neutron Diffusion Equation
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• Axial portion is similar to that of cubical geometry:
(∂2G/∂z2)/ G(z) = - (π/H)2 → G(z) = cos(zπ/H)
• Radial portion involves Bessel Function of first kindBessel Function of first kind:
[∂2F/ ∂r2+(1/r) ∂F/ ∂r]/ F(r) = - (2.405/R)2
F(r) = Jo(2.405 r / R)
• Overall Geometrical Buckling for a cylinder is expressed:
B2 = [(2.405/R)2 + (π/H)2 ]
Separation of Variables Solution of 3-D Neutron Diffusion Equation
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Cylindrical Flux Profile: Φ(r,z) = F(r)G(z)
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Geometrical Buckling for Other Geometries
• Geometrical Buckling factor captures surface to volume effects of different geometries
• Buckling factors are for barebare, unun--reflectedreflectedsystems:
Taken from: J. Lamarsh, “Nuclear Reactor Analysis, p.298
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Vacuum Boundary Correction
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Vacuum Boundary Condition Approximation• Simple diffusion calculations have
assumed Φ vanishes at boundary
• Obviously neutrons will stream out of core region at boundary unless reflected backreflected back
• Flux Φ would vanish at distance “d”given by: dΦ/dx = - Φo / d
• Solving for current at boundary via diffusion approximation yields: d ~ 2D
• Since: D = (1/3)λtr (λtr is mean free transport length) - thus: d ~ (2/3)λtr
• Detailed numerical analysis via transport methods indicate:
d = 0.71 λtr
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Corrections Needed for Deviations from Transport Equation Simplification
• We “casually” employed some assumptions not consistentnot consistent with transport equation simplifications
• “No discontinuities”• Diffusion constant does not vary
spatially•• Multiplying media is highly Multiplying media is highly
discontinuousdiscontinuous• Small Gradient terms: dΦ/dr
Maybe not so bad – but depends on previous item
• Assumption of bare, non-reflecting media implies high neutron leakage
• Power reactors designed to reduce leakage via neutron reflector
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Multi-Group Diffusion: Need for Numerical Models
• One Group Diffusion Model reasonably predicts thermal flux in simple uniform geometriessimple uniform geometries
• Analyzing effects of flux depression near fuel pellets or control rods (very strong absorbers) necessitates considering multiple neutron groups
• Simplest form is 2-Group Diffusion model:
• Fast neutron source is from fast and thermal fission• Thermal neutron source is thermalized fast neutrons•• We will use this model in future to discuss critical conditionsWe will use this model in future to discuss critical conditions
fffaff DS φφ 20 ∇+Σ−= − thththathth DS φφ 20 ∇+Σ−= −
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Multi-Group Diffusion: Need for Numerical Models
• Consideration of many neutron groups improves accuracy but adds numerical computation complexity
•• Additional sourcesAdditional sources: scattering inscattering in from other energy groups
•• Additional sinksAdditional sinks: scattering outscattering out to other energy groups
• Multi-group diffusion equations are solved via numerical matrix solvers
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Example Application of Multi-Group Diffusion
• Suppose we want to understand temperature distribution within fuel pellet
• Thermal neutrons strongly absorbed as they move from moderator into fuel pellet
• This causes flux depressionflux depression• Fission neutrons leak out of
fuel quickly• Fast flux is peaked in center• Heat generation within pellet:
q(r) ~ Σ Φ(r,Ei)Σf(Ei)Efission
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Modeling of Reflectors
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Reflector Region is Water Outside Reactor Core
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Modeling Reflector Involves System of Equations
• Two region system of diffusion equations:
• - no neutron source within reflector region
• Subscript “c” refers to core region, “r” refers to reflector region
• Boundary conditions at edge of core must match: Φc(Rc) = Φr(Rc)
• Flux gradient must not be discontinuous at edge: dΦc /dr(Rc) = dΦr /dr(Rc)
•• Problem:Problem: We should consider fast neutrons leaking from core but thermalizing in reflector region and bouncing back into core region
rrrar
cccaccac
D
Dk
φφ
φφφ2
2
0 ∇−Σ=
∇−Σ=Σ
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Modeling Reflector Involves System of Equations• At this point we must jump to numerical solution!numerical solution!• Escaping fast neutron flux readily thermalizes in water region• Increased thermal neutrons in reflector raises flux at periphery
of reactor core
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Limitations of Diffusion Theory• Stacey notes in Nuclear Reactor Physics (p. 49):• “Diffusion theory is a strictly valid mathematical description
of neutron flux….when assumptions used in derivation are when assumptions used in derivation are satisfiedsatisfied.”
• Absorption is less likely in moderator region, hence flux shape in moderator region is reasonably accuratereasonably accurate
• Flux within fuel pellets is impacted by very strong neutron absorption, hence flux shape in fuel pellets less accurateflux shape in fuel pellets less accurate
• Diffusion theory is widely used in reactor analysis •• SECRET:SECRET: “use transport theory to make diffusion theory
work in specific areas where it would be expected to fail”• “Numerous small elements in reactor are replaced by
homogenized mixture with effective averaged cross sections and diffusion coefficients”
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Summary• Neutron diffusion theory works well outside of fuel pelletsoutside of fuel pellets
• Neutron diffusion originates from Boltzmann’s equation
• Neutron diffusion models: neutron sources, sinks, leakage at periphery
• General approach is to develop energy group dependentenergy group dependentconstantsconstants for: D, Σt , Σa
• Diffusion theory is pretty good explaining general reactor neutron flux profiles
• Reactor physicists know how to correct known weaknessesknown weaknessesof diffusion theory via adjustmentsadjustments