APR1400 General Arrangement PDF

Summary

This document provides an overview of the APR1400 nuclear power plant, outlining its general arrangement, reactor coolant system, reactor vessel, steam generator, pressurizer, reactor coolant pump, turbine, and generator. It includes diagrams and descriptions, emphasizing the design features and functionalities of each component.

Full Transcript

APR1400 General Arrangement

41
 APR1400 Nuclear Steam Supply
System in Containment

42
 NSSS – Reactor Coolant System

Loop configuration
1 Reactor vessel
1 Pressurizer
2 Steam generators
4 Recirculating Coolant
Pumps
2 Hot legs, 4 Cold legs

43
 NSSS – Reactor Vessel

4 Inlet nozzles, 2 Outlet nozzles
and 4 Direct Vessel Injection
(DVI ) nozzles.

Provides barrier to fission
product release

Part of coolant system
pressure boundary

44
 NSSS – Steam Generator (SG)

SG tube design
No. of tubes per SG : 13,102
Plugging margin : 10 %
Material : Inconel 690

Improved upper tube support
bar and plate
To reduce flow-induced vibration

Modified primary outlet nozzle
angle
To improve stability of mid-loop
operation

45
 NSSS – Pressurizer

Design values
Total Free volume : 2,400 ft3 (67.9 m3) 4 POSRV
Coolant volume at full power : 1,100 ft3 (31.1 m3) Nozzles
Heater capacity : 2,400 kW

Increased pressurizer volume
Enhance capability against RCS transients

Pilot Operated Safety Relief Valve (POSRV)
4 POSRVs
Function both over-pressure protection and safety
depressurization
Reliable valve operation without chattering and
leakage
Low valve stuck-open susceptibility

46
 NSSS – Reactor Coolant Pump (RCP)

Type
Vertical bottom suction
Horizontal discharge
Single stage impeller
Motor-driven centrifugal pump
Speed : 1,190 rpm

Shaft seal assembly
Two face-type mechanical seals
Reduce the RCS pressure to volume control
tank pressure
Third face-type low-pressure vapor seal
Withstand RCS pressure when RCP is stopped

47
 Turbine & Generator

Turbine
Number : 1 double flow HP
TBN, 3 double flow LP TBN
Type : Tandem-Compound
Turbine Speed : 1,800 rpm
Output : 1,455 MWe
Last Stage Blade : 52 inch
LSB

Generator
Number : 1
Type : Direct Driven
(conductor cooled)
Voltage : 24 kV, 3Phase
Frequency : 60 Hz

48
 Reactor Power System Layout

49
 Where the Thermal Energy (Heat) Comes From

UO2 fuel pellet. Enriched to
3-5 percent U-235

50
 Logarithmic Distance Scale (Meters)

Electron
~ 10-17 meters ~ meters
~ 10-2 meters
~ 10-10 meters

10-25 10-20 10-15 10-10 10-5 100 105 1010

1
Neutron 1 meter
~ 10-15 meters
~ 105
meters

Distance
to sun
~ 10-9
~ 10-14 meters meters ~ 1011
meters
51
 Fundamental Nuclei ~10-14m
Particles

4He 16O

Proton +
235U

Materials ~10-2m
Neutron
Machines (meters)

- Crystal
Atoms ~10-10m ~10-9m
Structures

+

 +n+++

52
 Fundamental
Particles Nuclei ~10-14m

4He
The world is composed
16O
of various subatomic
Proton + particles
235U – Also referred to as
fundamental particles
Neutron
To understand nuclear
- reactions
– We need to have a
Atoms ~10-10m
basic understanding of
+ some of these
fundamental particles

 +n+++

53
 Fundamental Particles (continued)

Fundamental
Particles For our purposes we will concern ourselves with
only the following fundamental particles:

Particle Symbol Charge Mass Half-life
Proton +
proton p +e 1.673×10-27 kg stable?
neutron n 0 1.675×10-27 kg 10.4
min
Neutron
electron -, e- -e 9.109×10-31 kg stable
positron + +e 9.109×10-31 kg stable
-
neutrino 0 ? stable
photon  0 0 stable
+
1 Electron charge (-e) = 1.6022×10−19 Coulomb
 1 ampere = 1 Coulomb/sec = 6.24 ×1018 electrons/sec
54
 Atomic Structure

Atoms consists of a small, dense, positively
charged nucleus surrounded by a cloud of
negatively charged electrons.
n+
Niels Bohr: Electrons rapidly travel around the e-
nucleus in discrete orbits. An electron in one of
these orbits (or shells) has a discrete amount of
energy.
Simplified
representation of an
Atomic nucleus contains atom. NOT to scale.

– Positively charged protons and
– Electrically neutral neutrons.
Except for the atomic nucleus of hydrogen-1 which
contains only one proton and no neutrons.

Protons and neutrons are called nucleons.

55
 Atomic Structure (continued)

Chemical properties of an atom are determined
by the number of electrons and their distribution
around the nucleus.

Nuclear properties of an atom are determined by

+n+++
the atomic nucleus. It is responsible for all nuclear
effects: radioactive transformation, nuclear
energy, etc.

Nucleus contains nearly all the mass of the atom.

Subatomic particle Mass
Proton 1.67262 ×10-27 kg
Neutron 1.674929 ×10-27 kg
Electron 9.10939 ×10-31 kg

56
 Terminology and Notation
A
Atoms and nuclei are denoted as
Z X
X – symbol representing a chemical element. For
example: H, C, O, Au, Na, U, etc.

Z – atomic number: number of protons in the atomic n+ e-
nucleus (also, number of electrons in an electrically
neutral atom).

A – atomic mass number: total number of nucleons
Examples:
in the nucleus.
235
Atomic nucleus consists of Z protons and N neutrons 92 U 6
3 Li
N = A – Z neutrons. N – neutron number. 239
94 Pu
Nuclide is a species of atom characterized by its
atomic number Z and mass number A and the
energy state of the nucleus.

57
 Isotopes

The atomic number Z (the
number of protons in the nucleus) A
uniquely identifies a chemical Z X
element.

Isotopes – nuclides with the same
number of protons but different
number of neutrons.
n+ e-
– Example: isotopes of carbon,
12C, 13C, 14C.
6 6 6

C-12, C-13, C-14

58
 Forces Inside Atoms and Nuclei

Electrostatic force described by Atom ~10-10m
Coulomb's law: Like charges repel
each other, opposite charges attract.

This force holds atoms together: +n+++

In the nucleus, protons and neutrons
are held together by a much stronger
nuclear force (or strong force).
Nuclei ~10-14m
– Nuclear force has a very short range: ~10-15
4He
meters. 16O

– Nuclear force overcomes the repulsive
(electrostatic) force acting between protons.
– Nuclear force is responsible for release of 235U
energy when a nucleus breaks apart.

59
 Four Fundamental Forces

Gravity – attractive force between masses.

Weak force – associated with some radioactive decay modes.

Electromagnetic force – exists between charged particles.

Nuclear force (Strong force) - strong attractive force between
all nucleons (protons and neutrons).

The strength of these four fundamental forces range over ~40
orders of magnitude:

Nuclear Electromagnetic Weak Gravity
1 1·10-2 1·10-15 1·10-39

60
 Stability of the Nucleus

The balance between the attractive and repulsive
forces determines the stability of a nucleus.

The most important factor is the neutron-to-proton ratio.

For light nuclei, Z ~ N and their neutron-to-proton ratio is
about one (N : Z is about 1:1).

For nuclei with A > 40, more neutrons are needed to
balance the repulsive forces between the protons. For
stable atoms, the neutron-to-proton ratio approaches
1.5.

If the nucleus has more neutrons than needed for
stability or doesn’t have enough neutrons, the atom is
unstable.

An unstable nucleus will attempt to become stable by
emitting particles or energy. -- Radiation

61
 Band of Stability

Source: adapted from http://en.wikipedia.org/wiki/File:Isotopes_and_half-life.svg

62
 Radiation

An unstable nucleus will attempt to become stable
by emitting particles or energy. -- Radiation

Radiation is energy traveling through
space or matter in the form of
particles or electromagnetic waves.
-, +
Radiation includes:
Alpha particles
Beta-rays
Gamma-rays
n
Neutrons
Neutrinos

Cosmic rays

63
 Radiation and Radioactivity

Radiation is produced
– via decay of a nucleus
– as a byproduct of nuclear and atomic reactions

Atoms with unstable nuclei are radioactive.
They can spontaneously transform into other
nuclides. As they do so, they emit radiation of
one type or another.

Terminology:
– Radionuclide – a radioactive nuclide.
– Radioisotope – a radioactive isotope.

64
 Activity

Source activity (A)
– The rate of radioactive decay (decays/sec)

– Common units
Becquerel (Bq) – one Bq is one decay per second
Curie (Ci) – one curie is equal to 3.7 x 1010 decays per second

Calculating activity:
A=N
N = the number of radioactive atoms in the sample
λ = the decay constant
(Probability of decay per unit time per radioactive atom)

65
 Decay Constant and Half-life

Decay constant (λ)
– Probability of decay per unit time per radioactive atom
– λ is constant for all time and for all atoms of the same
species

ln( 2) 0.693
= =
t1/ 2 t1/2

– Half-life (t1/2 ) of the radioactive atoms in a sample is
The time required for half of the radioactive atoms in the
sample to decay: N(t1/2) = ½ N(t=0)
The time during which the activity of the sample
decreases by a factor of two: A(t1/2) = ½ A(t=0)

66
 Decay of a Radionuclide Sample

1.0
Sr-82
Normalized concentration of radioactive atoms,

0.9 T1/2 = 25.36 days

0.8

0.7

0.6 U-238
T1/2 = 4.47 x 109 years
0.5
N/N0

0.4

0.3

0.2

0.1

0.0
0 1 2 3 4 5 6 7 8 9 10
Time in units of half-life, t 1/2

67
 Chart of the Nuclides http://atom.kaeri.re.kr/ton/nuc1.html

A tabulated chart that lists the stable and unstable
nuclides.

The chart is a two-dimensional graph in which the nuclides
are arranged with their atomic number Z along the vertical
axis and their neutron number N along the horizontal axis.

Each point (square) plotted on the graph represents the
nuclide of a real or hypothetical chemical element.

The chart offers a greater insight into the characteristics of
isotopes than the periodic table, which shows only
elements but not the isotopes.

Z
N

68
 Isotopic Abundance
Stable and unstable isotopes of various chemical
elements are found in nature.

Some isotopes of a given element are more
abundant than other isotopes of the element.

Isotopic abundances are given in atom percent.
Abbreviation: a/o.

In one million uranium atoms, how many atoms of
each isotope are present?

238U : 99.2745 a/0

235U : 0.7200 a/0

234U : 0.0055 a/0

Z

69
N
 Isotopic Abundance Example

Uranium has three naturally occurring isotopes: 234U,
235U and 238U.

Their abundances 0.0055%, 0.72% and 99.2745%
respectively.

In one million uranium atoms, how many atoms of
each isotope are present?

Expected numbers of atoms:
– approximately 55 234U atoms
– 7,200 235U atoms, and
– 992,745 238U atoms.

70
 Enriched and Depleted Uranium

All isotopes of uranium have
– The same chemical properties
– different nuclear properties.

Uranium with 3-5% 235U is used in most power reactors.
Natural uranium ore is only 0.72% 235U.

Enrichment is the process of increasing the proportion of
a particular isotope.

Enriched uranium is uranium in which the concentration
of 235U is greater than in natural uranium ore.

Depleted uranium is uranium in which the concentration
of 235U is less than its natural value of 0.72%.

71
 Stability of the Nucleus (Review)

The balance between the attractive and repulsive forces
determines the stability of a nucleus.
1
The most important factor is the neutron-to-proton ratio. 1 H
For light nuclei, Z ~ N and their neutron-to-proton ratio is
about one (N : Z is about 1:1). n
+ e-
For nuclei with A > 40, more neutrons are needed to 12
C
6
balance the repulsive forces between the protons. For
stable atoms, the neutron-to-proton ratio approaches 1.5

If the nucleus has more neutrons than needed for stability
or doesn’t have enough neutrons, the atom is unstable.

+n+++
An unstable nucleus will attempt to become stable by
emitting particles or energy -- Radiation. 208
82 Pb
72
 Radioactive Decay

The figure shows all of the
stable nuclides as a function Atomic Number (Z) Versus Neutron
of Z (vertical axis) and N Number (N) for All Known Stable
Isotopes
(horizontal axis)
140
– Note that there are more neutrons Z=N Line
120 Neutron
than protons in most nuclei Poor
100

– The extra neutrons provide +
80
nuclear stability

Z
60
-
There are only certain 40
Neutron
combinations of N and Z that 20 Rich

produce stable nuclei 0
0 20 40 60 80 100 120 140
– The rest are radioactive N

Author: Dr. Charlton, NUEN, TAMU

73
 Beta Decay +

Neutron rich isotopes are
typically β - emitters Atomic Number (Z) Versus Neutron
Number (N) for All Known Stable
Isotopes
A
Z
X → A
Z +1
Y +  + 00 e
0
−1
140
Z=N Line
− − Neutron
n ⎯⎯→ p + e + ve
120
Poor
100

80 +
Neutron poor isotopes are

Z
generally β+ emitters (or 60
electron capture, E.C.) 40
-
Neutron
X → Y + 10 + 00 e
A A 20 Rich
Z Z −1
0
0 20 40 60 80 100 120 140
+ +
p ⎯⎯→ n + e + ve N

Author: Dr. Charlton, NUEN, TAMU
Fission products are typically
neutron rich
74
 Beta Decay (continued)

Consider the
excerpt from
the Chart of
the Nuclides

Z

N Source: http://atom.kaeri.re.kr/ton/nuc1.html

The element sodium (Z=11) has various isotopes
(N=11, N=12, N=13, …)
only Na-23 (Z=11, N=12) is stable
+

Na-22 decays by β+ emission p ⎯⎯ → n + e+ + ve

Na-24 decays by β- emission −
n ⎯⎯→ p + e + ve
−

75
 Beta Decay (continued)

Often, the daughter nucleus is also unstable and will undergo
an additional β- decay

This leads to a decay chain:
20
8
O → 9F +
20
 + 00
0
−1
20
9
F → Ne + 20
10
0
−1
 +
0
0

– Where Ne-20 is stable

Source:http://atom.kaeri.re.kr/ton/nuc1.html

76
 Alpha Decay

The mode of decay for any Atomic Number (Z) Versus Neutron
isotope is determined by its Number (N) for All Known Stable
Isotopes
position on the chart of the
nuclides. 140

120 Neutron Z=N Line

Heavy elements are typically 100
Poor

α - emitters 80 +

– An alpha particle is an

Z
60
energetic helium nucleus (2 -
protons and 2 neutrons) 40
Neutron
20 Rich

A− 4
A
Z
X → Y + 
Z −2
4
2
0
0 20 40 60 80 100 120 140
N
Heavy elements might also Author: Dr. Charlton, NUEN, TAMU
spontaneously fission

77
 Gamma Decay Example
Nuclides often emit gamma rays
in addition to other radiations; these
emissions usually serve to bring the 60Co
product nucleus to its ground state

60Co decays as follows:
99+% 2.506 MeV
0.013%
60
27
Co → 60
28
Ni +  + 00 + 
0
−1 0.12%
2.158 MeV

1.332 MeV

Thus, most of the time 60Co
emits two gamma rays of
1173 and 1332 keV
60Ni
60Cohas a half-life of 5.27
Author: Dr. Charlton, NUEN, TAMU
years or
t1/ 2 = 5.27 yrs

78
 Atomic Weight

Using the data below, compute the atomic weight
of naturally occurring uranium.

Uranium has three naturally occurring isotopes:
234U, γ(234U) = 0.0055%, M(234U) = 234.0409456
235U, γ(235U) = 0.72%, M(235U) = 235.0439231
238U, γ(238U) = 99.2745%, M(238U) = 238.0507826

M(U) = (0.0055 * 234.041 + 0.72 * 235.044 +
99.2745 * 238.051) / 100 = 238.0289127
= 238.03

79
 Atomic Mass Unit, Moles, and Avogadro
Atomic Mass Unit (amu)
– numerically equivalent to the atomic weight of an atom
– one-twelfth the mass of the neutral carbon-12 atom
1
1 amu =  m(12 C )
12

1 amu = 1.66057 × 10-24 g

Mole – equal to the quantity containing as many elementary units as
there are atoms in 12 grams of 12C

Avogadro’s number – the number of atoms or molecules in one mole
of any substance: NA = 6.022 × 1023 mol-1

Example: One mole of carbon-12 has a mass of exactly 12 g. Hence,
we can calculate the mass in grams of one atom of 12C:
12 g / (6.022 × 1023) = 1.99 × 10-23 g
80
 Atomic and Nuclear Dimensions

Neither atoms nor nuclei have a sharp outer
boundary. U-238

Atomic radius represents the average distance
between the nucleus and the boundary of the R
electron cloud. It depends on the atomic number Z.

The average radii are approximately the same for all
atoms: about 200 x 10-12 m (picometers - pm)
(Except for a few of the lightest atoms: H, B, C, N, etc.) Atomic Radius, RA
≈ 200 picometers
Nucleus ~ sphere with radius = 200,000 fm
R = 1.25 fm × A1/3
where A is the atomic mass number, U-238
and 1 femtometer = 1 fm = 10-15 m Nuclear Radius, RN
RN = 1.25 * (238)1/3 fm
RN = 7.75 fm
An atom is mostly empty space.

81
 Where does the Thermal Energy (Heat)
Come From?

Nuclear Fission

82
 Mass and Energy

The energy produced in nuclear systems is
derived from Einstein’s famous formula:

E = mc 2

where c = 2.9979 ×108 m/s is the speed of light.

Mass and energy are equivalent, or
convertible from one to another.

83
 Rest-mass Energy of the Electron

Rest-mass energy is the energy of a body at rest:
E0 = m0c2

Rest-mass energy of an electron:
– Rest-mass of an electron me = 9.10954×10-31 kg
– Speed of light c = 2.9979 × 108 m/s.
– Rest-mass energy of an electron:

mec2 = (9.10954×10-31 kg)*(2.9979 × 108 m/s)2

= 81.871 ×10-15 kg-m2/s2 = 81.871 ×10-15 Joules (J)

where J denotes joule: 1J = 1 kg-m2/s2 (units of energy)

84
 Electron Volt

The electron volt is another useful practical unit.

One electron volt is the energy gained by an electron
when it passes through a potential difference of one volt
1 eV = (1.602177 ×10-19 C)(1 Volt)
1 eV = 1.602177 ×10-19 Joules (J)
AA Alkaline battery contains ~ 9,000 J of energy

Rest-mass energy of the electron
mec2 = 81.871 ×10-15 J = 51.0999 ×104 eV

mec2 = 0.511 MeV

85
 Energy Equivalent of 1 amu

1 amu = 1.66057 × 10-24 g

Using Einstein’s formula:
E = mc
2

( )
2
− 27  8 m
= 1.66057 10 kg  2.9979 10 
 s
= 931.5 MeV

Recall: 1J = 1 kg·m2/s2 and 1 eV = 1.602177 ×10-19 J

86
 Neutron-induced Fission

A neutron is absorbed by a target nucleus
A compound nucleus is formed in an excited state
The compound nucleus fissions

A1 n
n A A+1 * Z1
W n
Z X Z
X A2
Z2
Y n

Scission of the compound nucleus into three or more
fragments also occurs, though it is rare (1 in 400)

87
 Nuclear Chain Reaction

U →( U) → Rb + 3 ( 01n )
*
1
0 n + 235
92
236
92 Cs +
140
55
93
37

ΔMc2 = (Initial Mass – Final Mass)∙ c2 = 210 MeV / fission

The total energy released per fission is around 210 MeV

1 Watt = 6.24 E12 MeV/sec Self-sustaining nuclear chain reaction

To generate 1 watt of power we
need:
6.24 E12 MeV/sec
210 MeV/fission

= 2.97 E10 fissions/sec

How do we get that many
fissions every second?

88
 Fission Rate in 1400 MWe Nuclear Power Plant

210 MeV per fission on average

1 watt = 1 Joule/sec = 6.24 E12 MeV/sec
6.24 E12 MeV/sec
= 2.97 E10 fissions/sec = 1 watt
2.1 E2 MeV/fission

1400 MW x E6 watts/MW x 2.97E10 fissions/watt-sec =
4.16 E19 fissions/sec
BUT WAIT!! Something is missing…?

4.16 E19 fissions/sec X 3 = 1.25 E20 fissions/sec = 1400 MWe

89
 Energy from Fission

Particles Energy Energy Where Deposited
Emitted Recovered
(MeV) (MeV)
Fission fragments 168 168 fuel
Prompt neutrons 5 5 fuel, clad, coolant
Prompt -rays 7 7 fuel, clad, coolant, shield
Decay ’s 8 8 fuel
Decay -rays 7 7 fuel, clad, coolant, shield
Decay neutrinos 12 0 universe
Capture -rays 0 3-12 fuel, clad, coolant, shield
Total 207 198-207

 -
A1 n 
n A A+1 * W
Z1
X X n
Z Z + A2
Y n
Z2

90

 Characteristics of Fission Reactions (continued)

Fission fragments give up their
internal energy in a series of
steps

– Prompt neutrons and
gamma-rays within 10-14 to
10-12 sec

– Around 10-11 sec, fission
fragments come to rest

– Above 10-3 sec, fission
products begin chains of
beta decays; some decay
by neutron emission
(delayed neutrons)
© 1994, 2013 Encyclopaedia Britannica, Inc.

91
 Fission Products

Fission product distributions as a
function of FP mass number tend Fission Product Distribution for
to show a binomial distribution 235
U Thermal and 14 MeV Fission
1.0E+00
On average, a fissioning nuclide
1.0E-01
splits in half (i.e., two equal mass,
equal charge products) 1.0E-02

– However, symmetric fission is in 1.0E-03

Fission Yield
fact a rare event 1.0E-04

1.0E-05
Fission products tend to be
1.0E-06
neutron rich ( β- and γ-emission)
1.0E-07
0.0253 eV
Fission products: 1.0E-08 14 MeV

– Are biological hazards 1.0E-09
60 90 120 150 180
– Produce decay heat Mass Number
– Are neutron poisons Author: Dr. Charlton, NUEN, TAMU

92
 Fissile and Fissionable-But-Nonfissile Nuclides

“Fissile” nuclides
– Can undergo fission following the absorption of a
zero-energy neutron (room temperature neutron).
Examples: 233U, 235U, 239Pu, and 241Pu

“Fissionable but non-fissile” nuclides
– Can undergo fission if the incident neutron has
some threshold value of kinetic energy
Example: 232Th, 238U, 240Pu

93
 Fertile Nuclides

It is possible to manufacture certain fissile nuclides from
non-fissile nuclides

The non-fissile nuclides from which fissile isotopes can be
produced by neutron absorption are said to be “fertile”

Fissionable but non-fissile nuclides 232Th and 238U can be
used to produce fissile nuclides: 233U and 239Pu

− −
Th (n,  ) Th ⎯⎯→ Pa ⎯⎯→
232 233 233 233
U

− −
U(n,  ) U ⎯⎯→ Np ⎯⎯→
238 239 239 239
Pu

94
List of Required Texts

1. U.S. NRC "Nuclear Reactor Concepts" Workshop Manual,
http://www.nrc.gov/reading-rm/basic-ref/teachers/unit3.html
– Nuclear Power for Energy Generation
http://www.nrc.gov/reading-rm/basic-ref/teachers/01.pdf
– The Fission Process and Heat Production
http://www.nrc.gov/reading-rm/basic-ref/teachers/02.pdf
– Pressurized Water Reactor Systems
http://www.nrc.gov/reading-rm/basic-ref/teachers/04.pdf
2. DOE Fundamentals Handbook “Nuclear Physics and Reactor
Theory”,
http://www.hss.doe.gov/nuclearsafety/ns/techstds/standard
/hdbk1019/h1019v2.pdf

95
 References

Lamarsh, J. R., and Baratta, A. J., “Introduction to
Nuclear Engineering”, third edition, Prentice Hall,
2001
Turner, J. E., “Atoms, radiation, and radiation
protection”, third edition, Wiley-VCH, 2007
DOE Fundamentals Handbook “Nuclear Physics and
Reactor Theory”,
http://www.hss.doe.gov/nuclearsafety/ns/techstds/
standard/hdbk1019/h1019v1.pdf

96
References

U.S. NRC "Nuclear Reactor Concepts" Workshop Manual,
http://www.nrc.gov/reading-rm/basic-ref/teachers/unit3.html
– Nuclear Power for Energy Generation
http://www.nrc.gov/reading-rm/basic-ref/teachers/01.pdf
– The Fission Process and Heat Production
http://www.nrc.gov/reading-rm/basic-ref/teachers/02.pdf
– Pressurized Water Reactor Systems
http://www.nrc.gov/reading-rm/basic-ref/teachers/04.pdf
DOE Fundamentals Handbook “Nuclear Physics and Reactor
Theory”,
http://www.hss.doe.gov/nuclearsafety/ns/techstds/standard/
hdbk1019/h1019v2.pdf
Lamarsh, J. R., and Baratta, A. J., “Introduction to Nuclear
Engineering”, third edition, Prentice Hall, 2001
Stacey, W. M., “Nuclear Reactor Physics”, second edition,
Wiley-VCH, 2007

97