Space Nuclear Power

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Space Nuclear Power

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Title: Space Nuclear Power

1
Space Nuclear Power

Benjamin Amiri
Brian Ade
David Dixon
Space Nuclear Power Group
Los Alamos National Lab

2
Purpose of This Course

To overview the basic physics underlying fission
reactors
To convey an understanding of the design
approaches and considerations for fission reactor
systems
To convey an understanding of design and
integration issues related to space fission
systems
To convey an understanding of special issues
related to space fission systems (e.g., Special
Nuclear Materials safeguarding and transport)?

3
Questions Faced by Teachers for Studentswho are
tomorrows adults

What are the properties of nuclear materials?
What is radiation?
How to produce, use and dispose of nuclear
materials?
What is a nuclear reactor?
What is the difference between an open and
closed fuel cycle?
What is transmutation?
What is a nuclear weapon?
What is environmental management
What are nuclear programs of tomorrow?
What are nuclear technical challenges of
tomorrow?

4
Some Historical Perspective

Start with Oklo, Gabon, rich uranium deposits and
groundwater seeped
2 billion years later
1905 Einstein develops Nobel Prize winning
explanation of the Photoelectric Effect-
Einsteins Theory of Special Relativity - energy
and mass are equivalent.
1924 Prince Louie de Broglie- particles can
behave as waves
1925 1926 Schrodinger and Heisenberg formulate
quantum mechanics
In 1930, W. Bothe and H. Becker highly
penetrating radiation was emitted when beryllium,
boron or lithium were bombarded by alpha
particles from Po
In 1932, Irene Currie and her husband protons
were produced when striking hydrogen containing
substances with this newly discovered penetrating
radiation
James Chadwick particle is neutral and weighs
the same as proton, named this new particle
neutron
In 1934, Enrico Fermi irradiated uranium with
neutrons trying to produce the first transuranic
elements however, he accidentally achieved the
world's first nuclear fission. In 1938, he
receives the Nobel Prize in Physics
In 1939, Hans and Strassmann Reactants from
fission included elements in the medium mass
region. The presence of these medium mass region
nuclides suggested that the nucleus had split.
The fact that the sum of these medium mass
nuclides did not add to the sum of the initial
parent suggested that some of the mass was
converted into energy.
L. Meitner and O. Frisch termed this process
fission and also calculated the energy released
during fission of a U-235 nuclide to be 200 MeV
Albert Einstein then wrote his famous letter to
President Franklin Roosevelt
Enrico Fermi and Leo Szilard proposed placing
uranium in a matrix of graphite. On December 2nd
1942, the first controlled self-sustaining chain
reaction was achieved in a squash court under the
University of Chicagos Stagg Field
Little Boy, August 6 1945, Hiroshima killing over
100,000 people, Fat Man, August 9 1945, Nagasaki
killing 75,000

5
Reactor History

In 1946, Enrico Fermi published a scheme for
outlining the future uses of nuclear energy
September 5, 1953 First peacetime research
reactor critical in Raleigh, NC.
December 8, 1953 US President Dwight D.
Eisenhower, Atoms for Peace speech to the United
Nations
December 2, 1957 Duquesne Light Company --
Shippingport Atomic Power Station (PWR).
August 3, 1957 Argonne National Laboratory and
General Electric -- GE Valacitos
First commercial BWR to be licensed by the US AEC
The progress of these commercial power systems
later lead to the development of other competing
reactor systems
CANDU, GCFR, LMFBR, PBMR, MSR

6
Fission is a Well-Developed,Extensively Utilized
Technology

Fission power systems have been operating safely
and reliably since 1942
Fission reactors are used by governments,
industry, utilities, and universities
Existing nuclear fission power plants are the
least expensive source of electricity in the US
public acceptance may be increasing
Several countries have plans for development
and/or utilization of advanced reactors.

7
What is the structure of an atom

Neutron 1u, charge is neutral /-
Proton 1u, charge is positive
Electron 0.0005u, charge is negative -
Atomic number, Z of protons in atom
Atomic mass neutrons Z
Nucleus contains neutrons and protons
Electrons are in orbit around nucleus
Isotopes of the same element have the same Z
number, but different nuclear mass

8
Common Sources of Radiation

Common Sources of Radiation Include
Solar radiation
H-3 , Be-7, C-14
Concrete/Building Materials (lt10 mrem)?
Uranium is found in ppb in concrete and decays to
radon gas which emits alphas/gammas
Yourself
K-40
Sleeping next to someone for 8 hours 2 mrem
Medical Devices
Xrays, Flouroscopy, PET, Nuclear Medicines
Smoking (up to 16,000 mrem)?
Po-210, radon
The average cumulative dose for a human on earth
is 360 mrem/year

9
Natural Sources of Radioactivity

Natural Sources in the U.S. (mSv/yr)
Radon 2.0
Internal to Body 0.39
Terrestrial 0.28
Cosmic 0.27
C-14 , H-3 0.01
TOTAL 3.0
Person-made Sources
Diagnostic Xrays 0.39
Nuclear Medicine 0.14
Consumer products 0.10
TOTAL 0.6

10
What are the properties of nuclear materials?

Four types of Radioactive Decay
Alpha emission
Beta particle, electrons expelled by excited
nucleus
Gamma radiation
Neutron
Nuclear Reactions
Fission
Capture
Scatter
Half life

11
Radioactive Decay

Beta Decay (e-)?

Alpha Decay

(2.45 Mev)?

Gamma Decay

Neutron Decay

12
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13
Radioactive Decay Equations

dN/dT -N ? where N of Radioactive
nuclei, t is time,
and ? is the
decay constant- time
N ? is the activity of a sample in
distintegrations/time
Activity is measured in Curies (1 Ci 3.7 E10
d/s)
or Becquerels (bq) 2.707 E -11 Ci or 1 d/s
NN

e
N Number radioactive nuclides surviving

For N

N / 2
T
0.693/ ?
14
Photon Interactions with Matter

Photons (?s and x-rays) interact with matter in
three ways
- Photoelectric effect ? Z4 / E3
- Compton Scattering elastic scattering of
photon w/ free electron scattered photon
has less energy than incident photon as E(?)
increases, energy loss to incident photon
increases
- Pair Production at E(?) gt 1.02 MEV (1 MeV
1.602 -13 Joules), the photon, in the
presence of a nucleus, can spontaneously convert
to an electron (e-) and positron (e) pair
Pair production dominates over 5 Mev Compton
Scattering dominates in the 0.5 to 5 Mev range

15
Photoelectric Effect
16
Compton Scattering
17
Pair Production
18
Total Gamma Ray Absorption
19
Gamma Ray Absorption is Energy and Z Dependent
Values of the mass attenuation coefficient, ?/?
and the mass energy-absorption coefficient, ?en/?
as a function of photon energy.
20
Gamma Ray Absorption is Energy and Z Dependent
Values of the mass attenuation coefficient, ?/?
and the mass energy-absorption coefficient ,
?en/? as a function of photon energy.
21
Gamma Ray Absorption is Energy and Z Dependent
Values of the mass attenuation coefficient, ?/?
and the mass energy-absorption coefficient ,
?en/? as a function of photon energy.
22
Mass Attenuation Coefficient (?/? cm2/g) of Al,
Fe, W, and U at 1.0, 3.0, and 8.0 MeV
Shield design must also take into account
buildup, inelastic neutron scatter, gammas from
neutron capture, geometry, thermal management,
radiation damage, and other factors.
23
Comparison of Fission and Radioisotope Power
Radioisotope Decay
Fission
Heat Energy 0.024 MRV/nucleon (0.558 W/g
PU-238 Natural decay rate (87.7-year half-life)?
Heat Energy 0.851 MRV/nucleon Controllable
reaction rate (variable power levels)?

Long history of use on Apollo and space science
missions 44 RTGs and numerous RHUs launched by
U.S. during past 40 years
Heat produced from natural alpha (? ) particle
decay of Plutonium (Pu-238)?
Small portion of heat energy (5 - 20) converted
to electricity via passive or dynamic processes.

Many U.S. technology programs over last 50 years
only one unit (SNAP-10A) was flown in 1965.
Former U.S.S.R. flew over 30.
Heat produced from neutron-induced splitting
(fission) of Uranium (U-235). At steady-state, 1
or the 2 to 3 neutrons from reaction cases a
subsequent fission in a chain reaction process.
Heat converted to electricity, or used directly
to heat a propellant.

24
What does fission produce?
Fission fragment 1

Energy
Radiation
Neutrons

neutron
energy
235U
neutron
Fission fragment 2
neutron
235U
radiation
neutron
radiation
neutron
Fission fragment 1
energy
Fission fragment 2

Chain reaction

25
Nuclear Fission Process
Fission
Maximum Stability
Fusion
180 MeV prompt useful energy (plus 10 MeV
neutrinos) - additional energy released in form
of fission product beta particles, gamma rays,
neutron capture gammas (200 MeV total useful)?

Neutron absorbed by heavy nucleus, which splits
to form products with higher binding energy per
nucleon. Difference between initial and final
masses prompt energy released (190 MeV).
Fissile isotopes (U-233, U-235 and Pu-239)
fission at any neutron energy
Other actinides (U-238) fission at only high
neutron energies
Fission fragment kinetic energy (168 MeV),
instantaneous gamma energy (7 MeV), fission
neutron kinetic energy (5 MeV), Beta particles
from fission products (7 MeV), Gamma rays from
fission products (6 MeV), Gamma rays from neutron
capture (7 MeV).
For steady power production, 1 of the 2 to 3
neutrons from each reaction must cause a
subsequent fission in a chain reaction process.

26
Nuclear Fission Process
27
Fission Products

Fission events yield bimodal distribution of
product elements.
These products are generally neutron-rich
isotopes and emit beta and gamma particles in
radioactive decay chains.
Most products rapidly decay to stable forms a
few, however, decay at slow rates or decay to
daughter products which have long decay times.
Example fission products of concern
Strontium-90 (28.8-year half-life)?
Cesium-137 (30.1-year half-life)?
Isotope amounts decrease by factor of 1,000 after
10 half-lives and 1,000,000 after 20 half-lives.
Decay power 6.2 at t0 (plus fission from
delayed neutrons), 1.3 at 1 hour, 0.1 at 2
months (following 5 years operation).

28
Prompt vs Delayed Neutrons

gt99 of total fission neutrons are prompt
neutrons.
Prompt neutrons released within 1.0 x 10-14 s
of the instant of fission.
Most prompt neutrons have energies between 1
and 2 MeV, some gt 10 MeV

Prompt Fission Neutron Energy Spectrum for
Thermal Fission of Uranium-235
29
Prompt vs Delayed Neutrons

Fraction of delayed neutrons varies with
isotope and (slightly) with neutron spectrum.
Average delayed neutron energy significantly
less than average prompt neutron energy.
Delayed neutron importance factor gt1 for
compact HEU systems.

30
Reactor Kinetics
Reactivity ? (k-1)/k, where k is the
effective multiplication factor Reactivity in
? / ? Prompt neutron lifetime l 1 / (v
?a (1 L2Bg2))? Where l prompt neutron
lifetime v average neutron speed ?a
macroscopic absorption cross section 1 L2Bg2
nonleakage probability Prompt neutron lifetime
is on order of 10-6 s for compact, fast-spectrum
system and 10-4 for thermal reactor
31
Reactor Kinetics
If there were no delayed neutrons, reactor would
be difficult to control Reactor period Tp l/
? Example ? 0.0001, l 1 microsecond gt
Tp 0.01 s Delayed neutrons stabilize
operation leff ? l (?-?)/? where ?
properly weighted average decay constant for six
actual delayed neutron groups ? 0.08 s-1 Actual
stable reactor period would be Tpeff (?-?)/? ?
800 seconds in previous example
32
Delayed Neutrons
Example of Delayed Neutron Precursor
Other important neutronic parameters Nu ?
average number of neutrons liberated per
fission Eta ? neutrons liberated per neutron
absorbed
33
Reactor Basics
Secondary Shield
Primary Coolant Loop
Primary Shield
Secondary Coolant Loop
Fission energy transfers to primary coolant
Energy to turbine or engine for power production
Heat Exchanger
Energy transfers to secondary coolant
34
Nuclear Reactor Basics
Radial neutron flux distribution in spherical core
35
Reactor Design

The goal is to determine the amount of fissile
and control material needed in order to
Maintain the self-sustaining chain reaction
Operate the system at a prescribed power
Operate for a prescribed amount of time
Achieving some type of operating goal
Accounting for reactivity deficits
Secondary design considerations may include
waste, useful fissile material and medical
isotope production
Varied Material and geometry combinations in
order to design a system that meets the operating
goals at the minimum cost
Mechanism Equations/Process
Coefficients Nuclear Data

Refueling at Davis-Besse Nuclear Power Station
36
Deterministic Method
37
The Monte Carlo Method

The Monte Carlo method uses probability theory to
model a system stochastically
Random sampling of events

Probability that a neutron moves a distance dx
without any interaction
Probability that a neutron has its first
interaction in dx p(x)dx

Probability density function (PDF)? A real-valued
function whose integral over any set gives the
probability that a random variable has values in
the set

Cumulative Distribution Function (CDF) ?The
probability that the variable takes a value less
than or equal to x

38
Reaction Sampling

If particle interacts in a cell volume the
isotope with which the particle interacted must
be determined

Then the reaction type must be determined

39
Neutron Cross Sections
Measure of the probability of a particular
neutron-nucleus interaction. Property of the
nucleus and the energy of the incident
neutron. Symbolized ?, common unit is barn
1.0 x 10-28 m2 Neutron Flux nv ? n
neutrons / m3 v neutron speed (m/s)? Reaction
rate ? N ? N nuclei / m3 ? neutron flux
(neutrons / m2-s)? ? cross section (m2)?
40
Comparison of Hydrogen and Deuterium Cross
Sections
41
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42
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43
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44
Simplified Depletion Equation
45
Boiling Water Reactor
46
Pressurized Water Reactor
47
CANDU
48
LMFBR
49
Generation IV Reactor Core Modeling

As advanced reactor concepts challenge the
accuracy of current modeling technologies, a
higher fidelity more robust depletion tool is
necessary in order to properly model
time-dependant core characteristics

50
Fission Power Systems
Fissioning 12 fl oz (341 ml) of Uranium yields 50
times the energy contained in a Space Shuttle
External Tank Energy Density 82 billion joules
per gram
50 x

Fission overcomes limitations of other candidate
power sources
Chemical already near theoretical performance
limits
Radioisotopes versatile and long-lived, but low
power density and limited Pu-238 supply
Natural sources (e.g., solar, EM tethers) highly
dependent on location w/respect to sun or planet
Advanced concepts (e.g., beamed energy, fusion)
too immature, may not work, and/or require
substantial in-space infrastructure and
investment
Greatly extends capability, sophistication and
reach of future science missions
Enables use of high-performance electric
propulsion beyond inner solar system
Provides long-duration, power-rich environments
for sophisticated scientific investigations,
high-data rate communications and complex
spacecraft operations
Improves safety, capability and performance of
future human planetary missions
Power-rich spacecraft and surface operations
Rapid transportation to reduce extended exposure
to solar/cosmic radiation and zero-g

51
Radioisotope Power Systems

NASA uses two types of Radioisotope Power Systems
(RPS), both of which use heat from decay of
plutonium-238.

Radioisotope Thermal Generator (RTG)?
Heat transferred to thermal-to-electric power
conversion system
Flown on many NASA missions Pioneer, Voyager,
Viking, Apollo, Galileo, Ulysses, Mars
Pathfinder, Cassini
Radioisotope Heater Unit (RHU)?
Heat keeps spacecrafts instruments warm and
within designed operating temperatures
Latest deployment onboard NASAs Mars Exploration
Rovers Spirit and Opportunity
NASA Project Prometheus is supporting
Pluto/New Horizons mission
Stirling Radioisotope Generator (SRG) Mission
Multi-Mission Radioisotope Thermal Generator
(MMRTG)?

Pu-238 Fuel Pellet
RHU
52
Why Fission?

Fission is the only near-term technology that can
provide reliable high power at low mass for a
large variety of missions.
Conventional chemical systems.
Very near their theoretical performance limit,
low energy density.
Solar power.
Degrades rapidly as distance from the sun
increases.
Dependent on orientation, radiation field,
eclipses, debris, etc.
Radioisotope power.
Energy density is many orders of magnitude below
fission.
Future sources of Pu-238 or other radioisotopes
unknown.
Advanced concepts.
Fusion, anti-matter, pulsed-nuclear, tethers,
solar sails, etc.
These are many decades from being used for
practical exploration.
All of the above power sources have a valuable
place in space exploration, but only fission can
truly enable ambitious exploration in the
near-term.
Recent technology advances in power conversion
systems, radiators, spacecraft design,
electronics, etc., put less burden on the
reactor.
Reactor does not have to be a Ferrari right out
of the gate.

53
Potential Benefits of Space Fission Systems

Space Fission Power can enable or contribute to
many national and global missions, including the
Presidents new exploration vision.
Ambitious space science and exploration.
Mars/lunar surface power/propulsion (robotic and
manned).
Outer-planet missions Jovian Moons, Pluto
orbiter, etc.
Interstellar precursor or solar missions.
Enhanced national and planetary defense.
High power and enhanced mobility for defense
applications.
Potential use for comet/asteroid defense.
Synergy with advanced terrestrial and airborne
defense systems.
Significant commercial value in space.
Satellite power, mobility, maintenance,
retrieval.
Space tourism (orbital, lunar, ?).

Revitalizing the nations nuclear power
infrastructure and capabilities
Space fission programs inspire students and young
professionals to pursue nuclear engineering (gt100
applicants for LANL student-internships this
year)?
Many technologies developed could be used for
advanced terrestrial power reactors
Furthermore, for new and enabling technologies
the majority of applications are not thought of
until the technology is proven and in hand.

54
Summary of Radioisotope/Fission System Differences
55
What makes a space reactor unique?

Fission reactors represent a well established
terrestrial technology.
Commercial power plants
Research/production reactors
Naval applications
There are several major requirements that
distinguish a space reactor from a terrestrial
reactor (to different levels depending on the
application (i.e. commercial or naval)
Specific mass (alpha mass/power)?
Reliability and lifetime
System Integration
Operations/Environment
Safety
Safeguards
Subclasses of space reactors also exist, but most
of these distinguishing factors apply to all of
them.
I.e. space power, surface power, process heat,
thermal propulsion, etc.

56
Differences Between Terrestrial and Space Reactors

Specific mass (alpha mass/power)?
Reliability
System Integration
Operations/Environment
Safety
Safeguards
Testing
It is not practical to test the flight-unit with
nuclear power. Nuclear test-units cannot be
tested in prototypic environment and have vastly
different safety requirements. On the plus side,
small space systems can be designed to allow
prototypic nuclear criticality testing and
non-nuclear-powered thermal-structural system
testing.

57
Nuclear Subsystem Functions

Reactor core
Typically consists of an array of fuel pins
Produces heat by fissioning of 235U
Primary heat transport
Tranfers heat from reactor core to power
conversion subsystem
Gas or liquid metal (loop or Heatpipe)?
Usually includes an intermediate heat exchanger
Radiation shield
Limits gamma and neutron doses to other
subsystems and payload
Instrumentation and control
Controls fission rate in reactor core
Controls startup, shutdown, and other transients
Maintains subcriticality under accident
conditions
Structure
Supports NSS components during all mission phases
Provides mounting interface to power conversion
subsystem and NEP vehicle

Brayton subsystem
Control drives
Heat transport ducting
Nuclear subsystem
Radiation shield
Neutron relflectors
Reactor core
(Gas-cooled direct Brayton example shown)?
58
Principle Nuclear Reactor Elements Core

Designed to maintain stable chain reaction
process while delivering power at desired
temperature distribution.
Options for core cooling include heat pipes,
pumped gas, and pumped liquid metal. Each has
advantages and disadvantages depending on overall
system design and application.
Core designed for safe, stable operation.
Materials and geometry chosen so that power
increase results in reactivity decrease.
Minimum required fissile material mass typically
less for moderated reactors than for
fast-spectrum reactors. Total system mass may be
similar because of other factors.
Hydrogenous moderators limited to peak operating
temperature of 1000 K, potentially limiting power
conversion efficiency.

59
Principle Nuclear Reactor Elements Fuel
Nb-1Zr Cladding Cap

Numerous fuel options available. Choices
include
Geometry (e.g. pin, particle, prismatic, foil)?
Isotope (e.g. U-233, U-235, Pu-239, Am242m)?
Compound (e.g. U-metal, UZrH, UO2, UN, UC, UC2,
UCZrN, (U,Zr,Nb)C, UF4)?
Factors to consider include the following
Required fuel operating temperature
Fuel burnup (fraction of uranium fissioned)?
Fuel operating environment
Fabricability / technical risk
Desired/required uranium density
Core power density
Two leading fuel options are UO2 and UN
UO2 flown in space (TOPAZ), used by commercial
power industry and Navy, available commercially
and from National Laboratories
UN (current baseline) developed during SP-100 and
previous programs. High uranium loading, high
thermal conductivity, low swelling/fission gas
release

BeO Reflector Pellet
UN Fuel Assembly
BeO Reflector Pellet
Heatpipe Module
Nb-1Zr Cladding Cap
60
Principle Nuclear Reactor Elements
Moderator/Reflector/Control/Shield
Clad Be Control Drum

Moderator
Hydrogen best moderator material for space
systems. UZrH or UZrH good to 1000 K.
Reflector
Beryllium (Be) and Beryllium Oxide (BeO) best for
space systems
Be flown in space, easier to fabricate
Control
Control by varying neutron capture in reflector
region (rotating control drums) or by varying
rate of neutron escape (sliding or pivoting
reflector)?
Rotating control drums flown in space. Sliding
reflectors potential advantage for certain
designs
Shield
High-Z material for gamma attenuation (e.g. W)?
Hydrogenous material for slowing down neutrons
Reduce capture-gamma generation (Li-6 or B-10 for
absorbing neutrons)?
Reduce gammas produced by inelastic scatter
(layered shield)?

Clad B4C Reaction Control Panel
Clad Be Reflector Panel
61
Reactor Control and Safety

Design for inherent stability
Negative temperature and power reactivity
feedback coefficients
Neutron escape dominates in small, fast-spectrum
system
Provide redundant and diverse shutdown mechanisms
Reflector control (e.g. drums, sliders)?
Reflector ejection
In-core control rods
Minimize mission-ending single point failures in
control system
System remains operational following single or
multiple control system failures
Prevent inadvertent system start
Preclude inadvertent system start during all
credible launch accidents.
System essentially non-radioactive at launch

62
Summary

Fission systems are in productive use today
around the globe for military and commercial
purposes.
Fission, cross-section, radioactive decay, etc
have been presented in a most elementary manner
(w/o calculus or quantum mechanics). The fun for
we nuc pukes is to take these concepts and make
practical devices from them.

63
Summary / Observations

The physics of fission is very attractive.
Fission process is easy to sustain, fission has
effectively infinite energy density.
The challenge of space fission power and
propulsion is engineering systems that meet
mission requirements and can be built, flight
qualified, and launched in a timely and
affordable fashion.
Space fission systems are essentially
non-radioactive at launch, and have other
desirable attributes.
Development of advanced fission systems depends
on a successful series of evolving flight
missions.

64
Trades Fast vs Thermal Neutron Spectrum

Mass
Moderated spectrum can allow lower mass reactor
(higher fission cross section)?
Neutron shield mass also slightly smaller for
moderated system because of lower flux and less
leakage
Gamma shielding about the same because of less
high-Z material in core
Overall system mass depends on the core
temperature and thermal performance
Thermal performance
If mass benefit is realized for moderated system,
then it will have higher power densities, which
will nullify the mass advantage if the system is
heat transfer limited
In a small reactor, only hydrogen can be an
effective moderator. No established technology
for hydrogenous material above 1100 K
UZrH 900 K to 1000 K, Yttrium hydride 1100 K
Cooling of moderator adds a level of system
complexity - reliability, cost, schedule
Nuclear performance
Moderated system has longer neutron lifetime, not
a significant factor
Moderated system has larger reactivity feedback
coefficients
Can help reactor stability in steady state
Good at preventing overheating in extreme
scenarios a big advantage for terrestrial
systems.
Is a disadvantage in startup and shutdown,
especially because more excess reactivity is
required in the system to allow startup.
Moderated system more complex because of more
feedback mechanisms
Compact-fast system is easier to model and
simulate - point kinetics is generally valid.

65
Trades Fast vs Thermal Neutron Spectrum

Lifetime
If system lifetime is limited by fast fluence,
then thermal system has an advantage
Fluence does not appear to be a life-limiting
factor for potential JIMO concepts
If system lifetime is limited by fuel burnup,
then fast system has an advantage
Burnup limits will play a role in JIMO reactor
designs above 500 kWt.
A conservative fuel burnup limit (2) limits the
power of a low mass reactor to 12 years at 500
kWt
A more risky fuel burnup limit.(6) limits the
power of a low mass reactor to 12 years at 2
MWt
Moderator lifetime could be a big issue for
moderated system
Complexity
Moderated system is more complex on about every
level - design, development, fab, analysis,
testing.
Safety
Fast spectrum system can take full advantage of
spectral shift to remain subcritical in water,
because poisons hardly affect nominal operation
If a thermal system could be designed to be fully
or over moderated, it would have an advantage,
but this is probably impossible for this size
reactor.

66
Trades Fast vs Thermal Neutron Spectrum

Safeguards
A practical moderated system of this size will
probably have about 1/2 the fuel loading of the
fast system
An advantage, but would have the same safeguards
issues
Moderated system might be able to use lower
enriched fuel (corresponding mass penalty)?
Cost
The only significant cost advantage of the
moderated system is that there is less fuel, most
of the other factors mentioned favor the fast
system as being lower cost.

67
ISSUES Specific Mass

Mass is not a significant concern for most
terrestrial applications
A space reactor must be light-enough to be
launched as part of a spacecraft.
A surface reactor must be light enough to be
landed on surface.
An NEP reactor must have high enough alpha
(power/mass) to provide ample spacecraft
acceleration.
There is a tight relationship between alpha and
technical risk.

68
ISSUES Reliability and Lifetime

Terrestrial systems can utilize planned and
unplanned maintenance, and very large suite of
diagnostic tools
Space reactor must start-up and operate for its
entire lifetime without any hands-on assistance
or maintenance.
Remote maintenance and control will be
significantly limited by the limited diagnostics
that the system can accommodate, and by the
communication time delay.
Long-life at high-temperature with no maintenance
is unique (and extremely difficult).

69
ISSUES Spacecraft Integration

Advantages as compared to terrestrial
applications
No need for containment, emergency cooling, and
many other systems required for terrestrial
systems
Challenges
Versatility
Space reactor development begins at the same time
as other spacecraft components, must be flexible
to meet possible changes in interface
requirements as other systems are developed.
It is desirable to have a space reactor design
that can accommodate various mission performance
and environmental requirements.
Packaging
System must fit with integrated spacecraft
design, and accommodate launch shroud
superstructure and center-of-mass issues
Shielding
Terrestrial systems can utilize very heavy and
bulky shielding and large separation in many
cases, space reactors must shield nearby
components to allowable dose rates with as low as
mass as possible.

70
ISSUES Operations/Environment

Benefits as compared to terrestrial reactors
Lack of atmosphere allows use of refractory
metals
Although ground testing at temperature still
requires a vacuum
Challenges as compared to terrestrial reactors
Less efficient heat-sink
Must radiate in-space, as opposed to using large
volumes of water or cooling towers
No real-time reactor operators
Reactor must be designed for simple control, and
control must be primarily autonomous
Launch Loads
These are in some ways similar to seismic
evaluations for terrestrial reactors
Very cold environment
This can significantly complicate
startup/shutdown
Other
Lack of gravity
Affects different concepts in different ways,
some positive and some negative.

71
ISSUES Safety

Benefits as compared to terrestrial reactors
Negligible radioactivity
Reactor does not operate until after deployment -
dose next to reactor is less than background.
No significant safety impact of operational
accidents
Significantly simplifies design, operational
safety is one of the key cost and risk factors
for terrestrial reactor operation.
If a ground test is performed, then the system
will have to be designed and/or modified to meet
ground safety requirements.
Challenges as compared to terrestrial reactors
Unique potential scenarios that could cause
inadvertent criticality

72
ISSUES Safeguards

Challenges
Fuel is non-radioactive and highly enriched, need
to adequately protect during storage, transport,
and potential reentry after launch.
Procedures exist for performing almost all of
this function, but safeguards must be factored
into the logistics of the program from the start.

73
Small-Steps Toward More Advanced Systems

Recent technology advances in power conversion
systems, radiators, spacecraft design,
electronics, etc., can potentially put less
burden on the reactor.
Reactor does not have to be a Ferrari out of the
gate (if reactor requirements can be kept
simple)?
The most evolvable early system is the one that
successfully flies!
Program continuity, experienced personnel, and
infrastructure will enable development of
progressively more advanced systems.

Nuclear fuels qualification In-core / near-core
materials Neutron reflector and control system
Reactor primary heat transport Radiation
shielding HPEP Vehicle Thermal management Power
conversion System integration, including
radiator System stowage and deployment Reactor
/ spacecraft separation booms Avionics Attitude
Control Automated Reactor / System Control
Thrusters Flight qualification Launch
approval Public opinion Program structure
Early robotic missions use established technology
Infrastructure, personnel, and experience from
early missions enable development of human-rated
systems
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Obstacles to Keeping the First Step Small

Mission studies will almost always suggest the
use of a relatively high power reactor
This reason is in the hands of mission designers,
and there is no reason to expect this factor to
disappear (they are just doing their job).
It is usually felt that if a fission system is to
be used, it must be far superior to any other
power option for a specific mission (because of
the perceived technical, programmatic, and safety
risk). This drives a need for a higher-power,
lower-mass system.
This reason is in the hands of the top-level of
the agency and policy makers
There are usually plenty of paper (i.e.
conceptual) reactors that can meet the
higher-power, lower-mass requirements that are
desired, plus at least one engineer to support
the claim that this paper reactor can easily
become a real reactor.
This reason is in the hands of the space-reactor
engineers, and unless the reigns are pulled in
by the engineers, there is no reason not to
specify a high-performance reactor.

75
Space Reactor Safety and Launch Approval

24 safe launches of RTGs since 1961. One
reactor, SNAP-10A in April 1965.
Since 1977 the approval for launch of nuclear
material in the U.S. has been codified in
Presidential Directive/ National Security Council
Memorandum 25 (PD/NSC-25).
Highlights of PD/NSC-25 are
Presidential approval is required for the launch
of a spacecraft with nuclear materials aboard. In
certain cases, the head of the Office of Science
and Technology Policy (OSTP) may grant approval.
The agency head flying the mission must request
launch approval through OSTP.
For every mission an ad hoc review group is
convened to assess the risks verses benefits of
the mission - called the Interagency Safety
Review Panel (INSRP).
The INSRP consists of a representative from NASA,
DOD, and DOE with supporting technical panels
(e.g., meteorology, launch abort, etc). EPA and
the NRC have advisory roles.
United Nations agreements currently in place
1967 UN treaty on Outer Space
Reactors can be used for peaceful purposes
launching nation is internationally liable
launching nation remains owner of the satellite
Committee on Peaceful Uses of Outer Space
(COPUOS) oversees space reactor activities
UN Resolution 47/68
Launching nation must perform a safety
assessment.
Principle 3 provides some guidelines and criteria
for safe use.

76
Safety Engineering for Space Reactors

Space reactor safety engineering is simplified by
2 conditions
The reactor does not present a significant
nuclear safety risk prior to fission-powered
operation.
The reactor will not be powered-up until in a
stable orbit is established with gt300 year decay
time.
Based on these 2 conditions, inadvertent
criticality prevention is the only nuclear safety
issue for a flight reactor.
This greatly simplifies system design because
engineers can focus only those features and
events that impact reliability, and if
functionality is lost, there is no need to
evaluate or mitigate further damage or release.
These 2 conditions also simplify safety testing
requirements
Zero-power criticals are required to verify
nuclear safety
Non-nuclear testing is needed to testing the
control system, mechanical safety locks, etc.
Nuclear testing is not significant to safety -
only to reliability
Program decision - does the increase in
reliability justify the cost and increased safety
risk
Space reactors can be presented with unique
scenarios that could cause criticality, primarily
launch and transport accidents,
Note it has not been shown that an accidental
criticality event (burst or sustained) could
significantly increase integrated mission risk to
the public.
Current systems are designed to prevent
inadvertent criticality as a conservative measure.

77
Space Reactor Programs Historical Observations

SNAP reactors (1960s to early 1970s)?
UZrH fueled, liquid metal (NaK) cooled
w/thermoelectrics or Rankine
500 We to 60 kWe (1 year life)?
Several ground tests
One (SNAP-10A) flown in Earth orbit
Russian reactors
U-Mo Alloy or UO2 fueled, liquid metal (NaK)
cooled with thermoelectrics (gt30) or thermionics
(2)?
Low power (2-5 kWe), short life ( 1 year)?
Over 30 reactors flown in Earth orbit
Numerous other programs failed to lead to flight.
In most cases this was because the reactor
requirements and technology were too ambitious
(too large of a first-step)?

0.5 kWe SNAP-10A thermoelectric
5 kWe TOPAZ thermionic
At least 14 major US programs in addition to SNAP
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Fission Reactor Operation

System power controlled by neutron balance.
Average 2.5 neutrons produced per fission
(including delayed).
Constant power if 1.0 of those neutrons goes on
to cause another fission.
Decreasing power if lt 1.0 neutron causes another
fission, increasing if gt 1.0.
System controlled by passively and actively
controlling fraction of neutrons that escape or
are captured.
Burn 1 kg uranium per 1,000,000 kW-day

lt 1 ft
81
Space Reactor Engineering Historical
Observations

Significant technology has been developed over
the past five decades by programs aimed at
fielding advanced space fission systems. With
the exception of SNAP-10A (not listed), none of
these programs resulted in flight.
History shows we will need to be better
(technically and programmatically) if we are to
succeed with space fission system development and
utilization.
Technology with no flight heritage has little or
no impact on space programs.

82
Space Reactor Engineering Advanced
SystemsEarly Flight Enables Development and
Utilization of more Advanced Systems

Program continuity, experienced personnel, and
infrastructure will enable development of
progressively more advanced systems.
The most evolvable early system is the one
that successfully flies!

Radioisotope Power Systems
Power via decay of radioactive atoms
Well established space technology base

Fission Power Systems
Power via splitting of atoms, very high energy
density
Well established terrestrial technology base -
limited space experience

Non-nuclear breadboard test of a nuclear-electric
propulsion system heat-pipe cooled reactor
coupled with Stirling engine powering an ion
thruster (in separate chamber).
84
Approach Emphasizes Fabrication and Testing

Design to allow rapid hardware and test
iterations.
Design components and systems integrated into a
test plan that maximizes the probability of
program success.

For JIMO, cost and schedule dictates that
non-nuclear testing will be the work horse of
the test program.
Photos shown are non-nuclear testing of heat pipe
cooled reactor

85
Non-Nuclear System Testing
86
JIMO Reactor Top-Level System Requirements

All systems designed to provide power to a 100
kWe power conversion system
All systems designed to 12 year full-power
lifetime
Brayton systems designed to (parameters vary
slightly for each design)
Power 500 kWt
Tin 890 K
Tout 1150 K
Gas 72He/28Xe
Pressure 1.38 MPa
Pressure drop allocation 2.5 dp/P
Thermoelectric system designed to
Power 2.36 MWt
Tin 1265 K
Tout 1350 K
Neutron 5x1010 n/cm2 damage fluence at 25-m from
the reactor core
Gamma 25 kRad(Si) at 25-m from the reactor core

87
Space Reactors for JIMO

The reactor power system for the Jupiter Icy
Moons Orbiter (JIMO) mission is expected to
provide 100 kWe for more than a decade.
The current LANL space-reactor team has been
investigating this class of reactor continuously
for over 10 years.
There are many potential reactor power system
options for JIMO.
Most of these options are rather similar, the
major differences lie in primary reactor heat
transport and the electrical power conversion
system.

88
Three (of many) Potential Reactors are
Fast-Spectrum, U-235 Fueled, Be-Reflected,
Ex-Core Controlled
Gas-cooled concept
Heat pipe concept

400 kWt reactor
UN/Nb-1Zr
Na coolant (Heat Pipe)?

400 kWt reactor
UN/Nb-1Zr
He/Xe coolant

Principle difference is method of primary heat
transport and related design implications
89
JIMO Reactor Concepts
LANL has developed and evaluated several
potential reactor concepts for JIMO. The latest
4 concepts are shown here each provide thermal
power to a 100-kW electric system.
The reactor module mass generally ranges from
1500 kg to 3000 kg.
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This is an example of a small 1MWt liquid metal
(lithium) cooled Heat Pipe reactor
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Relative Reactor Sizes of 4 Potential JIMO
Reactors
HP-BR
GC-BR
50cm
LM-TE
LM-BR
96
In 1977, scientists exploring cracks in the ocean
floor deep beneath the sea found a big surprise.
Large, odd-looking animals were surviving without
sunlight. Strange plants and animals, never seen
on Earth before, were living deep on the ocean
floor. These plants and animals had no sunlight
to keep them warm. How could these new plants
live without the suns energy to live? How could
the animals live without the oxygen from plants?
97
Instead of warm energy from the sun, these plants
and animals get their warm energy from heat
produced in the center of the Earth. The heat is
released into the ocean from chimneys called
thermal vents, just like the fireplace in your
house releases heat up the chimney.
If youve ever been to Yellowstone National Park,
you may have seen Old Faithful, a thermal vent
called a geyser.
98
A spacecraft called Galileo traveled to Jupiter
in 2003 and discovered a frozen ocean on
Jupiters moon, Europa. The spacecraft also saw
things on Europa that looked like the cracks they
discovered on the ocean floor of Earth in
1977. Those cracks could let energy from Europa
heat its ocean water, just like the way thermal
vents heat the Earths ocean water.
99
Mars Surface Power

Operation on Mars presents several design
challenges
Potential corrosion of reactor materials due to
Martian atmosphere.
Solution No refractory metals, Stainless-steel
as the primary material.
Although material changes due to carburization
need to be considered
Shielding issues caused by the Martian regolith
and atmosphere.
Solution Shield surrounds entire core,
additional component shielding.
Weather/environment - dust buildup, high wind,
large temperature swings.
Vertical radiator profile, thicker structural
members, insulation/baffles.
Operation on Mars also presents several potential
advantages.
Enhanced conductive heat transfer caused by CO2
in gaps.
Helps reduce temperatures in failed heatpipe
condition
Does not require He gap between fuel-pin and
module
This could greatly simplify handling at the Cape
Enhanced radiative heat transfer - emissivity
increased by oxidation/carburization.
Also helps reduce temperatures in failed heatpipe
condition
Gravity assisted thermal-hydraulics.
Can greatly simplify integration of core to power
conversion system
Mars lander aeroshell could potentially serve as
Earth reentry aeroshell
Eliminates significant design/mass concern if
aeroshell is required for safeguards

100
FRINK is Part of an Integrated Space Reactor
Design Process

MRPLOW Modular Reactor Powering Lunar Outpost
Works
MRPLOW is the workhorse design tool that drives
the design process for lunar reactors.

MONTEBURNS Automated MONTE Carlo BURNup tool
that links MCNP and ORIGEN
MONTEBURNS provides burnup reactivity, flux and
fluence, decay heat, activity, etc.

MOE MCNP Output Edits.
This is the package of codes that reads MCNP
output data, then normalized it and puts it in
various forms to pass to different design tools.

FRINK Fast Reactor Integrated Nuclear Kinetics
FRINK calculates reactor transient response based
on simplified assumptions of the power conversion
system.

101
HOMER-15 and 3-kWe Stirling Power System
102
Dose Next to a JIMO-Class Reactor Before Operation

Radiation transport calculations have shown that
the radiation dose is below nominal background
levels next to the SAFE-400 prior to operation.

12 hour hike up Colorado 14,000 ft peak 0.48
mR, Chest X-ray 40 mR, Average background 360
mR, Occupational dose limit 5 R. Dose rate data
obtained from EPA website www.epa.gov.

103
This class of reactor is radiologically benign
prior to operation.
Note The dominant dose contributor depends on
the reactor configuration and fuel form.
104
Radioactivity decays to very low levels after 300
years

There radioactivity of a JIMO-class reactor will
decay to benign levels of radioactivity

If the reactor is used for an NEP spiral out of
Earth orbit, the activity increases only as
spacecraft moves out to a longer orbit.

105
Potential accident scenarios that could cause
inadvertent criticality

Core flooding
All void space in core filled with water or wet
sand
This includes flow channels, heatpipes,
fuel-pins, or any potential voids within the
core, even if they are individually hermetically
sealed. The combination of forces to do this and
keep the core intact may be impossible
Core immersion
All space surrounding core is filled with water
or wet sand
Wet sand adds more reactivity due to increased
reflection
Immersion must be analyzed both if system remains
intact or if the core is stripped from the
reflector and rest of system
Core compaction
Depending on core geometry, it may be possible to
compact the core to a more reactive
configuration. Reactors with solid packing
have an advantage.
Core disassembly on impact
For some concepts, a rearrangement of the fuel
pins can increase core reactivity, both on land
or in water. Scenarios have to be evaluated on a
concept specific probabilistic basis.
Launch pad fires, transport accidents, etc.
Analyzed as needed once the development and
mission architecture is established, not usually
a concern for fission systems that are not
radioactive.
Spurious/inadvertent control signals
Can be handled with thorough redundancy,
engineering, and testing.

106
Listing of Some Immersion Criticality Safety
Options

Flooding/immersion scenarios are generally
considered the most credible accident that could
cause inadvertent criticality (although
consequences are extremely low).
Nominal shutdown margins are so large that only
the increased moderation provided by water can
bring the system close to critical.
Potential options that can be considered to avoid
inadvertent criticality (many options require
unobstructed access to one end of the core)?
Spectral - Thermal/resonance neutron absorbers
are permanently placed in str

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Space Nuclear Power - PowerPoint PPT Presentation

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