Notes |
AIR COMMAND AND STAFF COLLEGE
AIR UNIVERSITY
Operational Defenses through Weather Control in 2030
by
Michael C. Boger, Major, United States Air Force
A Research Report Submitted to the Faculty
In Partial Fulfillment of the Graduation Requirements
Advisor: Major Paul J. Hoffman
Maxwell Air Force Base, Alabama
April 2009
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Operational Defenses through Weather Control in 2030
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14. ABSTRACT
The United States needs to incorporate the defense against directed energy weapons with the same
intensity used developing anti-ballistic missile defenses. One of the major drawbacks to optical or directed
energy systems is the inability to penetrate clouds or dense fog. Advances in technology are beginning to
bring weather phenomena under our control. Greatly increased computing power and micronized delivery
systems will allow us to create specific perturbations in local atmospheric conditions. These perturbations
allow for the immediate and lasting ability to create localized fog or stratus cloud formations shielding
critical assets against attack from energy based weapons. The future of nanotechnology will enable
creation of stratus cloud formations to defeat DEW and optically targeted attacks on United Sates assets.
The solution the weather control problem involves networked miniature balloons feeding and receiving
data from a four-dimensional variation (4d-Var) computer model through a sensor and actor network. A
network of diamond-walled balloons enters the area to be changed and then both measures and affects
localized temperature and vapor content. This system effectively shortens the control loop of an
atmospheric system to the point it can be managed. The capabilities in the diamond-walled balloons are
based on the future of nanotechnology.
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Disclaimer
The views expressed in this academic research paper are those of the author(s) and do not
reflect the official policy or position of the US government or the Department of Defense. In
accordance with Air Force Instruction 51-303, it is not copyrighted, but is the property of the
United States government.
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Abstract
The United States needs to incorporate the defense against directed energy weapons with
the same intensity used developing anti-ballistic missile defenses. One of the major drawbacks
to optical or directed energy systems is the inability to penetrate clouds or dense fog. Advances
in technology are beginning to bring weather phenomena under our control. Greatly increased
computing power and micronized delivery systems will allow us to create specific perturbations
in local atmospheric conditions. These perturbations allow for the immediate and lasting ability
to create localized fog or stratus cloud formations shielding critical assets against attack from
energy based weapons. The future of nanotechnology will enable creation of stratus cloud
formations to defeat DEW and optically targeted attacks on United Sates assets. The solution the
weather control problem involves networked miniature balloons feeding and receiving data from
a four-dimensional variation (4d-Var) computer model through a sensor and actor network. A
network of diamond-walled balloons enters the area to be changed and then both measures and
affects localized temperature and vapor content. This system effectively shortens the control
loop of an atmospheric system to the point it can be “managed.” The capabilities in the
diamond-walled balloons are based on the future of nanotechnology.
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TABLE OF CONTENTS
Disclaimer ....................................................................................................................................... ii
Abstract.......................................................................................................................................... iii
List of Figures................................................................................................................................. v
Weather Operation: White Carpet .................................................................................................. 1
Introduction..................................................................................................................................... 3
Methodology................................................................................................................................... 4
Problem Significance ...................................................................................................................... 5
Defeating Optical Target Engagement and Directed Energy ......................................................... 7
Optical Target Engagement ........................................................................................................ 7
Directed Energy Weapons .......................................................................................................... 9
Weather Control Past and Present ................................................................................................ 14
Foundations of Weather Control ................................................................................................... 17
Relevance Tree .......................................................................................................................... 17
I Give You Nanotechnology!.................................................................................................... 19
Conclusion and Recommendations ............................................................................................... 26
Appendix A: Concept Weather Control Relevance Tree .............................................................. 28
Appendix B: Component Relevance Tree .................................................................................... 29
Appendix C: Acronym List ........................................................................................................... 30
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List of Figures
FIGURE 1: Directed Energy Weapons in the Electromagnetic Spectrum ……………………. 10
FIGURE 2: Autonomous Nanotechnology Swarm Timeline………………….………………. 23
FIGURE 3: Four Generations of Nanotechnology…………………………………………….. 25
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Weather Operation: White Carpet
The strike package is a complicated mixture of fourth and fifth generation aircraft,
integrated with ISR and strike unmanned aerial vehicles (UAV). The lead element into the area
of regard (AOR) is a set of strike UAV’s. As the unmanned aircraft enter the threat areas, the
enemy integrated air defense system (IADS) becomes fully active. The ability to engage the
strike package is limited to kinetic surface to air missiles (SAM) and anti-aircraft artillery
(AAA). Sophisticated directed energy weapons (DEWs) attempt to engage but are thwarted by a
cloud layer between the strike aircraft and the ground. The unmanned vehicles make short work
of the kinetic systems, essentially following the guidance and infra-red (IR) signatures of the
launch sites. As the UAV’s descend below the cloud layer enroute to their SAM and AAA
targets, some are intercepted by DE systems. Only three of 120 aircraft are engaged, indicating
the severe degradation of the enemy’s IADS.
The manned fighters and bombers enter the AOR with a reduced threat array and ability
to focus on the enemy’s less-capable fighter defenses. After disposing of enemy fighters and
avoiding or evading kinetic surface to air weapons, each aircraft delivers their deadly payload.
The return to base is nearly as smooth. The enemy relied excessively on DEW defense systems.
The fear of nearly zero time of flight (TOF) DE IADS was rendered totally ineffective by that
mysterious cloud layer.
Operations actually began six hours prior to the strike aircraft entering the AOR. The
CFACC directed Weather Control to proceed with operations. A Global Hawk was on station at
high altitude and 150 miles “upstream” from the AOR. At the determined altitude and location,
the UAV released its balloon payload. Diamond nano-skinned balloons of approximately three
to five millimeters in diameter began distributing through approximately every square meter in a
pre-determined column. Upon command, solar cells and elemental mirrors in the balloons
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began to absorb sunlight, heating the skin of the balloon. The entire column, controlled through
the balloon sensor and actor network (SANET), began to heat and develop into a localized high
pressure area. As the high pressure developed, the jet stream was pushed north of the AOR,
stabilizing the atmosphere between the forward edge of the battle area (FEBA) and primary
target area. More UAVs launched from near the FEBA hours prior were established in their
assigned orbits. On command, similar diamond balloons were released, reporting current
localized temperature, water vapor content and pressure back to the UAVs. As the UAVs passed
their data back to Weather Control, computers developed specific inputs to the atmospheric
equation. These inputs were sent back to the balloons. Some balloons utilized electrolysis to
remove water molecules in the atmosphere. Others gathered water molecules to build cloud
condensation nuclei as they maneuvered towards their desired altitude. Some balloons heated or
cooled, to establish a temperature/pressure ratio allowing for the formation of clouds. Over the
course of a few hours a definite cloud deck developed, constantly supported by an artificial high
pressure area and fed by an army of micro balloons networked, powered and operated by
nanotechnology.
During the mass brief of the strike aircraft, Intelligence described the lethal matrix of
directed energy IADS in the AOR. After the aircrew reviewed their routes in reference to the
threats, the Defensive Weather Controller (DWC) began his brief of DE denial: A cloud deck
from 11,000 to 12,000 ft mean sea level (MSL). The DWC estimated that any optical and
microwave systems will be rendered ineffective. Even with the destruction of the
delivery/networking UAV’s, the generated weather phenomenon was expected to last
approximately four hours with a 97% match to briefed description. Potential for external
weather interference was mitigated by a preemptive high pressure; jet stream steering trough
established 120 nm north of the AOR. All sensors reported positive generated condensation with
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confirmation from optical satellite feeds. A young F-35 wingman whispered to his flight lead
during the brief, “Man, I hope this weather stuff works.”
Introduction
Directed Energy is fast becoming the popular weapon of the future. Along these lines,
optical intelligence is still, and will remain to be a critical method of targeting weapons. These
weapons will be wide-spread by approximately 2010.1 The United States needs to incorporate
the defense against these weapons with the same intensity used developing anti-ballistic missile
defenses. One of the major drawbacks to optical or directed energy systems is the inability to
effectively penetrate clouds or dense fog. Advances in technology are beginning to bring
weather phenomena more completely under our control. Greatly increased computing power and
miniaturized delivery systems will allow us to create specific perturbations in local atmospheric
conditions. These perturbations allow for the immediate and persistent ability to create localized
fog or stratus cloud formations shielding critical assets against attack from energy based
weapons. The future of nanotechnology will enable creation of stratus cloud formations to
defeat DEW and optically targeted attacks on United Sates assets. Focus on weather control in
an isolated defensive manner helps to alleviate the fear of widespread destruction on nonmilitary personnel and property.
The overall solution to this weather creation problem involves networked miniature
balloons feeding and receiving data from a four-dimensional variation (4d-Var) computer model
through a sensor and actor network. A network of diamond-walled balloons enters the area to be
changed and then both measures and affects localized temperature and vapor content. This
system effectively shortens the control loop of an atmospheric system to the point it can be
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“managed.” The capabilities in the diamond-walled balloons are based on the future of
nanotechnology.
Methodology
Determining weather control methods in the year 2030 required the use of multiple
methodologies. The question of “What is required to control the weather and how do we do it?”
needed an answer. The entire process began with an extensive environmental scan. Current
methods of weather modification were studied to determine limitations in weather control. This
step also involved finding key experts in the fields related to weather control. An initial concept
relevance diagram was developed. Two individuals help assemble a panel of experts. The
Public Information Chairman of Weather Modification Association (WMA) and contract
manager of multiple National Oceanic and Atmospheric Administration (NOAA) programs, Dr.
Thomas DeFelice, and Mr. Peter Backlund, Director of Research at the National Center for
Atmospheric Research (NCAR) helped establish contacts to develop requirements for an initial
concept diagram. The concept diagram was then vetted among the experts and a community of
weather modification researchers and entrepreneurs at WMA (www.weathermodification.org).
The concept relevance tree was refined (Appendix A) to the specific requirements to create an
opaque mesocale stratus cloud formation – that which would be useful on the battlefield.
Experts from weather modeling, weather system dynamics and nanotechnology helped link
requirements to capabilities. These links were developed into a component relevance diagram
(Appendix B). Dr. Ross Hoffman from Atmospheric and Environmental Research Inc provided
guidance on weather simulation, systems and dynamics. Dr. J. Storrs Hall, author of Nanofuture,
and research fellow at the Institute for Molecular Manufacturing, supported research on
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nanotechnology. Concurrently, the author conducted an environmental scan in the area of smart
networks and military application of weather control technology.
The roadmap for this discussion of operational weather control involves a discussion of
requirements, application and capabilities. The conversation begins with the capability of
weather to interfere or deny optical targeting and DEW attacks. The discussion then explains the
complexity of weather and system control concepts. A relevance tree with direct input from field
specific experts flushes out the intricacies of these technologies and their dependencies on each
other. Finally, the future of these technologies is discussed to place weather control in the 2030
timeframe.
Problem Significance
Weather control opens vast opportunities for the United States military to explore.
Besides enabling many operations, a key capability involves the defense against future optical
targeting and directed energy threats. A simple opaque cloud of water vapor negates the optical
tracking and engagement of a target with directed energy. While controlling the atmosphere
over a target area is far more difficult than setting the temperature with an air conditioner,
advances in technology will make it possible for men to shape weather conditions in a localized
area. When we harness the clouds and the fog, we can use it as a shield against offensive
capabilities in 2030.
For current precision weapons to be effective, the target must be found, fixed, tracked,
attacked and assessed.2
Water vapor in the form of fog or layered cloud formations causes a
problem for these capabilities. Many systems require visual or infrared (IR) detection and
tracking methods for adequate resolution. If the target is moving, weapons are continuously
guided by designated the target with lasers. Directed energy weapons turn the laser itself into the
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weapon. Other methods of detection and tracking include millimeter and microwave detection.
All of these methods of applying DE to target engagement can be thwarted by the mighty water
droplet.3
There are methods (varying wavelengths) and power levels of DE that can penetrate
weather for targeting purposes, but the power and close-range required exposes them to direct
attack.4
A few issues have re-ignited weather control and modification interests. Increased
computer modeling power has made detailed experimentation possible. The fear of global
warming and increased publicity of weather related tragedies have ignited the sciences. The
technology of weather modification has expanded into rain or snow development (cloud
seeding), hail dissipation and lightning dissipation. Current credible scientific study deals with
hurricane, tornado and flood mitigation.5
China is the current lead investor in weather
modification and control technology, investing nearly 40 million dollars annually.6 The Chinese
efforts were put on display for the world during the 2008 Summer Olympics.7 The efforts of the
Chinese to reduce the amount of rain (by inducing precipitation elsewhere) seemed to work, but
as is a current issue with weather modification, there is not indisputable proof. The military uses
of controlling the weather are vast, and future technology will enable more specific control of the
weather – actually creating, not modifying weather.
Others in the United States Air Force have forecasted the ability to use weather as a
tactical advantage. The Air Force 2025 paper Weather as a Force Multiplier: Owning the
Weather in 2025 specifically addresses the increase in computing power in conjunction with
current weather modification techniques to shape the battlespace. Pressing this an additional 10
years into the future will see more dynamic and specific use of nano and micro technologies in
conjunction with increased autonomous networking capability. Rather than steering a storm or
moving fog, a military commander will create weather to utilize defensively.
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Defeating Optical Target Engagement and Directed Energy
To engage a moving target, a system must detect and track the target in real-time. Then,
a weapon must be guided or updated with the targets location during the weapons time of flight.
Finally, the weapon must survive the flight through the atmosphere, on the way to the target. It
must be understood how effective weather is against DEWs and optical target engagement on the
battlefield. Weather affects deliverable through the technology in this discussion begins above
1,000 feet above ground level (AGL), avoiding turbulent interaction with the ground.8 The
weather phenomena to be used as a DEW defeat mechanism is established as a stratus or altostratus layer of clouds comprised of a mixture of crystals and droplets of water.9 This cloud is as
thick as required to be optically opaque against visible, infrared (IR) and ultraviolet (UV)
wavelengths. An approximate cloud thickness of 300 to 500 feet is assumed, resulting in a
visibly opaque cloud formation.10 Actual cloud thicknesses will depend on results from
computer modeling and inputs of cloud vapor content (crystal, vapor and micro-droplets) as well
as predicted weapons to defeat. A discussion of optical engagement and targeting will show how
clouds can force the enemy into alternate and attackable means of surveillance. Second, a
discussion of future DEW technology and limitations will show how clouds will reduce DE
effectiveness for strategic and tactical use.
Optical Target Engagement
Optical tracking and targeting can be accomplished by a variety of means. Methods
range from ground based outposts to satellites in orbit. There are three distinct capabilities of
finding, tracking and guiding weapons. Finding, tracking and guiding weapons on a target are
capabilities that are dependent on the detail you can see, the time available to see the target and
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the method you are using to update a weapon in flight. The ability to simply find a target is the
least complicated, if it doesn’t move!
The higher the altitude at which an optical platform operates generally results in reduced
flexibility of its search area. Military targeting satellites would have similar requirements as
civilian satellites such as GEOEYE 1. GEOEYE 1 operates in the region of low earth orbit and
can produce 16 inch resolutions with an approximate seven foot positional accuracy.11 Lower
earth orbit is roughly considered to be 200 to 930 miles above the earth.12 At this resolution you
can identify types of vehicles and objects while determining coordinates upon which to have
weapons or energy impact. The limitation involves time. GEOEYE-1 is a comparable civilian
system which can revisit a location approximately every two days.13 If the target is visible and
does not move during the two day envelope, then systems such as GEOEYE-1 can effectively
maintain a track. Systems like GEOEYE-1 cannot penetrate weather phenomena that the naked
eye cannot see through. Optical occlusion for more than two days can be accomplished by
weather phenomena that deny acquisition of the ground. The effect of this denial drives the
enemy to utilize a system closer to the target area, denying the current sanctuary of space or
requiring a different method of surveillance. Alternate methods of surveillance will require an
electromagnetic method outside of passive visual, IR, UV detection and surveillance closer to the
target area. Electromagnetic methods require the transmission of energy, resulting in the
pinpointing of and possible destruction of the transmitting source. Reducing the range to the
area of interest exposes the manned or unmanned optical targeting platform to attack from the
target area.
Optically tracking and targeting are similar in concept with the exception of time.
Dynamic targets and precision weapons require a method to update both target location and
weapon flight path throughout the weapon time of flight. Without transmitting electromagnetic
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energy, optical systems are required to provide the resolution and tracking capability for accurate
engagement of most target types. Atmospheric moisture that is thick enough to occlude the
target or the target’s movement effectively negates both optical tracking and laser-based methods
of guiding weapons.14 By creating clouds in specific locations and altitude blocks, optical
weapons systems will be forced to occupy predictable locations making them easier to target or
avoid. Making the tracking laser and weapon the same thing reduces weapon time of flight and
is a critical capability of DE.
Directed Energy Weapons
High Energy Lasers (HEL) and High Power Microwaves (HPM) are currently the
primary methods of directed energy attack. Both of these categories break down further into the
methods of creating the laser or microwave energy as well as transmission and control of the
beams. It is the expectation that within the next 15 years, these types of DEW will become
increasingly common on the battlefield.15 Department of Defense (DOD) interest in directed
energy programs spans from the tactical to strategic uses on the ground and in space.16 HEL and
HPM technologies have different methods of effectiveness on their target. HELs apply high
temperatures on the surface, destroying their target. Lasers can also cause disorienting effects on
the operator of their target.17 HPMs affect the internal circuitry of the target or internal tissues of
the operators.18 Both HELs and HPMs have the strengths of zero time of flight but the effects
require a great deal of energy to remain coherent from the weapon to the target. HEL and HPM
require separate discussion of effects and defeat mechanisms.
DEWs have a limit of operation within the electromagnetic spectrum. The power of
these weapons depends on their electromagnetic signature. Figure 1 shows where laser and
microwave weapons inhabit the electromagnetic spectrum. Both wavelength and frequency are
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tied together since the speed of the energy weapon is considered to be constant at the speed of
light (c). As a result, the variables of wavelength or frequency are characteristics that can be
modified. The amount of energy per second, measured as watts, depends on the pulse length or
total amount of lasing or radiating time for a given beam. As frequency increases, wavelength
decreases and the amount of energy in a directed beam also increases.
Figure 1. The Directed Energy Weapons in the Electromagnetic Spectrum (adaped from
http://kingfish.coastal.edu/marine/animations courtesy of Louis Keiner).
Energy = Plank's constant × Frequency
E = hν = hc/λ
Where h = Plank's constant is 6.626 × 10-34 joules per second
λ = wavelength
This is important because longer wavelengths have the best chance of surviving an encounter
with particles in their way.19 In the region of one micrometer (1µm) wavelengths, directed
energy can survive interaction with water vapor but still do not have the energy density to
overcome atmospheric absorption.20 A trade off is made between getting a specific amount of
energy over a long range or having a lower amount of energy survive interaction with weather.
As the wavelength increases, the weapon must be closer in range and operate for a longer
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amount of time to deliver an effective density of electromagnetic energy. This is where the
defeat of DEW due to weather occurs.
Ground based HEL systems may be used against airborne and space based targets. Space
and airborne lasers can be employed against fielded maneuver forces as well as strategic
locations such as governmental facilities, headquarters, and operations centers.21 In both cases,
the laser “beam” must travel through the atmosphere to the target. The future of laser technology
is expected to produce approximately 10 million watts by the year 2030.22 At this power level
the contact area of an aircraft’s aluminum skin can exceed 1500° F within a second, causing its
destruction.23 Laser weapons require approximately a second of target tracking time, nearly
negating the requirement to continuously track a target. Superheating the target requires getting
the laser to the target. With the exception of space to space employment of lasers, the beam
energy must travel through the earth’s atmosphere. Lasers have to deal with refraction,
reflection and absorption during their short time of flight.
In the absence of clouds, the laser still must account for diffraction issues due to varying
densities at the propagation medium.24 The beam of light may not arrive at the intended target
due to bending caused by temperature and density changes in air. To help overcome this, laser
weapons systems utilize a secondary compensation and tracking laser to evaluate the atmosphere
enroute to the target. Data from the tracking laser continuously compensates for the atmosphere
by changing characteristics and aiming of the main destructive beam. This tracking laser has
much less power with a long wavelength to penetrate atmospheric turbulence. This targeting
laser, however, suffers from the same issues as current kinetic weapon lasing systems; the
inability to penetrate water vapor that is opaque to visible light. Before the weapon is even
employed, it is defeated by opaque water vapor.
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The coherent electromagnetic energy used as the weapon in HELs suffers from loss due
to refraction, reflection and absorption. Refraction reduces the light beam focus and coherency.
The intensity of power is reduced as optical properties of water droplets and ice crystals bend the
laser beam, breaking it into smaller elements of coherent light.25 The thicker the cloud layer, the
more the beam is refracted. Reflection also scatters the beam by bouncing portions of the laser
out of the direction of travel. The reflection in clouds reduces the intensity and power of the
beam for each element of the cloud it interacts with. A 100 foot thick stratus cloud of mixed ice
and droplet particles can totally obscure a laser, reducing it to a glimmer of incoherent light with
negligible heating effect beyond the clouds.26 The total power, intensity and coherence of the
beam will determine whether it can “burn through” the cloud and have any applicable energy on
the far side of the cloud. Keep in mind, the targeting and compensation laser has already been
defeated so we do not know if the weapon energy is correctly aimed at target. Can a laser
tunnel through the cloud with enough energy?
The concept of using a terawatt tunneling pulse laser has been suggested to give a DE
laser a path through clouds. This concept has a problem with the other issues of atmospheric
absorption due to water phase changes. The concept requires a continuous wave and pulsed laser
to coexist in a coaxial fashion. The pulsed laser punches a hole in the cloud as the continuous
wave laser propagates unhindered. 27 The theory works when tested against homogenous water
vapor aerosols.28 However, everything changes when the cloud is a mix of ice, droplets and
vapor. As the laser heats the mixture, the aerosol and ice form a combination of regionalized
vapor and plasma. The tunneling and primary lasers now have to deal with the absorption of
energy from the changing aerosol with the addition of plasma.29 Both lasers themselves have an
excessively chaotic effect on the non-homogenous cloud, further dissipating the beams.30 After
the laser passes through the atmosphere, the cloud mixture immediately re-establishes the
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mixture equilibrium to the pre-laser state.31 This is the strength of utilizing the mixture of water
phases rather than smart dust or opaque mechanical means to defend against DEW. With enough
power, it is conceivable that a laser or laser combination could eventually burn through a mixture
at the cost of time and power.
HPM weapons attack the electrical or network functionality of a system. HPM can also
have direct effects on personnel. The non-lethal effects of HPM on humans are significant,
occurring at the range of thousands of feet but are negated by any physical structure between the
transmitter and target.32 The long range capability of HPMs deals with the capability of
disabling electronic components of weapons systems in the kilometers range of effect.33 This
discussion centers around the projection of electromagnetic pulse (EMP) or associated effects
over a tactical range effecting aircraft and command and control (C2) capabilities.34 To disable
C2 networks and weapons systems, a microwave source must be projected onto the system under
attack. The difference between HEL and HPM occurs in the frequency/wavelength of
electromagnetic spectrum as well as the size or coherence of the propagated energy. HPM is not
employed in a tight, coherent beam of energy. HPM are “shot” as a broad region of energy
waves. As a result, defeating HPM is less dependent on the reflected and refracted disruption of
coherent excited radiation and more reliant on the absorption broadcast energy. Microwaves
provide a density of energy that can destroy complex electronic devices while still being aimed
at a specific location in space. The position of HPM in the electromagnetic spectrum requires a
large antenna to aim microwave energy.35 The amount of energy required at the target to
accomplish affects can be considered a constant. Like optical targeting and engagement, the
ability to deliver energy against a target can be made dependent on range due to weather
interference.
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To defeat HPM, weather needs to reduce the energy transmitted over range to the point of
negligible returns. Beam steering and intensity become primary factors in the delivery of energy.
Once again, clouds provide a method of both denying atmospheric sampling and establishment
of a homogeneous medium. HPM can penetrate weather, but the use of clouds can limit the
effectiveness of HPM to specific regions of frequency for which equipment can be hardened.
Microwaves attenuate by imposing most of their energy on water molecules. This is how a
microwave oven cooks food. This is the method that clouds can use to lock effective HPM
weapons into specific frequencies. The natural attenuations caused by water, nitrogen and
carbon monoxide in clouds constrain HPM to frequencies of 22, 35, 94, 140 or 220 GHz.36 You
can effectively, and more cheaply, harden critical equipment against these five frequencies rather
than the spectrum of HPM. Attenuation through absorption still occurs in these bands, requiring
the HPM source to reduce range to target and increase antenna size to be effective.37 Weather
cannot have much effect on those HPM that involve delivery of EMP devices in close proximity
to their target. HPM bombs or EMP generators are intended to function within a kilometer of the
target. At these ranges, the delivery system can be targeted by conventional assets.
It is the natural phenomena of refraction, reflection and absorption that clouds enhance in
defense of ISTR and DEWs. The abundance of the crystalline, liquid and vapor water in clouds
makes them a credible and persistent defense against DEW. Clouds either totally negate the
DEW threat or force the enemy into an alternate method of targeting and attack. Creation of the
described 1000 foot thick stratus clouds is the challenge for technology.
Weather Control Past and Present
There is a long history of man attempting to control or modify the weather. Most
attempts at weather control involved enhancing or utilizing an existing weather phenomenon
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such as creating rain from already present clouds. Weather dissipation was an interest of the
military during the early 1940’s, utilizing large trenches of burning fuel to dissipate fog to enable
aircraft to takeoff on bomber missions.38 Later, in the 1960’s and 1970’s Project Popeye was a
military attempt to increase localized rainfall to reduce mobility on the supply routes of North
Vietnam, shaping the battlespace for war planners.39 Concurrently project GROMET II was
underway in the Philippine Islands. This project indicated more measurable success in
producing rain to stop a severe drought.40 Since then, the US military dramatically reduced
funding for active weather control activities, leaving it to private industries to brighten the hopes
of Midwest farmers in search of rain.
Civilian attempts at weather control centered on making existing clouds produce rain.
Making rain was intended to help farmers overcome droughts. Additional interest developed in
making clouds deteriorate into rain in areas that were not prone to flooding. Seeding clouds
could also reduce the severity of storms and hail damage to crops and property. The US Weather
Bureau undertook a project of massive cloud seeding in 1947.41 For the next twenty years,
research and experimentation focused on what types of chemicals or methods of seeding could
produce precipitation. The research itself was problematic due to the inability to link rainfall
results directly to specific variables in the activities of cloud seeding. Variables such as seeding
media, cloud type, time of the day and season were changing during the experiments.42 Two
major problems were identified. First, the timeframe and geographic area of measuring was too
large, making attribution of seeding methods problematic. Second, the physics of cloud
production, sustenance and finally destruction were not understood.43 44 The speed at which a
system could be identified, seeded and measured for results was too slow. Satellite, radar and
remote temperature measurement capabilities eventually helped scientists to quickly identify and
evaluate a weather system during an experiment.45
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New technologies such as radar and satellite sensing have enabled the study of cloud
lifecycle dynamics. Lightening suppression, tornado and hurricane detection and dissipation are
now being hypothesized.46 Cloud seeding is still the predominant method of weather
modification, requiring an existent weather system. The effects of seeding and the methods of
applying them can now be measured, directly attributing results to system variables.47 It was
technology leaps in measurement that allowed scientists to accurately determine the variables
and results of a system over a broad geographic and time span. The ongoing leap in weather
forecasting and control research is based on computer power and modeling.
Computing power and modeling developments have allowed weather scientists to
forecast complex weather systems effectively. Downstream forecasting, estimating when an
upstream weather system will arrive, has given way to accurately determining multiple weather
system interactions. The Weather Research and Forecasting Model (WRFM) is the current
mesoscale weather prediction model based on three dimensional variation (3d-Var).48 The
accuracy of the modeling system depends on the stability of the variables and the computing
power used by the model. The combination of this powerful modeling capability and real-time
data available from measuring devices allows this model to forecast the birth and lifecycle of a
weather system.49
The strength of the WRFM rests in the use of nonhydrostatic atmospheric modeling.50
This method allows for the model to simulate non-linear chaos within clouds and systems of
clouds. This is important because now a model can extrapolate an output from a system that is
not proportional to the inputs. The WRFM applies the interaction of small-scale and mesoscale
systems in the area of five to thousands of kilometers, dependent on the ability to accurately
measure these areas. The WRFM is an initial step towards removing the stigma of applying
Chaos Theory towards mesoscale weather systems. A system is broken down into elements.
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The size of these predicted elements only depends on the frequency of measurement and number
of data points available in the given system. The WRFM does not look at the global system, it
does accurately simulate the internal and intrasystem physics of clouds.51 So why can’t the
weatherman get it right?
The availability of the WRFM and the computing power to support it are limited. The
WRFM is a collaborative operation between the NOAA, NCAR and six other major
organizations. The WRFM is mostly used for research and future forecast method modeling.
Getting the proper amount and timeliness of data into the WRFM is the weatherman’s limitation.
Most radar and satellite measurement methods take samples of portions of a weather system.
Updating and maintaining a persistent stream of system data from distinct points in the system
simultaneously is difficult. Most current methods of measurement are very capable of describing
portions of a weather system by their movement or change. This method of mass flux element
measurement works well with linear models; inputs are proportional to outputs. The non-linear
modeling requires for selective use of data. For better data assimilation and utilization, the
measurement devices almost need to be a part of the weather system, and this is where
technology will fill the gap. The fast modeling and computations of the WRFM are now
hindered by the accuracy of measuring in the system. How does one go from taking accurate
forecasting to the actual development of a weather system?
Foundations of Weather Control
Relevance Tree
Relevance trees helps break a concept down to basic functions and requirement. For
weather control, these topics further devolve into the physical or operational parts of a system to
create a cloud in the atmosphere. The relevance tree was used as a tool to determine what
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technologies need to be linked in order to control a complex system like weather. Through
collaboration between experts in weather, computer modeling, and nanotechnologies, the
elements of the system are reduced from required functions to the suggested components for
weather creation.
The concept relevance tree (Appendix A) presents cloud development requirements with
some additional considerations. Isolating and establishing the atmospheric area to be modified
became the initial area of discussion among members of the Weather Modification Association
and subject matter experts (SMEs). The concept tree indicated a grand set of ten major criteria:52
1. Establish/Isolate a System
2. Measure Variables in System
3. Determine Required Variable Values in the System
4. Change Variables in the System
5. Network System Components
6. Control Location of Components
7. Deconfliction With other Assets
8. Manpower
9. Side Effects
10. Vulnerability to Attack
(Weather Modification Association panel of experts and the author, 2008)
The size of the problem required the researcher to focus the problem to just
accomplishing the development of a cloud system. As a result, items eight through ten were
removed from this project. Manpower, possible side effects and vulnerability of the weather
control system are important but were found to be beyond the scope of this project. The
remaining items were further broken down to the descriptions of their function. Great
consideration was given to the difficulty of isolating the atmosphere for modeling. Debate and
expert input settled the issue to broad effects stabilizing the mass flow to manageable levels in
which the elements within the mesoscale could be affected would suffice. The concept relevance
tree has been broken down to the critical requirements of isolating an atmospheric area;
measuring and setting variables within the system.
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A closed loop system needs to be developed to control weather. Weather control goes
one step further than the current capabilities of 3d-Var modeling while measuring atmospheric
variables outside the system. Two major technological humps stand in the way of weather
control. First, making a cloud in a specified geographic area requires setting and isolating a
system to create weather in. Much like “controlling the air mass” with an air conditioner.
Second, the actual methods of altering the temperature, pressure, or vapor content within the
elements of the system.
The Ideal Gas Law, PV=nRT is an extremely simplistic way of regarding the control of
weather. Water vapor content changes this from an ideal gas equation, but sufficiently models
the interaction. Cloud development depends on vapor content and method of coalescing into an
opaque cloud.
Pressure X Volume = Quantity (moles) X Gas constant X Temperature
PV = nRT
Condensation rate is proportional to vapor condensation based on the Ideal Gas Law. It is the
iterative and complex interaction between the equilibrium of condensation and the Ideal Gas
Law that will develop clouds. Volume, in this case, depends on mass flow rates. Pressure and
temperature are dependent on each other and the water content in the air will determine at what
temperature/pressure a cloud will form. The nuclei of cloud formations can vary from water
droplets to micro ice-crystals. The change in pressure and temperature with altitude determine
the construct of that mixture. How do you control the inputs and outputs to your system?
I Give You Nanotechnology!
The component relevance tree (Appendix B) matched the requirements. Crossreferencing the requirements with the environmental scan of future nanotechnology and
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computer modeling provided solutions to the concept relevance tree. The primary problem
determined through the relevance diagram was speed and precision at which a closed-loop
weather control system could operate. Nanotechnology enabled sensors and networks answered
the problems of measuring, altering and communicating the variables within a weather system.
4d-Var modeling combined with current computing power and accurate data accounted for the
control of the system. The delivery of these systems can be accomplished with current
technology. Having the sensors, network and means of modification of the atmosphere part of
the proposed cloud system removes control lag. The center of this weather control system
revolves around a formation of diamond nano-skinned balloons encasing a host of
nanomachines.
Current weather modification research focuses on the new concept of determining critical
optimal perturbations in atmospheric conditions that will, in essence “box in” a volume of
airspace.53 The area of interest does not need to have zero mass flow. The flow only needs to be
stabilized and directional enough to allow for modification of temperature, pressure and vapor
content to the degree that it results in cloud formations. Perturbations can be as simple as
heating or cooling a large area of atmosphere. Large space-based reflectors could quickly
generate a large high pressure area. The perturbation does not need to be as specific as building
a cloud system and may be hundreds of miles away from the area of interest.54 Once these
designed blockades are in effect, the air mass that has been stabilized can then be adjusted. This
is similar to using smoke in test section of a wind-tunnel. The flow only needs to be constant
and directional enough for the smoke added to allow for visualization of aerodynamic effects in
the tunnel test section.
Micro and nanotechnology provide both a detailed sensor grid to measure critical
variables in a weather generation algorithm and then fill in the variables required to generate the
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desired effects. Current computer power enables 4d-Var modeling. Computing power in 2020
will enable the networking and sensor grid required 4d-Var analysis to determine variable
settings to establish these perturbations to control the system.55 4d-Var extrapolates on the
capabilities of WRFM 3d-Var analysis and determines the minimum large scale perturbation
necessary.56 The modeling starts with small initial state perturbations and simulates the nonlinear response over a 6 or 12 hour window.57 Future applications of these perturbations take the
form of isolated low and high pressure areas or troughs to steer the jet stream or its affect in
relation to the area of interest. Making the high or low pressure area can be as simple as heating
or cooling a massive column of air with diamond balloons.58 Experiments on 4d-Var modeling
began in 2002, already capable of handing weather control data. Dr. Hoffman of Atmospheric
and Environmental Research Incorporated and the former NASA Institute for Advanced
Concepts (NAIC), denies that weather is a truly chaotic system when modeled through 4d-Var
methods.59
Once the mass flow into and out of an area is controlled, it becomes a simple issue of
establishing specific localized temperature (dew point spread), pressure gradient and water
content per volume of air through a column in the atmosphere. Dr. J. Storrs Hall provided a
solution to half of the concept relevance tree through insight on diamond nano-skinned balloons.
The component tree helps indicate now nanotechnology will enable diamond nano-skin balloons
to accomplish several tasks. Dr. Hall best describes the diamond balloons.
“You build a little balloon, my guess is the balloon needs to be somewhere between a
millimeter and a centimeter in size. It has a very thin shell of diamond, maybe just a
nanometer thick. It is round, and it has inside it an equatorial plane that is a mirror. If you
squished it flat, you would only have a few nanometers thick of material. Although you
could build a balloon out of materials that we build balloons out of now, it would not be
economical for what I’m going to use it for.”60
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Motion, location and networking of the balloons can be controlled in several ways.
Altitude is controlled through the buoyancy of the balloon through a combination of electrolysis
of water and nano-pumps removing molecular water from within the balloon. The walls of the
balloon could have nano-fans, providing additional thrust.61, 62 Utilization of the earth’s
magnetic field and the charge on the skin of the balloons themselves will aid in formation
keeping with other balloons.63 Nano-network controllers within each balloon will maintain
contact with neighboring balloons. Solar power through the nano-antenna arrays will charge
nano-batteries.64 Proton exchange membrane (PEM) batteries are current day nanotechnology
that is powered by electrolysis of water.65 Directional micro-antenna will be able to determine
position of the balloons with the formation relative to one another. The diamond balloons will
house an array of sensor and communication technology which is currently being developed to
build radios from carbon nanotubes.66 These communication systems collect and transmit onsite,
accurate data to the complex computer systems that model and establish the controls for a
weather system. Some of the larger balloons function as a node, housing a GPS receiver67 and
micronized network uplink to provide high frequency communication of the network to a ground
station or UAV.68 The distribution of these balloons will depend on the amount of atmospheric
mass flow in the AOR. Discussions with WMA participants and Dr. Hall estimate at least one to
two balloons per cubic meter would be required to initiate changes in conditions. These
estimates were based on current cloud seeding densities. Networking these balloons is similar to
current research into nano-swarms.
The study of sensor and actor networks (SANET) encompasses the communication,
control and activity of our proposed balloon network. Such a network concept includes the
requirement to maneuver nodes and communicate in a complex and distributed network.69 The
study of self controlling and communicating networks began in the 1960s.70 The concept
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accelerated within the last five years with the spread of integrated wireless networking.71 The
function of SANETs specifically requires a network of sensors to communicate, maintain
positional distribution and sense among a distribution of nodes.72 These nodes then pass the data
to and from a monolithic processing center, our 4d-Var model in this case. SANETs are
currently limited by architecture and power, but are already being developed.73 The weather
control application of such networks follows the development timeline and technology of
Autonomous Nanotechnology Swarms.
Figure 2. Autonmous NanoTechnology Swarms (ANTS) Development Timeline (reprinted from
http://ants.gsfc.nasa.gov/time.html).
Autonmous NanoTechnology Swarms (ANTS) is currently being researched by Goddard
Space Flight Center.74 Modeled after insects, ANTS is network architecture applicable to future
nanofactories. Goddard Space Flight Center is currently using ANTS beginnings in experiments
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with large scale robot “herds.” ANTS is the support structure for Addressable Reconfigurable
Technology (ART). The core of ART is a networked swarm of nanomachines capable of
configuring themselves for a variety of tasks.75 The element control requirements for ARTs are
nearly identical to what is required for the proposed network of nano-enabled balloons for
weather sensing and control. The timeline of ANTS development in Figure 2 indicates usable
functionality for distributed SANET control by 2030.
The individual methods of atmospheric modification at the molecular level share
development with the capabilities of nanomachines. A combination of nano-pumps working at
the molecular level can transport water between layers in the atmosphere as the balloons bob up
and down in the air column.76 Nanofactories can conduct electrolysis on water, molecularly
building nuclei of droplets or ice crystals or reducing water vapor. Cooling through
thermoelectric nanomaterials currently being designed for computer applications will enable
control of the balloon skin temperature.77, 78 This cooling and vapor content will have an effect
on the localized pressure as a result of the ideal gas law. As with many non-linear systems, small
inputs can develop large and self sustaining events, as determined by a 4d-Var model. Larger,
more temperature based control balloons will be the center of the high and low pressure
perturbations. The effect required is not as specific, resting mostly on regional temperature.79
Will nanotechnology be developed to the level of atmospheric control by 2030?
Money spent on nanotechnology gives a good indication if it will continue to develop.
Lux Research, a market science and economic research firm, claims that nanotechnology will
become commonplace in across the spectrum of consumer goods by 2014.80 2004 showed a
mere 12 million dollars invested globally in nanotechnology. In contrast, 2008 Lux Research
estimates rise to 150 billion in sales of emerging nanotechnology. It is expected that sales of
nanotechnology will reach 2.5 trillion dollars by 2014.81 Dr. Hall, stated that “2030 nanotech is
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likely to be good enough for a Weather Machine” in correspondence with the researcher.82 Four
generations of nanotechnology have been described by the U.S. National Nanotechnology
Initiative (Fig 3).83 We are currently in the second generation, specifically marked by the
advances in computer CPU technology. Advances in the third generation will allow for much of
the diamond nano-skinned balloon systems to function. The fourth generation will converge
networkability, energy conversion and molecular scale activities in atmospheric change.84
Figure 3. Four Generations of Nanotechnology Development.85 (reprinted from “National
Nanotechnology Initiative – Past Present and Future,” http://www.nano.gov).
Nanotechnology enables the two critical humps in weather control. By the 2030
timeframe, nanotechnology will allow complex models to receive accurate and timely data from
within and across the atmospheric system. These models can then direct those elements to make
changes to the atmospheric system. System detail, data and response will be a function of the
size of an area, how quickly it is changing and how many weather balloons are at your disposal.
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Conclusion and Recommendations
The future of nanotechnology will enable creation of stratus cloud formations to defeat
DEW and optically targeted attacks on United States assets. This research has shown that optical
or directed energy systems can be rendered ineffective with clouds or dense fog. Clouds, rather
than “smart dust” or ablative particle methods result in a persistent, regenerative defense against
DEW. Advances in technology are beginning to bring weather phenomena more completely
under our control. Current capabilities such as 4d-VAR computer modeling enable the
establishment and design of a cloud system. Small diamond nano-skinned balloons allow the
measurement and delivery devices to become elements of the weather system, removing closedloop control response lag time. Nanotechnology allows these balloons to maneuver and network
within and from the atmospheric system. Finally, nanotechnology facilitates the basic functions
of measuring and changing critical variables required for weather control operations.
Concepts not covered in this research include the logistics of manning and operating a
weather control system. Studying the requirements to support the span of technological systems
and broad physical area will be necessary as weather control becomes a reality. The
vulnerability or exploitive possibilities of the system can be analyzed in the process of
developing tactics, techniques and procedures (TTPs) as with any major weapon system.
Defense of a weather control system requires more specific details on the subsystems to be of
use. Although described as a defensive measure in this project, the author fully realizes a wide
spectrum of possible weather control applications. While conducting the environmental scan for
this project many experts highlighted dangerous second and third order effects along with
international opinion and law in regards to weather modification. In order to sustain a weather
shield, other areas will have prolonged periods of perturbations. Although not a direct area of
this particular paper, potential chain reactions and affects outside the specific area must be
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considered an implemented into the Weather Operations Plan (WOP). The most important
recommendation is to begin monitoring and preparation for weather control technology.
Weather operators and organizations in the USAF need to monitor the technologies linked in this
discussion. As the capabilities converge, USAF organizations may be the key to engaging,
organizing and implementing the defensive use of weather control.
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Appendix A: Concept Weather Control Relevance Tree
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Appendix B: Component Relevance Tree
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Appendix C: Acronym List
3d-Var – Three dimensional variation
4d-Var- Four dimensional variation
AGL – Above Ground Level
AAA – Anti-Aircraft Artillery
ANTS- Autonomous NanoTechnology Swarm
AOR- Area Of Regard
ART – Addressable Reconfigurable Technology
C2 – Command and Control
CFACC – Combined Forces Air Component Commander
CPU – Central Processing Unit
DE – Directed Energy
DEW – Directed Energy Weapon
DOD – Department of Defense
DWC – Defense Weather Command
EMP – Electro-Magnetic Pulse
FEBA – Forward Edge of the Battle Area
GHz - GigaHerz
HEL – High Energy Laser
HPM – High Power Microwave
IADS – Integrated Air Defense System
IR - InfraRed
ISR – Intelligence Surveillance and Reconnaissance
MSL – Mean Sea Level
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NOAA – National Oceanic and Atmospheric Administration
NCAR - National Center for Atmospheric Research
PEM – Proton Exchange Membrane
SAM – Surface to Air Missile
SME – Subject Matter Expert
TOF – Time of Fall or Time of Flight
TTP – Tactics, Techniques and Procedures
UAV – Unmanned Aerial Vehicle
USAF – United States Air Force
UV – Ultra Violet
WMA – Weather Modification Assocation
WOP – Weather Operations Plan
WRFM – Weather Research and Forcasting Model
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ENDNOTES
1
Geis, “Directed Energy Weapons On The Battlefield: A New Vision For 2025”, 1. 2 Author’s combat and planning.
3
Thill, “Penetrating The Ion Curtain: Implications of Directed Energy Integrated Air Defense
Systems in 2030”, 7.
4
Office of the Under Secretary of Defense for Acquisition, Technology and Logistics, Defense
Science Board Task Force on Directed Energy Weapons, 20.
5
National Research Council, Critical Issues In Weather Modification Research, 31-33.
6
National Research Council, Critical Issues In Weather Modification Research, 23.
7
William Langewieshe, “Stealing Weather,” 172.
8
Carlotti, “Two-point properties of atmospheric turbulence very close to the ground: Comparison
of a high resolution LES with theoretical models.”
9
Volkovitsky, Propigation of Intensive Laser Radiation in Clouds, 8. 10 Author’s experience with F-16 optical and IR targeting systems
11 http://www.satimagingcorp.com/satellite-sensors/geoeye-1.html
12 http://www.tech-faq.com/low-earth-orbit.shtml
13 http://www.satimagingcorp.com/satellite-sensors/geoeye-1.html
14 Authors experience in the employment of UAV kinetic weapons
15 Geis, “Directed Energy Weapons On The Battlefield: A New Vision For 2025”, 1.
16 Defense Science Board Task Board Report on Directed Energy Weapons, Memorandum For
Chairman, Defense Science Board.
17 Thill, “Penetrating The Ion Curtain: Implications of Directed Energy Integrated Air Defense
Systems in 2030”, 12.
18 Thill, “Penetrating The Ion Curtain: Implications of Directed Energy Integrated Air Defense
Systems in 2030”, 10.
19 Volkovitsky, Propigation of Intensive Laser Radiation in Clouds, 301.
20 Volkovitsky, Propigation of Intensive Laser Radiation in Clouds, 18.
21 Defense Science Board Task Board Report on Directed Energy Weapons, p ix. 22 Thill, “Penetrating The Ion Curtain: Implications of Directed Energy Integrated Air Defense
Systems in 2030”, 9.
23 Mueller, “The Relative Effects of CW and RP Lasers on Composites and Metals,” 10, 13.
24 http://hyperphysics.phy-astr.gsu.edu/Hbase/phyopt/grating.html#c1
25 Reed, “Refraction of Light.” http://www.ps.missouri.edu/rickspage/refract/refraction.html
26 Volkovitsky, Propigation of Intensive Laser Radiation in Clouds, 16.
27 Thill, “Penetrating The Ion Curtain: Implications of Directed Energy Integrated Air Defense
Systems in 2030”, 37.
28 Allen, Uthe, “Tactical Considerations of Atmospheric Effects on Laser Propagation”, p 12.
29 Volkovitsky, Propigation of Intensive Laser Radiation in Clouds, 27.
30 Kopp, “Beam Propagation”, http://www.ausairpower.net/AADR-HEL-Dec-81.html.
31 Volkovitsky, Propigation of Intensive Laser Radiation in Clouds, 200. 32 HPM anti-personnel system demonstrated to Author while stationed at Moody AFB, GA.
33 Thill, “Penetrating The Ion Curtain: Implications of Directed Energy Integrated Air Defense
Systems in 2030”, 11.
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34 Defense Science Board Task Board Report on Directed Energy Weapons, Memorandum For
Chairman, Defense Science Board. p 35 – 36.
35 Thill, “Penetrating The Ion Curtain: Implications of Directed Energy Integrated Air Defense
Systems in 2030”, 10.
36 Narcisse, Air Force Weather Preparations to Support Directed Energy Weapons Across the
Department of Defense. p 9.
37 Thill, “Penetrating The Ion Curtain: Implications of Directed Energy Integrated Air Defense
Systems in 2030”, 10.
38 Barry B. Coble, Benign Weather Modification, 9.
39 Lewis, “Controlling the Weather”
40 Howe, The Need For Increased Control of Weather Modification Activities, 23.
41 National Research Council, Critical Issues In Weather Modification Research, 17.
42 National Research Council, Critical Issues In Weather Modification Research, 18.
43 Garstang, “Weather Modification, Finding Common Ground.” 649-650.
44 Klemp and Skamarock, A Time-split Nonhydrostatic Atmospheric Model for Weather
Research and Forecasting Applications, p 2.
45 National Research Council, Critical Issues In Weather Modification Research, 46. 46 National Research Council, Critical Issues In Weather Modification Research, 30-33.
47 Garstang, “Weather Modification, Finding Common Ground”, 651.
48 Weather Research and Forecasting Model, http://www.wrf-model.org/index.php
49 “Final Report of the Technical Workshop on WRF-ESMF Convergence.” http://www.wrfmodel.org/wrfadmin/publications/WRF-ESMF-Convergence-Workshop.pdf.
50 Skamarock, A Time-split Nonhydrostatic Atmospheric Model for Weather Research and
Forecasting Applications, 4.
51 Correspondence with William Shamarock, National Center for Atmospheric Research, 8 Dec
2008.
52 Dr. Thomas DeFelice, Public Information Chairman of Weather Modification Association
(WMA), NOAA contract manager and expert witness for Joint Hearing by Senate
Subcommittee on Science & Space and Subcommittee on Disaster Prediction and
Prevention, November 10, 2005.
Mr. Peter Backlund, National Center for Atmospheric Research (National Science Foundation)
Director if Integrated Science Program and Research Relations
Dr. Ross Hoffman, Vice President, Research and Development of Atmospheric and
Evironmental Research Inc, formerly with the NASA Institute for Advanced Concepts
(NIAC).
Individual correspondence with six members of the Weather Modification Association. These
members range from two weather PhD University professors and current weather modification
industry representatives. Each member provided their inputs to both the concept and component
relevance trees in the appendix of this paper. Since the accomplishment of the relevance trees,
each of the six members independently requested that they not be directly associated with a
military paper based on discrete weather control.
53Hoffman, Controlling the Global Weather, 3. 54 Hoffman, Controlling the Global Weather, 4.
55 Hoffman, Controlling the Global Weather, 1. 56 Hoffman, Controlling the Global Weather, 6.
33
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57 Hoffman, Controlling the Global Weather, 3.
58 Hoffman, Controlling the Global Weather, 5.
59 Hoffman, Controlling the Global Weather, 3 and correspondence with Dr. Ross N. Hoffman.
60 Hall, “The Weather Machine: Nano-enabled Climate Control for the Earth”
61 Hall, “The Weather Machine: Nano-enabled Climate Control for the Earth”
“Nano-Lightning Cooling For Computers,” discussion of micro-scale ion-driven airflow,
http://www.azonano.com/news.asp?newsID=68
63 Ahmad, “Future Trends For Nanotechnology and the Application of Nanotechnology in Solar
Cells, Nanofibres, Sensors, Ultra Light Materials and Corrosion Prevention,”
http://www.azonano.com/Details.asp?ArticleID=1718
64 Kwok, “Felxible Nanoantenna Arrays Capture Abundant Solar Energy,”
http://www.eurekalert.org/pub_releases/2008-08/dnl-fna080808.php
65Hall, Nanofuture, What’s Next for Nanotechnology. 53. 66 Service, “TR10: NanRadio,” http://www.technologyreview.com/communications/20244/
67Hall,“The Weather Machine: Nano-enabled Climate Control for the Earth”
68 Correspondence with Dr. J. Storrs Hall.
69 Dressler, Self-Organization in Sensor and Actor Networks, 6. 70 Dressler, Self-Organization in Sensor and Actor Networks, 3. 71 Dressler, Self-Organization in Sensor and Actor Networks, 9. 72 Dressler, Self-Organization in Sensor and Actor Networks, 11,12. 73 Dressler, Self-Organization in Sensor and Actor Networks, 10.
74 http://ants.gsfc.nasa.gov/
75 http://ants.gsfc.nasa.gov/ArchandAI.html
76 Hall, Nanofuture, What’s Next for Nanotechnology, 86.
77 Correspondence with Dr. J. Storrs Hall
78 Chowdhury, “On-Chip Cooling by Superlattice-based Thin-film Thermoelectics,”
http://www.nature.com/nnano/journal/vaop/ncurrent/abs/nnano.2008.417.html
79 Correspondence with Dr. Ross N. Hoffman.
80 “Statement of Findings: Sizing Nanotechnology’s Value Chain,”
http://www.altassets.com/pdfs/sizingnanotechnologysvaluechain.pdf. 81 “Statement of Findings: Sizing Nanotechnology’s Value Chain,”
http://www.altassets.com/pdfs/sizingnanotechnologysvaluechain.pdf.
82 Correspondence with Dr. J. Storrs Hall
83 Roco, National Nanotechnoloy Initiative – Past, Present, and Future. 29.
84 Roco, National Nanotechnoloy Initiative – Past, Present, and Future. 29.
85 Roco, National Nanotechnoloy Initiative – Past, Present, and Future. 28.
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