Embodiments are generally related to radiation protection. Embodiments also relate to protecting an electronic component against space environment radiations. Embodiments additionally relate to a system and method for reducing energetic proton flux, trapped in the inner radiation belt by injecting Ultra Low Frequency (ULF) electromagnetic waves. Embodiments additionally relate to a system and method for reducing energetic electron flux enhancements in the gap and inner belt caused by natural solar storms or High Altitude Nuclear Explosions (HANE).
The structure and behavior of the energetic electrons and protons trapped in Earth's Radiation Belt (RB) has been the subject of numerous experimental and theoretical studies. Morphologically, two regions are distinguished in the magnetosphere: (i) an inner RB for L shells lower than two and (ii) a gap and an outer RB for L shells higher than two. The inner RB is dominated by protons with energy in excess of 10 MeV and lifetimes from a few years at low altitudes of 400 to 500 km to many tens of years at higher altitudes. Overall the inner belt energetic protons are relatively stable with a typical lifetime of ten years. Contrary to this, the outer RB is very dynamic and dominated by energetic electron fluxes associated with solar events and space weather process. The gap is characterized by low energetic electron flux providing a beneficial environment for the function of satellites.
Earth's inner radiation belt located inside L=2 is dominated by a relatively stable flux of trapped protons with energy from a few to over 100 MeV. Radiation effects in spacecraft electronics caused by the inner radiation belt protons are the major cause of performance anomalies and lifetime of Low Earth Orbit satellites. For electronic components with large feature size, of the order of a micron, anomalies occur mainly when crossing the South Atlantic Anomaly (SAA). However, current and future commercial electronic systems are incorporating components with submicron size features. Such systems cannot function in the presence of the trapped 30 to 100 MeV protons, as hardening against such high-energy protons is essentially impractical.
Low Earth Orbiting (LEO) satellites spend a significant part of their orbit in the inner RB that is populated by energetic protons with energy, from one to more than one hundred MeV. The interaction of energetic protons with electronic devices of modern spacecraft results in high rates of anomalies due to Single Event Effects (SEE). Such anomalies range from nuisance effects that require operator intervention to debilitating effects leading to functional or total loss of the spacecraft. A set of operational problems occur when protons deposit enough charge in a small volume of silicon to change the state of memory cell, so that a one becomes zero and vice versa. The memories can become corrupted and lead to erroneous commands. Such soft errors are referred to as Single Event Upsets (SEU) and often generate high background counts to render the sensor unusable. Sometimes a single proton can upset more than one bit giving rise to Multiple Bit Upsets (MBU). Some devices can be triggered into a high current drain, leading to burn-out and hardware failure, known as single event latch-up or burn-out. Other devices suffer dielectric breakdown and rupture.
For LEO satellites, the dominant source of proton influence is the South Atlantic Anomaly (SAA). The SAA is a localized region at a fixed altitude, where protons in the inner RB reach their maximum intensity as a result of the asymmetry of the Earth's magnetic field that can be approximated by a tilted, offset dipole in the inner magnetosphere. At present, satellites with micron size Commercial-Off-The Shelf (COTS) electronics experience serious effects mainly when transiting the SM. For example, the intolerable frequency of SEU of the IBM 603 microprocessors (5 micron CMOS) in Iridium forced Motorola to disable the cache while transiting the SAA. Similar anomalies were experienced by the Hubble Space Telescope and numerous other satellites. To mitigate such effects, spacecraft utilize shielded electronic components that can reduce the flux of protons with energy below few MeV. However, it is very hard to shield against proton fluxes with energy in excess of 20 to 30 MeV.
The severity of the environment is usually expressed as an integral linear energy transfer spectrum, that represents the flux of particles depositing more than a certain amount of energy and charge per unit length of the material. This is referred as Linear Energy Transfer (LET), and given in units of MeV per g/cm2 or per mg/cm2. The effect on devices is characterized as a cross section (effective area presented to a beam), that is a function of the LET. The frequency of SEU caused by energetic protons is a non-linear function of the feature size. For large feature sizes, SEU are due to charge deposition caused by secondary particles with higher LET. For feature sizes smaller than 90 nm, direct proton ionization can cause SEU, resulting in an increase of the frequency of proton SEU by two or more orders of magnitude for deep submicron devices. This could preclude their use even for orbit latitudes different than the SAA. Further hardening the microelectronic components, besides the added weight, is very ineffective for proton energies higher than 20 to 30 MeV. For example, even one inch of Al reduces the 60-80 MeV flux by less than a factor of three. The recent tests have shown that the SEU cross section for energies between 1 to 10 MeV for bulk 65 nm Complementary Metal Oxide Semiconductor (CMOS) technology is by two orders of magnitude higher than for micron size devices, rendering current shielding level inadequate even at low proton energies.
Use of COTS in space applications is dictated by their high volume production and wide-spread, use. The high volume production drives down their recurring component costs because of high yields and economies of scale. The wide-spread use of COTS reduces the system cost. Furthermore open standards drive down development and life-time support costs reduce the time to market for new products. The SEE issue for submicron CMOS or other electronic components presents a major dilemma, since it will prohibit use of COTS circuits with sub-micron size features and will limit the use of micro-satellites at LEO orbits.
Thus it is difficult to shield against 30 to 100 Mev protons to the level required by sub-micron features of current and future commercial electronic components. Heavy weight penalty must be paid to effect such shielding. Therefore, it is believed that a need exists for an improved system and method for reducing the energetic proton flux trapped in the inner radiation belt. Such system and method should allow the use of commercial electronics with submicron feature size on Low Earth Orbit (LEO) satellites and microsatellites without the operational constraints imposed by the presence of energetic proton fluxes trapped at the inner radiation belts.
Under natural conditions the flux of energetic electrons with MeV energies in the gap is relatively low and does not affect significantly the performance and lifetime of satellites at LEO and MEO orbits. This is not however the case following an accidental or deliberate High Altitude Nuclear Explosion (HANE). Nuclear tests conducted by the US and the USSR in the early sixties indicated that following HANE the flux, of energetic electrons increases by more than a factor of 1000 and remains trapped over times of several years. It is therefore believed that a system that can reduce the flux of energetic electrons injected in the RB following HANE is urgently needed. Such a system will bring the flux of the trapped energetic electrons to their natural level in timescales of order of days or weeks thereby allowing the proper functioning of LEO and (CEO satellites.
The following summary is provided to facilitate an understanding of some of the innovative features unique to the disclosed embodiment and is not intended to be a full description. A full appreciation of the various aspects of the embodiments disclosed herein can be gained by taking the entire specification, claims, drawings, and abstract as a whole.
It is, therefore, one aspect of the disclosed embodiments to provide for radiation protection.
It is another aspect of the disclosed embodiments to provide for protecting an electronic component against space environment radiations.
It is a further aspect of the present invention to provide for a system and method for reducing energetic particle flux trapped in the inner radiation belt and gap by injecting Ultra Low Frequency (ULF) electromagnetic waves.
It is yet another aspect of the present invention to provide for a system and method for reducing energetic electron flux enhancements in the gap and inner belt caused by natural solar storms or High Altitude Nuclear Explosions (HANE).
It is a another aspect of the present invention to provide for a system and method that allows the use of commercial electronics with submicron feature size on Low Earth Orbit (LEO) satellites and microsatellites without the operational constraints imposed by the presence of energetic proton fluxes trapped at the inner radiation belts.
It is a yet another aspect of the present invention to provide for a system and method for reducing energetic proton flux trapped in the inner radiation belt by injecting ULF electromagnetic waves into LEO and selecting ULF frequency range by ensuring that the injected waves are in gyrofrequency resonance with trapped 10 to 100 Mev protons and relativistic MeV electrons. The ULF electromagnetic waves can be generated by space or ground based transmitters.
According to the present invention, the energetic proton flux trapped in the inner radiation belt may be reduced by injecting Ultra-Low Frequency (ULF) electromagnetic waves, generated by space or ground based transmitters. The transmitted ULF frequency range is selected by the requirement that the injected waves are in gyrofrequency resonance with trapped 10 to 100 Mev protons and relativistic MeV electrons
Pitch angle scattering of the trapped particles in gyro-resonance with the injected waves increases their precipitation rate by forcing their orbits into pitch angles inside the atmospheric loss-cone and are lost by interacting with the dense neutral atmosphere at altitudes below 100 km. Efficient techniques for generating and injecting the required ULF power include Horizontal Electric Dipole (HED) transmitters, Rotating Magnetic Fields (RMF) using arrays of permanent or superconducting magnets and Transient Horizontal Electric Dipole Transmitters (THED). The particle flux reduction can be efficiently accomplished by using ground based arrays of permanent or superconducting magnets rotating at the selected ULF frequencies.
The present invention allow the use of COTS micro-electronic circuits with sub-micron features aboard LEO satellites and micro-satellites, reduce the current shielding weight and increase the useful lifetime of LEO satellites. The invention is based on the recognition that, the rate of SEU and other anomalies of electronic circuits aboard LEO satellites as well as the lifetime limitations are predominantly a function of the trapped proton flux in the 30 to 100 MeV energy range and relativistic MeV electrons. The SEU and electronic circuit anomaly issue will be resolved by providing techniques that will reduce the trapped energetic particle flux encountered by LEO satellites.
The aforementioned aspects and other objectives and advantages can now be achieved as described herein. A system and method for improving the survivability of space systems following a High Altitude Nuclear Explosion (HANE) incident resulting in energetic electrons being trapped in the inner radiation belt of Earth is disclosed. The ULF electromagnetic waves are generated by space or ground based transmitters and the frequency range is selected such that the injected waves are in gyrofrequency resonance with trapped energetic particles. The Radiation Belt Remediation (RBR) depends on the wave-number of the injected waves and the wave-number of the injected waves increases along their propagation path when they approach the cyclotron frequency of the dominant or minority ions 0+, He+ and H+.
The accompanying figures, in which like reference numerals refer to identical or functionally-similar elements throughout the separate views and which are incorporated in and form a part of the specification, further illustrate the disclosed embodiments and, together with the detailed description of the invention, serve to explain the principles of the disclosed embodiments.
a illustrates a graph showing variation of omni-directional proton flux above 10 MeV and 50 MeV energies as a function of the L value;
b illustrates a graph showing differential spectrum of inner RB protons;
a illustrates a map showing a radiation flux at the SAA at altitude 400 km;
b illustrates a map showing geographical distribution of SEU in nMOS DRAms on UoSAT-2 showing clustering of proton events in the SAA;
a and 5b illustrate graphs showing time variation of 55 MeV proton flux and their redistribution caused by the Starfish nuclear test;
a illustrates an apparatus for injecting ULF in the Radiation Belts using Horizontal Electric Dipole (HED), in accordance with the disclosed embodiments;
b illustrates an apparatus for injecting ULF waves in the Radiation Belts using Rotating Magnetic Field (RMF) antennas, in accordance with the disclosed embodiments;
a illustrates a graph showing ground response time as a function of antenna length and ground conductivity, in accordance with the disclosed embodiments;
b and
The particular values and configurations discussed in these non-limiting examples can be varied and are cited merely to illustrate at least one embodiment and are not intended to limit the scope thereof.
Radiation Belts (RB), also known as Van-Allen belts, are the locus of energetic electron and protons trapped by the Earth's magnetic field. It is customary and convenient to describe a given magnetic field line by its L value. The L value corresponds to the radial location of its intersection with the magnetic equator in units of Earth radius (RE).
The inner RB dominated by the presence of trapped energetic protons is shown in
a illustrates a map 300 showing a radiation flux in the SAA at altitude 400 km and
The large gradient of proton flux at the boundary between the inner and outer RB can be explained using the simplified “leaky-bucket” model. According to this model, the average proton flux at a particular L shell and energy is given by balancing the source of the energetic protons, such as Cosmic-Ray Neutron Albedo Decay (CRAND), to their loss to the atmosphere by processes such as inelastic nuclear collisions and slowing down by collisions with atomic oxygen at low altitude. The loss time T of a proton with energy E is controlled by the rate of energy degradation by collisional interactions with atomic oxygen and is given by the approximate formula,
T≈2×104(E/MeV)1.3(#/cm3/<ρ>)years Equation 1
where <ρ> is the atomic electron density averaged over a proton orbit. The mean atmospheric density encountered by Re protons (atomic electrons per cm3) averaged over solar cycle in a B-L map 400 as computed by Cornwall et al. (1965) is shown in
The dilemma occurs when similar considerations are applied to the outer RBs and compared with the results as shown in
A particularly hazardous for the survival of space systems situation arises if a nuclear device is detonated above the atmosphere (i.e. above 100 km altitude). In this case a large number of energetic electrons (Energy>1 MeV) are injected into the radiation belts due to beta decay of the radioactive fragments. Depending on the L-shell, altitude, and yield of the device the beta decay electrons can stay trapped for weeks, months and even years, creating an enhanced radiation environment. In fact during the Starfish HANE in 1962 the relativistic electron flux increased by a factor of more than 100 over the natural one and stayed above its natural value for several years. As estimated by the Defense Threat Reduction Agency the flux of relativistic electrons increases by more than a factor of 1000 for a hypothetical 10 kT HANE at 150 km over Korea. The same analysis predicts that the number of functioning satellites at LEO will be reduced by more than an order of magnitude within a few weeks. The important aspect is the fact that the satellites will survive if the newly injected relativistic electrons were forced to precipitate on a time shorter than one to two weeks. The techniques for achieving this task known as RBR rely on injection of whistler waves with frequency of kHz, a frequency region that has serious efficiency problems. The current invention relies in achieving RBR by using the same ULF frequency waves that can be used for the protons and the system that addresses PRBR can be used for RBR. We refer to this function of the system as the Low Frequency RBR (LFRBR).
The LFRBR concept relies on the fact that for low frequency waves resonance with energetic electrons depends only on the wave-number kz of the injected waves and although the low frequency waves initially injected have much smaller kz values than required, the wave-number of the injected waves increases along their propagation path when they approach the cyclotron frequency of the dominant or minority ions (O+, He+, H+).
A schematic drawing of the Proton Radiation Belt Remediation (PRBR) system 600 is illustrated in
Neglecting relativistic effects and concentrating on the primary resonance, energetic protons interact with SAW when the Doppler shifted wave frequency ω seen in the reference frame of the energetic proton is equal to its gyro-frequency Ω namely,
ω−kzνz=−Ω Equation 2
In Equation 2, kz is the wave-number in the magnetic field direction. Assuming ω<<Ω, and using the dispersion relation of SAW, with VA as the Alfven speed, as
ω=kzVA Equation 3
The protons velocity v and pitch angle α, resonate with SAW when
Equation 4 can be re-defined to obtain the minimum frequency required to interact with protons outside the loss cone angle αL of energy E, as
where M is the proton mass.
Computation of the scattering rate and proton lifetime in the presence of a given SAW spectrum requires a couple of relatively complex but otherwise standard computations. The first is to follow textbook procedure (Lyons and Williams, 1984) to calculate the pitch angle diffusion coefficient as a function of the SAW spectrum and amplitude for the energy range of interest. The second is to determine the effective diffusion coefficient by averaging over the bounce and azimuthal orbit. This gives the effective diffusion coefficient as a function of the SAW amplitude <δB>. It is important to emphasize that, this is the average amplitude that a proton sees when it completes its entire orbit. The results are the same, if the waves concentrated in a small azimuthal shell with higher amplitude or if the waves uniformly distribute over the azimuth. Finally the lifetime is computed as discussed in Lyons and Williams (1984), by solving the bounced averaged pitch angle diffusion equation as an eigen-value problem. The details of this analysis can be found in Shao et al. (2009).
Table 1 shows the proton lifetimes in the presence of SAW with average amplitude 25 pT for selected injection frequencies and proton energies. Notice that the diffusion rate as well as the lifetime scale as the square of the SAW amplitude.
Two factors affect the energy-power required to accomplish a desirable remediation. The first is obviously the size of the region in units of δL. The second is the SAW confinement time that in its turn depends on the reflection coefficient R of the SAW from the ionosphere. The results per δL=0.1 is expressed as a function of the reflection coefficient R. Considering the region of L=1.5, the volume is given approximately by 3×1020(δL/0.1)m3. Therefore, to achieve the lifetimes referred to in Table 1 the volume should contain a total energy of 75 kJ in SAW.
When SAW trapping region is treated as a leaky cavity, then
Where W is the SAW energy, P the injected power and ν is the energy loss rate. The energy loss rate due to transmission at the ionospheric boundary is ν=−InR/To, where R is the reflection coefficient at the ionospheric boundary and To is the Alfven wave transit time along the magnetic field line.
The LFRBR system schematic is similar to the one shown in
ω−kzνz=−Ωe/γ Equation 7
For ω<<Ωe the above equation becomes
kz=Ωe/γνz Equation 8
ULF waves injected as SAW satisfying Equation 3 do not satisfy the resonance condition of Equation 8 for relativistic MeV electrons when they are first injected near the bottom of the field line. However for waves with frequency dose to the ion cyclotron frequency of Oxygen or one the minority species at some point along their propagation path towards the conjugate kz changes and reaches a value that satisfies the resonance condition of Equation 8 for electrons with energies 1-2 MeV such as injected by a HANE. These waves are called Electro-Magnetic Ion Cyclotron (EMIC) waves.
The basic PRBR and LFRBR system 600 concept illustrated in
HED system is similar to traditional ELF transmitters that are used for submarine communications such as the FELF system located in Michigan. Greifinger examined a similar system for lateral injection of ULF signals in the Earth-ionosphere or the Alfvenic waveguide.
In HED system, antenna can be utilized to inject SAW upwards through the lower ionosphere along the magnetic field lines as illustrated in
Z(h) is the impedance at the bottom of the ionosphere and σP(h) is the corresponding Pedersen conductivity. Note that the electric and magnetic fields are driven by two anti-parallel currents such as antenna current and image current, separated by the skin depth distance 8, assuming δ<<L. From Equations 9 and 10, the power density injected in the ionosphere by a HED with dipole moment IL at a frequency f is thus given by
S=Z0(1/√{square root over (1+ρP(h)/iω∈)})(IL/4πh2)2(δ/h)2 Equation 11
Where Z0=120π is the impedance of free space. Taking the approximate area at an altitude h as h2, the injected power in the RB in practical units will be given by
P(z=h)≈α4(IL/3×104 A−km)2(75 km/h)4(δ/7 km)2 kW Equation 12
In Equation 12 α≈cos2 θ√{square root over (∈ω/ρP(h))} is the efficiency with which the power at the bottom of the ionosphere will couple to the SAW, if the angle that the Earth's magnetic field makes to the ground at the transmitter location is θ. Based on the fact that the ionospheric attenuation at few Hz frequencies is negligible and using nighttime conditions, the factor α is of order unity. As a zero order estimate, a HED with L≈10 to 15 km, and I=1 to 3 kA located on ground with conductivity approximately 10−4 S/m could in principle inject a few kW of power into the SAW mode required to achieve lifetime of the order of 2 to 3 years for 30 to 100 MeV trapped protons. In such a system the main loss is ohmic heating of the ground and overall efficiencies of the order or better than 10−3 can be achieved. The total ground power required is of the order of few MW.
An alternative system 850 that can inject SAW efficiently in the radiation belts is illustrated in
In practical units the power injected in SAW will be approximately
P≈α64(75 km/h)2(M/2×104 A−km2)2kW Equation 14
An advantage of the RMF system is its compactness and portability. For example, a superconducting magnet with 25 m2 area. Four hundred Ampere DC current and 105 turns has an approximate magnetic moment of 109 A-m2. Approximately twenty coils will be needed to get inject kilowatt level power. A further advantage of such a system is that it does not require low conductivity ground and can thus be located in any desirable location as well as it can be portable. For example it can be located in a barge or any platform such as of rig platforms.
THED systems which are similar to HED systems operate in transient mode with pulse length of the order of 0.1 to 1 seconds and can inject broadband waves in the desired frequency band. A significant advantage of such a system is that it can increase the injection efficiency of the steady state HED by as much as 20 dB by avoiding the effect of the magnetic field generated by the ground return current at the bottom of the ionosphere. This is accomplished by an innovative “sneak-through” operation part of the present invention.
a illustrates a graph 910 showing the ground response time as a function of antenna length and ground conductivity, similar to the L/R time of a circuit. Timescales of 0.1 to 1 seconds can be accomplished by a combination of antenna lengths in the few hundred meters for a range of ground conductivities.
S=Z0(1/√{square root over (1+σP(h)/iω∈)})(IL/4πh2)2 Equation 15
This is similar to Equation 11 but with the value of δ/h=1. This factor reduces the efficiency of the steady state HED by more than 15 to 20 dB. As seen in from
It will be appreciated that variations of the above disclosed and other features and functions, or alternatives thereof, may be desirably combined into many other different systems or applications. Also that various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art which are also intended to be encompassed by the following claims.
This Application is a Continuation-in-Part of U.S. Application Ser. No. 61/448,480 filed Mar. 2, 2011; and this application claims rights under 35 U.S.C. §119(e) from U.S. application Ser. No. 13/409,340 filed Mar. 1, 2012, the contents of both of which are incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
3866231 | Kelly | Feb 1975 | A |
4686604 | Gilman | Aug 1987 | A |
4999637 | Bass | Mar 1991 | A |
5041834 | Koert | Aug 1991 | A |
5053783 | Papadopoulos | Oct 1991 | A |
7197381 | Sheikh et al. | Mar 2007 | B2 |
7268517 | Rahmel et al. | Sep 2007 | B2 |
7627249 | Izadpanah | Dec 2009 | B1 |
20120223253 | Papadopoulos | Sep 2012 | A1 |
Number | Date | Country | |
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20130181145 A1 | Jul 2013 | US |
Number | Date | Country | |
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61448480 | Mar 2011 | US |
Number | Date | Country | |
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Parent | 13409340 | Mar 2012 | US |
Child | 13780363 | US |