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Subelement E3

RADIO WAVE PROPAGATION

Section E3C

Propagation prediction and reporting: radio horizon; effects of space-weather phenomena

What is the cause of short-term radio blackouts?

  • Coronal mass ejections
  • Sunspots on the solar equator
  • North-oriented interplanetary magnetic field
  • Correct Answer
    Solar flares
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What is indicated by a rising A-index or K-index?

  • Correct Answer
    Increasing disturbance of the geomagnetic field
  • Decreasing disturbance of the geomagnetic field
  • Higher levels of solar UV radiation
  • An increase in the critical frequency

A and K indices are about the level of activity in the geomagnetic field. If the indices are increasing so are the disturbances in the geomagnetic field.

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Which of the following signal paths is most likely to experience high levels of absorption when the A-index or K-index is elevated?

  • Transequatorial
  • Correct Answer
    Through the auroral oval
  • Sporadic-E
  • NVIS

Think of the magnetic fields of Earth being concentrated at the North and South poles. So if there's a magnetic disruption, you'd expect it to effect the magnetic poles the most... therefore "polar paths."

An additional memory tool is to look at the "A" and "K" indexes from the question. AK = Alaska, Alaska has Polar Bears...Polar Paths.

Cheat: “Elevated -> North -> Polar

"K"londikebar->"Polar"(bear)

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What does the value of Bz (B sub z) represent?

  • Geomagnetic field stability
  • Critical frequency for vertical transmissions
  • Correct Answer
    North-south strength of the interplanetary magnetic field
  • Duration of long-delayed echoes

The interplanetary magnetic field (IMF) is that part of the sun's magnetic field which is spread throughout the solar system by solar wind. \(B_Z\) describes the component of the IMF's direction and strength most relevant to space weather, and thus to radio.

\[Explanation.\]

In physics, the symbol B is used to denote a magnetic field. Field strength is often described as a three-dimensional vector with \(x\), \(y\), and \(z\) components. In the case of the IMF, the axes are oriented such that \(x\) points from the Earth to the sun, \(y\) is in the plane of the ecliptic tangent to the Earth's orbit, and \(z\) is perpendicular to both*, roughly along the Earth's magnetic axis from north to south.**

Normally, the Earth's magnetosphere repels most of the energy from the solar wind, which prevents our atmosphere from blowing away.*** But when \(B_Z\) tends southward, the polarity of the sun's magnetic field is opposite Earth's, which allows the two fields to connect rather than repulse each other.

When this happens during solar storms (and particularly coronal mass ejections), large amounts of energy from the solar wind may transfer along these connections and even temporarily reconfigure the Earth's magnetosphere, leading to many dramatic and disruptive phenomena including aurora and geomagnetic storms.

Further reading (with diagrams): http://blog.aurorasaurus.org/?p=178

* This is the Geocentric Solar Magnetospheric coordinate system (GSM).
** Technically \(B_Z\) points toward the "ecliptic pole."
*** This is what happened to Mars.

Hint: Buzz Lightyear protects the planets.

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What orientation of Bz (B sub z) increases the likelihood that charged particles from the Sun will cause disturbed conditions?

  • Correct Answer
    Southward
  • Northward
  • Eastward
  • Westward

The orientation of the magnetic field in a coronal mass ejection from the Sun is a huge factor in determining the strength of the event's effects here at Earth.

When coronal mass ejections occur on the Sun, a huge amount of energy is released from violent reconfigurations of the complex magnetic field surrounding the star. These events cause high energy charged particles to stream outwards from the sun's outer atmosphere, or corona, into the solar system. Since the particles are charged, they carry with them magnetic field perturbations as they move outwards that are partially (but not completely) reflective of the conditions at the sun when they were released.

If the CME's particles encounter Earth, we have a geomagnetic storm. One of the biggest regulators of the strength of effects of the particles on our magnetosphere and ionosphere is in the Z orientation (\(+\) = toward our north pole, \(-\) = toward our south pole) of the disturbance's magnetic field. That Z orientation is labeled as Bz.

If \(B_Z\) is southward in the incoming particle cloud, this is opposite to our Earth's normal magnetic field -- think of a bar magnet repelling a magnet with opposite polarity. In this case, the CME-associated Bz then pushes on the Earth's magnetic field and compresses it, dumping energy into the magnetosphere. The energy input can lead to oscillations in the magnetic field as the Earth 'fights back'.

Since the ionosphere is tightly bound to the background magnetic field lines, it too begins to move and oscillate, quickly developing lots of irregularities, scintillation, and other structures that degrade long-distance HF propagation. This is why Bz is a key factor in determining geomagnetic storm strength at Earth.


[FYI, NASA maintains spacecraft monitors just upstream of earth -- the Advanced Composition Explorer (ACE) and the new DSCOVR satellite -- that have comprehensive space environment monitors, and one of the key variables measured there is the orientation of B.]

-adamlein


Think: When things "go south," something bad is happening.

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How does the VHF/UHF radio horizon compare to the geographic horizon?

  • Correct Answer
    It is approximately 15 percent farther
  • It is approximately 20 percent nearer
  • It is approximately 50 percent farther
  • They are approximately the same

VHF and UHF have a relatively short range due to the fact that the high frequencies can't get bent by the atmosphere very much, which makes the range about seeing distance.

You can then guess that the radio waves will extend only slightly farther than the horizon, about 15% more than that distance.

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Which of the following indicates the greatest solar flare intensity?

  • Class A
  • Class Z
  • Class M
  • Correct Answer
    Class X

Solar flares are ranked A, B, C, M, and X with "A" being the lowest and "X" the highest. Intensity increases in alphabetic order. After X it goes X1, X2, X3, etc. The highest-rated solar flare ever was an X26 in 1859

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Which of the following is the space-weather term for an extreme geomagnetic storm?

  • B9
  • X5
  • M9
  • Correct Answer
    G5
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What type of data is reported by amateur radio propagation reporting networks?

  • Solar flux
  • Electric field intensity
  • Magnetic declination
  • Correct Answer
    Digital-mode and CW signals
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What does the 304A solar parameter measure?

  • The ratio of X-ray flux to radio flux, correlated to sunspot number
  • Correct Answer
    UV emissions at 304 angstroms, correlated to the solar flux index
  • The solar wind velocity at an angle of 304 degrees from the solar equator, correlated to geomagnetic storms
  • The solar emission at 304 GHz, correlated to X-ray flare levels

304A can be thought of as 304 Å (Angstroms). The word angstroms only occurs in the correct answer: UV emissions at 304 angstroms, correlated to solar flux index.

But what is the Solar Flux Index, and what does it have to do with Ultraviolet Light at 304 Å?

Solar Flux Index (SFI) is measured in solar flux units (SFUs). SFI is defined as the amount of flux (radio noise) emitted at 2800 MHz. Because 2800 MHz correlates with a wavelength of 10.7 cm, it is also referred to as the 10.7 cm Flux Index.

An ångström or angstrom unit (Symbol: Å or A) is a unit of length equal to 10–10 meters, used principally to express the wavelengths of electromagnetic radiation. It is named after Swedish physicist Anders Jonas Ångström.

This problem refers to λ = 304 Å = 30.4 nm.

The 304A Index, often shortened to just 304A, is a

"NOAA reported value from 0 to unknown. Indicates relative strength of total solar radiation at a wavelength of 304 angstroms (or 30.4 nm), emitted primarily by ionized helium in the sun's photosphere. Two measurements are available for this parameter, one measured by the Solar Dynamics Observatory, using the EVE instrument, and the other, using data from the SOHO satellite, using its SEM instrument. Responsible for about half of all the ionization of the F layer in the ionosphere. 304A looseley correlates to SFI. The background level - at solar minimums - will typically be around 134, and at solar maxima can exceed 200 or more. Updated hourly."

HINT: Think A for Angstroms "304 Å (Angstroms)" in the question.

Additional references:

http://adsabs.harvard.edu/full/1997ESASP.404..439J

https://www.arrl.org/files/file/Technology/tis/info/pdf/0209038.pdf

https://en.wikipedia.org/wiki/Noise_(radio)

http://www.qsl.net/w2vtm/hf_solar.html

http://www.voacap.com/ctu/propagation-ctu-en.pdf

https://www.electronics-notes.com/articles/antennas-propagation/ionospheric/solar-indices-flux-a-ap-k-kp.php

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What does VOACAP software model?

  • AC voltage and impedance
  • VHF radio propagation
  • Correct Answer
    HF propagation
  • AC current and impedance

VOACAP stands for Voice of America Coverage Analysis Program. It is used to predict HF propagation.

VOA is the clue contained in the question. As a shortwave broadcast operation, HF propagation would be the one thing they might be most interested in.

See HF predictions map.

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Which of the following is indicated by a sudden rise in radio background noise across a large portion of the HF spectrum?

  • A temperature inversion has occurred
  • Correct Answer
    A coronal mass ejection impact or a solar flare has occurred
  • Transequatorial propagation on 6 meters is likely
  • Long-path propagation on the higher HF bands is likely

Solar flares cause a sudden rise in background noise. So, if you detect a sudden rise in radio background noise, it might have been caused by a solar flare.

Silly way to remember:

voices rise as tempers flare

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