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Product: 3-Day Forecast
- Issued: 2024 Nov 21 0030 UTC
Prepared by the U.S. Dept. of Commerce, NOAA, Space Weather Prediction Center.
The greatest observed 3 hr Kp over the past 24 hours was 3 (below NOAA Scale levels). The greatest expected 3 hr Kp for Nov 21-Nov 23 2024 is 3.00 (below NOAA Scale levels).
Nov 21 | Nov 22 | Nov 23 | |
---|---|---|---|
00-03UT | 1.67 | 2.00 | 2.33 |
03-06UT | 1.33 | 1.67 | 3.00 |
06-09UT | 1.33 | 2.33 | 2.33 |
09-12UT | 1.33 | 1.00 | 2.00 |
12-15UT | 1.33 | 1.33 | 1.33 |
15-18UT | 1.33 | 1.67 | 1.33 |
18-21UT | 1.67 | 3.00 | 1.67 |
21-00UT | 1.67 | 3.00 | 2.33 |
Rationale: No G1 (Minor) or greater geomagnetic storms are expected. No significant transient or recurrent solar wind features are forecast.
Solar radiation, as observed by NOAA GOES-18 over the past 24 hours, was below S-scale storm level thresholds.
Nov 21 | Nov 22 | Nov 23 | |
---|---|---|---|
S1 or greater | 5% | 5% | 5% |
Rationale: No S1 (Minor) or greater solar radiation storms are expected. No significant active region activity favorable for radiation storm production is forecast.
Radio blackouts reaching the R1 levels were observed over the past 24 hours. The largest was at Nov 20 2024 1948 UTC.
Nov 21 | Nov 22 | Nov 23 | |
---|---|---|---|
R1-R2 | 50% | 50% | 50% |
R3 or greater | 10% | 10% | 10% |
Rationale: Solar activity is expected to be low, with a chance for M-class flares (R1/R2-Minor/Moderate) and a slight chance of X-class (R3-Strong) events 21-23 Nov.
SOHO EIT 171 |
SOHO EIT 195 |
SOHO EIT 284 |
SOHO EIT 304 |
SDO/HMI Continuum |
SDO/HMI Magnetogram |
LASCO C2 |
LASCO C3 |
The sun is constantly monitored for sun spots and coronal mass ejections. EIT (Extreme ultraviolet Imaging Telescope) images the solar atmosphere at several wavelengths, and therefore, shows solar material at different temperatures. In the images taken at 304 Angstrom the bright material is at 60,000 to 80,000 degrees Kelvin. In those taken at 171 Angstrom, at 1 million degrees. 195 Angstrom images correspond to about 1.5 million Kelvin, 284 Angstrom to 2 million degrees. The hotter the temperature, the higher you look in the solar atmosphere.
Real-Time Solar Wind Real-Time Solar Wind data broadcast from NASA's ACE satellite. |
WSA-Enlil Solar Wind Prediction |
Move your cursor over the timeline to 'scrub' through the forecast. |
WSA-Enlil is a large-scale, physics-based prediction model of the heliosphere, used by the Space Weather Forecast Office to provide 1-4 day advance warning of solar wind structures and Earth-directed coronal mass ejections (CMEs) that cause geomagnetic storms. Solar disturbances have long been known to disrupt communications, wreak havoc with geomagnetic systems, and to pose dangers for satellite operations.
Sun Spot Number Progression |
F10.7cm Radio Flux Progression |
The Solar Cycle is observed by counting the frequency and placement of sunspots visible on the Sun. The forecast comes from the Solar Cycle Prediction Panel representing NOAA, NASA and the International Space Environmental Services (ISES). The Prediction Panel has predicted Cycle 25 to reach a maximum of 115 occurring in July, 2025.
Northern Hemi Auroral Map |
Southern Hemi Auroral Map |
Instruments on board the NOAA Polar-orbiting Operational Environmental Satellite (POES) continually monitor the power flux carried by the protons and electrons that produce aurora in the atmosphere. SWPC has developed a technique that uses the power flux observations obtained during a single pass of the satellite over a polar region (which takes about 25 minutes) to estimate the total power deposited in an entire polar region by these auroral particles. The power input estimate is converted to an auroral activity index that ranges from 1 to 10.
D-Region Absorption Prediction |
The D-Region Absorption Product addresses the operational impact of the solar X-ray flux and SEP events on HF radio communication. Long-range communications using high frequency (HF) radio waves (3 - 30 MHz) depend on reflection of the signals in the ionosphere. Radio waves are typically reflected near the peak of the F2 layer (~300 km altitude), but along the path to the F2 peak and back the radio wave signal suffers attenuation due to absorption by the intervening ionosphere. The D-Region Absorption Prediction model is used as guidance to understand the HF radio degradation and blackouts this can cause.
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with 3-day Solar-Geophysical Forecast text formatting by Jeremy Dyde of Jerbils Weather