{"id":800179,"date":"2026-01-19T06:56:30","date_gmt":"2026-01-19T11:56:30","guid":{"rendered":"https:\/\/spaceweekly.com\/?p=800179"},"modified":"2026-01-19T06:56:30","modified_gmt":"2026-01-19T11:56:30","slug":"rare-s3-strong-solar-radiation-storm-in-progress-after-x1-9-flare-on-january-18","status":"publish","type":"post","link":"https:\/\/spaceweekly.com\/?p=800179","title":{"rendered":"Rare S3 – Strong solar radiation storm in progress after X1.9 flare on January 18"},"content":{"rendered":"


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Solar radiation storm produced by a long-duration X1.9 solar flare from Active Region 4341 on January 18 reached S3 \u2013 Strong levels at 10:20 UTC on January 19 after the \u226510 MeV proton flux exceeded 1 000 pfu.<\/p>\n

The flare peaked at 18:09 UTC on January 18 and was accompanied by Type II and Type IV radio emissions, a 3 200 sfu F10.7 radio burst with a Castelli-U signature, and a full-halo coronal mass ejection first observed in coronagraph imagery at approximately 18:30 UTC. The CME is expected to impact Earth on January 20.<\/p>\n

Proton flux levels initially crossed the S1 \u2013 Minor threshold at 22:55 UTC on January 18, exceeded S2 \u2013 Moderate levels early on January 19, and continued rising steadily through the morning hours. At 10:20 UTC, \u226510 MeV protons surpassed 1 000 pfu, triggering an S3 alert issued at 10:29 UTC.<\/p>\n

GOES-18 proton data show sustained increases across multiple energy channels, indicating an ongoing and well-developed solar energetic particle event. Elevated \u226550 MeV proton flux has also been observed, confirming the high-energy nature of the storm.<\/p>\n

At S3 intensity, increased radiation exposure is possible for passengers and crew on high-latitude, high-altitude flights, while astronauts conducting extravehicular activities are exposed to significantly elevated radiation levels. Satellite systems may experience single-event upsets, noise in imaging sensors, and minor reductions in solar panel efficiency. Polar high-frequency radio propagation may become degraded or experience intermittent blackouts.<\/p>\n

Solar radiation storms of S3 \u2013 Strong intensity are relatively rare space weather events. Based on long-term NOAA statistics, only a limited number of such storms usually occur during a full 11-year solar cycle, as they require efficient particle acceleration by strong solar eruptions and CME-driven shocks.<\/p>\n

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GOES Proton Flux rises following X1.9 solar flare on January 18, 2026. Credit: SWPC<\/figcaption><\/figure>\n<\/div>\n
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