Today’s Sun (artificially-colored in purple) seen at the...

Today’s Sun (artificially-colored in purple) seen at the 211-angstrom wavelength (Extreme Ultraviolet, or EUV), as viewed by the Solar Dynamics Observatory (SDO), by the Atmospheric Imaging Assembly (AIA).

At this wavelength, at a wavelength not seen by the un-aided eye, we observe this full-disk AIA image through the 21.1 nm (211 A) filter. This Extreme Ultraviolet (EUV) waveband is used to monitor active regions in the solar corona.

The image is a ‘false color image’, meaning that observed data are in a range outside of what human eyes can see, so the data are digitally recast into colors that emphasize physically important features. This view is created from data gathered by the Solar Dynamics Observatory (SDO) satellite that flies above Earth’s atmosphere in an inclined geosynchronous orbit.

Emissions captured in this image come from iron (Fe), a trace element in the solar atmosphere that emits Extreme Ultraviolet (EUV) light when heated to temperatures in excess of one million deg K. In the solar corona the temperatures are so high that most chemical elements have lost many of their electrons. Some of the remaining electrons still attached to the atom emit EUV radiation in narrow wavebands or lines.

The 21.1 nm filter (also called channel or bandpass) is dominated by emissions from highly ionized iron: 13 times ionized (missing 13 electrons) iron–Fe XIV. Other ionization levels of iron also contribute. The roman numeral descriptors are consistent with spectral notation: the level of ionization for a given roman numeral is one unit larger that the actual number of missing electrons. Additionally there may be some contribution from hot thermal plasma when solar flares are present. The temperatures associated with this level of ionization is about 2 x 10^6 K.

The bright regions in this image correspond to regions of closed magnetic field loops that trap the hot, emitting plasma. Large bright regions are often called active regions. The dark regions correspond to cooler temperatures and possibly to locations where magnetic field lines open into the heliosphere, and thus, do not trap hot plasma.

With this image, we can monitore active regions.

View live data and images at http://SunSpotWatch.com

We’re on Facebook: http://NW7US.us/swhfr

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Latest TEC map from NASA. What is TEC? Total Electron Content...

Latest TEC map from NASA. What is TEC? Total Electron Content (or TEC) is an important descriptive quantity for the ionosphere of the Earth. TEC is the total number of free electrons integrated between two points, along a tube of one meter squared cross section, i.e., the electron columnar number density. Affected by solar activity, Total Electron Content (TEC) describes the total number of free electrons present within one square meter between two points (i.e. between the receiver and satellite involved in measuring TEC).

These maps are also used to monitor ionospheric weather, and to nowcast ionospheric storms that often occur responding to activities in solar wind and Earth’s magnetosphere as well as thermosphere.

View live data and images at http://SunSpotWatch.com

Follow: http://ift.tt/1iWH4ta and http://ift.tt/1wJXm19

Facebook: http://NW7US.us/swhfr

And: Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

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Monthly DX Report 01.06.2017 - 30.06.2017

Monthly DX Report 01.06.2017 - 30.06.2017

Today’s Sun (artificially-colored in red) seen at the...

Today’s Sun (artificially-colored in red) seen at the 304-angstrom wavelength (Extreme Ultraviolet, or EUV), as viewed by the Solar Dynamics Observatory (SDO), by the Atmospheric Imaging Assembly (AIA).

At this wavelength, at a wavelength not seen by the un-aided eye, we can see the Sun through the 30.4 nm (304 A) filter. This Extreme Ultraviolet (EUV) waveband is used to monitor the chromosphere and lower transition region. It is useful to see plasma and filament activity, including filamet eruptions and coronal mass ejections (CMEs).

The image is a “false color image’, meaning that observed data are in a range outside of what human eyes can see, so the data are digitally recast into colors that emphasize physically important features. This view is created from data gathered by the Solar Dynamics Observatory (SDO) satellite that flies above Earth’s atmosphere in an inclined geosynchronous orbit.

Emissions captured in this image come from helium (He), the second most abundant element in the solar atmosphere. Singly ionized Helium (He II) emits Extreme Ultraviolet (EUV) light when heated to temperatures of ~70,000 deg K. In the upper solar atmosphere the temperatures are so high that most chemical elements have lost many of their electrons. The remaining electron, which is still attached to the atom, emits EUV radiation in narrow wavebands or lines when it is in an excited state.

The 30.4 nm filter (also called channel or bandpass) is dominated by emissions from singly (once) ionized helium which has missing 1 electron–He II. The roman numeral descriptor is consistent with spectral notation: the level of ionization for a given roman numeral is one unit larger that the actual number of missing electrons. The temperatures associated with this level of ionization is range from 6 x 10^4 K to 8 x 10^4 K.

The bright regions in this image correspond to regions of closed magnetic field loops that trap the hot, emitting plasma. Large bright regions are often called active regions. The dark regions correspond to cooler temperatures and possibly to locations where magnetic field lines open into the heliosphere, and thus, do not trap hot plasma.

View live data and images at http://SunSpotWatch.com

We’re on Facebook: http://NW7US.us/swhfr

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Here is the current forecast discussion on space weather and...

Here is the current forecast discussion on space weather and geophysical activity, issued 2017 May 31 1230 UTC.

Solar Activity

24 hr Summary: Solar activity was at very low levels. There were no spotted regions on the visible disk. Several B-class flares were observed from a region beyond the East Limb. No Earth-directed CMEs were observed in available coronagraph imagery.

A large filament centered near S15E30 disappeared from GONG H-alpha imagery at around 30/1200 UTC. The feature can also be seen lifting in loops of SDO AIA 304 imagery. Analysis of LASCO C2 imagery determined that this event is narrow off the East limb, and off the Sun-Earth line.

Forecast: Solar activity is expected to be at very low levels throughout the forecast period (31 May-02 Jun).

Energetic Particle

24 hr Summary: The greater than 2 MeV electron flux was at normal to moderate levels this period. The greater than 10 MeV proton flux remained at background levels throughout the period.

Forecast: The greater than 2 MeV electron flux is expected to be at normal to moderate levels on days one and two (31 May -01 Jun) with the potential to reach moderate to high levels by day three (02 Jun). The greater than 10 MeV proton flux is expected to persist at background levels throughout the forecast period (31-02 Jun).

Solar Wind

24 hr Summary: Solar wind parameters reflected near ambient conditions. Solar wind speeds gradually declined over the period from near 550 km/s to 450 km/s. Total field was between 6 and 9 nT while the Bz component was mostly northward. The phi angle was positive.

Forecast: Background solar wind parameters are expected on days one and two (31 May-01 Jun) with the return to a nominal solar wind regime. Day three (02 Jun) may see an increase in velocity associated with a non-recurrent, positive polarity, coronal hole visible in SDO AIA 193.

Geospace

24 hr Summary: The geomagnetic field was quiet.

Forecast: The geomagnetic field is expected to be mostly quiet on days one and two (31 May - 01 Jun). Active conditions are possible on day three (02 Jun) with the onset of HSS effects from the aforementioned non-recurrent positive polarity coronal hole.

Don’t forget to visit our live space weather and radio propagation web site, at: http://ift.tt/17yXOGK

Live Aurora mapping is at http://ift.tt/2lYUS2h

If you are on Twitter, please follow these two users: + http://ift.tt/1iWH4ta + http://ift.tt/1wJXm19

Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

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Daily solar report: Current Sunspot Cycle 24 Activity and Space...

Daily solar report: Current Sunspot Cycle 24 Activity and Space Weather

Sunspot count: Sun Spots: 0 as of 05/30/2017 10.7-cm Radio Flux: 74 SFU (SFU=Solar Flux Units) Estimated Planetary A-index (Ap): 7 | K-index (Kp): 0

Solar Wind: 368 km/s at 6.0 protons/cm3, Bz is 2.0 nT (May 31, 2017 at 1814 UT)

X-ray Solar Flares: 6h hi [B6.8][1944Z 05/30] 24h hi [B6.8][1944Z 05/30]

Background X-ray Level, Last Six Days

May 30 2017 :: A8.7 May 29 2017 :: B1.0 May 28 2017 :: B1.1 May 27 2017 :: B1.3 May 26 2017 :: B1.0 May 25 2017 :: A8.7

Global HF Propagation Conditions for 1800Z on 31 May, 2017 High Latitude: Normal Middle Latitude: Normal Low Latitude: Normal

Geomagnetic Latitude Ranges: High: 60-90 degrees, Middle: 20-60 degrees, Low: 0-20 degrees

For live data and images, visit http://SunSpotWatch.com

This report has been prepared by your space weather and radio propagation reporter, Tomas ( amateur radio operator, NW7US, http://NW7US.us )

Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

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Today’s Sun, seen through a filter of...

Today’s Sun, seen through a filter of ‘visible’ light (remember: NEVER look directly at the Sun!), as viewed by the Solar Dynamics Observatory (SDO), by the Helioseismic Magnetic Imager (HMI). This image is known as a 'continuum’ image; a continuum image is formed by filtering portions of the visible light part of the spectrum. The SDO HMI is designed to study oscillations and the magnetic field at the solar surface, or photosphere.

The continuum images allow us to track the evolution of sunspots. These images are important as they allow us to better understand the dynamic nature of the solar atmosphere.

View live data and images at http://SunSpotWatch.com

We’re on Facebook: http://NW7US.us/swhfr

Twitter feeds:
http://ift.tt/1iWH4ta and http://ift.tt/1wJXm19

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Today’s graph, plotting the SESC sunspot number, the...

Today’s graph, plotting the SESC sunspot number, the 10.7cm Radio Flux, and the Estimated Planetary A Index, for the last 30 days.

The numbers are:

   Date    | Sunspots | 10.7-cm Flux |  Ap 
==========================================
2017/05/30 |      0   |     74       |   7
2017/05/29 |     16   |     76       |  10
2017/05/28 |     20   |     79       |  51
2017/05/27 |     21   |     82       |  14
2017/05/26 |     22   |     80       |   3
2017/05/25 |     19   |     76       |   4
2017/05/24 |     15   |     78       |   4
2017/05/23 |     47   |     76       |   8
2017/05/22 |     55   |     74       |  10
2017/05/21 |     35   |     74       |   9
2017/05/19 |     24   |     72       |  11
2017/05/18 |     24   |     72       |  11
2017/05/17 |     13   |     71       |   8
2017/05/16 |     11   |     72       |   9
2017/05/15 |      0   |     71       |  14
2017/05/14 |      0   |     71       |  10
2017/05/13 |      0   |     70       |   4
2017/05/12 |      0   |     69       |   7
2017/05/11 |      0   |     69       |   6
2017/05/10 |      0   |     69       |   6
2017/05/09 |      0   |     69       |   6
2017/05/08 |     11   |     71       |   6
2017/05/07 |     23   |     72       |   8
2017/05/06 |     26   |     73       |   5
2017/05/05 |     31   |     74       |   6
2017/05/04 |     29   |     74       |   7
2017/05/03 |     15   |     75       |   4
2017/05/02 |     25   |     77       |   5

For complete live data and images visit http://SunSpotWatch.com

Be sure to share this post, to spread the love!

Get the space weather and radio propagation self-study course, today. Visit http://nw7us.us/swc for the latest sale and for more information!

Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

Get your copy of the self-study space weather and radio propagation course: http://nw7us.us/swc

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Southgate Amateur Radio News

Southgate Amateur Radio News

Did you know? Here’s a space weather and radio...

Did you know? Here’s a space weather and radio propagation educational tidbit – from http://SunSpotWatch.com – at 14:00 UTC on 2017-05-31:

The E-region of the ionosphere lies between approximately 90 and 140 km and is dynamic. The ionosphere’s E-region is ionized by soft x-ray solar radiation.

Don’t forget to visit our live space weather and radio propagation web site, at: http://SunSpotWatch.com

See the live aurora mapping is at http://ift.tt/2lYUS2h

If you are on Twitter, please follow these two users:

• http://ift.tt/1iWH4ta

• http://ift.tt/1wJXm19

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SY8APQ Lesvos Island. From DXNews.com

PY2DY will be active again from Lesvos Island, IOTA EU-049, 4 July - 2 August 2017 as SY8APQ.

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SY8APQ – Lesvos Island, EU-049

Tony, PY2DY will be active from Lesvos Island EU-049 as SY8APQ between July 4 to August 2, 2017. QRV on HF bands. QSL via LoTW.

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Today’s Sun (artificially-colored in yellow) seen at the...

Today’s Sun (artificially-colored in yellow) seen at the 171-angstrom wavelength (Extreme Ultraviolet, or EUV), as viewed by the Solar Dynamics Observatory (SDO), by the Atmospheric Imaging Assembly (AIA).

At this wavelength, at a wavelength not seen by the un-aided eye, we observe the Sun with the 17.1 nm (171 A) filter. This Extreme Ultraviolet (EUV) waveband is used to monitor the corona and upper transition region. With this filter, we can see the myrid of massive magnetic field lines, from simple to complex, that weave and twist throughout the Sun.

The image is a ‘false color image’, meaning that observed data are in a range outside of what human eyes can see, so the data are digitally recast into colors that emphasize physically important features. This view is created from data gathered by the Solar Dynamics Observatory (SDO) satellite that flies above Earth’s atmosphere in an inclined geosynchronous orbit.

Emissions captured in this image come from iron (Fe), a trace element in the solar atmosphere that emits Extreme Ultraviolet (EUV) light when heated to temperatures in excess of one million deg K. In the solar corona the temperatures are so high that most chemical elements have lost many of their electrons. Some of the remaining electrons still attached to the atom emit EUV radiation in narrow wavebands or lines.

The 17.1 nm filter, or channel, is dominated by emissions from highly ionized iron: 8 times ionized (missing 8 electrons) iron–Fe IX. The roman numeral descriptors are consistent with spectral notation: the level of ionization for a given roman numeral is one unit larger that the actual number of missing electrons. The temperatures associated with this level of ionization is about 6 x 10^5 K.

The bright regions in this image correspond to regions of closed magnetic field loops that trap the hot, emitting plasma. Large bright regions are often called active regions. The dark regions correspond to cooler temperatures and possibly to locations where magnetic field lines open into the heliosphere, and thus, do not trap hot plasma.

View live data and images at http://SunSpotWatch.com

We’re on Facebook: http://NW7US.us/swhfr

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ZS9V – Robben Island, AF-064

NEWS UPDATE – Permission has not yet been granted by the island authorities for this operation. We have made no announcement of it going ahead and will not do so until all the required approvals are in place. Right now, there is no reason to believe that this operation will happen this year. 73 Paul […]

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Latest TEC map from NASA. What is TEC? Total Electron Content...

Latest TEC map from NASA. What is TEC? Total Electron Content (or TEC) is an important descriptive quantity for the ionosphere of the Earth. TEC is the total number of free electrons integrated between two points, along a tube of one meter squared cross section, i.e., the electron columnar number density. Affected by solar activity, Total Electron Content (TEC) describes the total number of free electrons present within one square meter between two points (i.e. between the receiver and satellite involved in measuring TEC).

These maps are also used to monitor ionospheric weather, and to nowcast ionospheric storms that often occur responding to activities in solar wind and Earth’s magnetosphere as well as thermosphere.

View live data and images at http://SunSpotWatch.com

Follow: http://ift.tt/1iWH4ta and http://ift.tt/1wJXm19

Facebook: http://NW7US.us/swhfr

And: Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

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CDXP operators in Mauritania | Southgate Amateur Radio News

CDXP operators in Mauritania | Southgate Amateur Radio News: Southgate Amateur Radio News logo
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Page last updated on: Tuesday, May 30, 2017
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CDXP operators in Mauritania

CDXP operators Petr OK1BOA, Palo OK1CRM, David OK6DJ, Petr OK1FCJ, Pavel OK1GK, Ruda OK2ZA, Karel OK2ZI and guest operators Jean 5T0JL and Ahmad 5T2AI will be active as 5T5OK from Nouakchott, Mauritania, between September 18-26th.

Activity will be on 160-6 meters using CW, SSB and RTTY.

QSL via OK6DJ, ClubLog's OQRS or LoTW.

For more details and updates, see: http://www.cdxp.cz

OPDX

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The sun's magnetic dynamo is weakening | Southgate Amateur Radio News

The sun's magnetic dynamo is weakening | Southgate Amateur Radio News

Stats ‹ dxerhamnews — WordPress.com

Stats ‹ dxerhamnews — WordPress.com

03/06/2017 – Serbian Castles Day!

– A first activity day of Serbian castles will take place on the 3rd and 4th of June 2017. Great activity of Serbian hams is expected.
Organized by Dragan Ivanovic YT2KID & Castel club “King Lazar”, Krushevac.

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16-18/06/2017 WCA&BHS pedition to LZ-00263 Thracian Tomb in Kazanlak

Ivan LZ2HT plans to activate Thracian Tomb in Kazanlak WCA LZ-00263 (BHS SZ-25) during World Castles Weekend starting Friday 16th May afternoon. In PSK will use special callsign LZ8EPC/P. This reference is valid also for WHSA – WH-BG004.

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June 2017: Ionospheric Propagation Predictions

At the end of May there were 4 class B flares and on day 27th one of the Coronal Mass Emission (CME) hit the Earth, causing a sudden rise in the geomagnetic field. So the propagation has undergone a rather marked degradation.
June’s solar activity should be very low with a chance of C-class stream activity throughout the month.
No further CMEs and consequent agitation of the geomagnetic field can be excluded, typical events of the continuous decaying Solar cycle.
The propagation of June will be rather poor with E-Sporadic events, typical of the season, so there will be blanketing effects during daylight hours.

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Amateur Radio Operators to Assist in an Emergency:

MOULTRIE, Ga. -- "When all else fails\& Amateur Radio" is the motto of the Amateur Radio Relay League and, with this in mind, the Colquitt County Sheriff's Office and the Amateur Radio Emergency Service (ARES) have signed a memorandum of understanding (MOU) to support emergency communications within the county. The MOU was signed by Colquitt County Sheriff Rod Howell and Colquitt County ARES Emergency Coordinator Andy Clark on Friday in the sheriff's office. "We do this service so that the community can be better prepared in a disaster," Clark said. The MOU serves as a working agreement between these agencies in the event of an emergency where the existing communications infrastructure is compromised because of natural or manmade disasters. These guidelines are adopted and revised periodically when necessary to reflect current and community needs and practice. The guidelines are based on best practices and reflect efforts by the sheriff's office and ARES to ensure the community is protected during time of need. "Colquitt County Sheriff Rod Howell sees the benefits in having a trained communications service ready if a disaster strikes within his jurisdiction," said Clark. The local ARES group provides emergency backup communications for the county when communications are restricted. The ARES members are all volunteers and part of the national organization, Amateur Radio Relay League, which has be in existence since April 1914. The ARES volunteers provide their own equipment and are constantly training and applying their skills in case they are needed.

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Today’s Sun (artificially-colored in purple) seen at the...

Today’s Sun (artificially-colored in purple) seen at the 211-angstrom wavelength (Extreme Ultraviolet, or EUV), as viewed by the Solar Dynamics Observatory (SDO), by the Atmospheric Imaging Assembly (AIA).

At this wavelength, at a wavelength not seen by the un-aided eye, we observe this full-disk AIA image through the 21.1 nm (211 A) filter. This Extreme Ultraviolet (EUV) waveband is used to monitor active regions in the solar corona.

The image is a ‘false color image’, meaning that observed data are in a range outside of what human eyes can see, so the data are digitally recast into colors that emphasize physically important features. This view is created from data gathered by the Solar Dynamics Observatory (SDO) satellite that flies above Earth’s atmosphere in an inclined geosynchronous orbit.

Emissions captured in this image come from iron (Fe), a trace element in the solar atmosphere that emits Extreme Ultraviolet (EUV) light when heated to temperatures in excess of one million deg K. In the solar corona the temperatures are so high that most chemical elements have lost many of their electrons. Some of the remaining electrons still attached to the atom emit EUV radiation in narrow wavebands or lines.

The 21.1 nm filter (also called channel or bandpass) is dominated by emissions from highly ionized iron: 13 times ionized (missing 13 electrons) iron–Fe XIV. Other ionization levels of iron also contribute. The roman numeral descriptors are consistent with spectral notation: the level of ionization for a given roman numeral is one unit larger that the actual number of missing electrons. Additionally there may be some contribution from hot thermal plasma when solar flares are present. The temperatures associated with this level of ionization is about 2 x 10^6 K.

The bright regions in this image correspond to regions of closed magnetic field loops that trap the hot, emitting plasma. Large bright regions are often called active regions. The dark regions correspond to cooler temperatures and possibly to locations where magnetic field lines open into the heliosphere, and thus, do not trap hot plasma.

With this image, we can monitore active regions.

View live data and images at http://SunSpotWatch.com

We’re on Facebook: http://NW7US.us/swhfr

from Ham Radio Times http://ift.tt/2qzv4ZF
via IFTTT

Latest TEC map from NASA. What is TEC? Total Electron Content...

Latest TEC map from NASA. What is TEC? Total Electron Content (or TEC) is an important descriptive quantity for the ionosphere of the Earth. TEC is the total number of free electrons integrated between two points, along a tube of one meter squared cross section, i.e., the electron columnar number density. Affected by solar activity, Total Electron Content (TEC) describes the total number of free electrons present within one square meter between two points (i.e. between the receiver and satellite involved in measuring TEC).

These maps are also used to monitor ionospheric weather, and to nowcast ionospheric storms that often occur responding to activities in solar wind and Earth’s magnetosphere as well as thermosphere.

View live data and images at http://SunSpotWatch.com

Follow: http://ift.tt/1iWH4ta and http://ift.tt/1wJXm19

Facebook: http://NW7US.us/swhfr

And: Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

from Ham Radio Times http://ift.tt/2qzd7KQ
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Ham Talk Live #67 -- DX HOF Inductee WB9Z:

This week on Ham Talk Live!, Jerry Rosalius, WB9Z is our guest on the show to talk about his recent induction into the CQ DX Hall of Fame and his DXpeditions!

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Today’s Sun (artificially-colored in red) seen at the...

Today’s Sun (artificially-colored in red) seen at the 304-angstrom wavelength (Extreme Ultraviolet, or EUV), as viewed by the Solar Dynamics Observatory (SDO), by the Atmospheric Imaging Assembly (AIA).

At this wavelength, at a wavelength not seen by the un-aided eye, we can see the Sun through the 30.4 nm (304 A) filter. This Extreme Ultraviolet (EUV) waveband is used to monitor the chromosphere and lower transition region. It is useful to see plasma and filament activity, including filamet eruptions and coronal mass ejections (CMEs).

The image is a “false color image’, meaning that observed data are in a range outside of what human eyes can see, so the data are digitally recast into colors that emphasize physically important features. This view is created from data gathered by the Solar Dynamics Observatory (SDO) satellite that flies above Earth’s atmosphere in an inclined geosynchronous orbit.

Emissions captured in this image come from helium (He), the second most abundant element in the solar atmosphere. Singly ionized Helium (He II) emits Extreme Ultraviolet (EUV) light when heated to temperatures of ~70,000 deg K. In the upper solar atmosphere the temperatures are so high that most chemical elements have lost many of their electrons. The remaining electron, which is still attached to the atom, emits EUV radiation in narrow wavebands or lines when it is in an excited state.

The 30.4 nm filter (also called channel or bandpass) is dominated by emissions from singly (once) ionized helium which has missing 1 electron–He II. The roman numeral descriptor is consistent with spectral notation: the level of ionization for a given roman numeral is one unit larger that the actual number of missing electrons. The temperatures associated with this level of ionization is range from 6 x 10^4 K to 8 x 10^4 K.

The bright regions in this image correspond to regions of closed magnetic field loops that trap the hot, emitting plasma. Large bright regions are often called active regions. The dark regions correspond to cooler temperatures and possibly to locations where magnetic field lines open into the heliosphere, and thus, do not trap hot plasma.

View live data and images at http://SunSpotWatch.com

We’re on Facebook: http://NW7US.us/swhfr

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via IFTTT

Here is the current forecast discussion on space weather and...

Here is the current forecast discussion on space weather and geophysical activity, issued 2017 May 30 1230 UTC.

Solar Activity

24 hr Summary: Solar activity decreased to very low levels. There were no spotted regions on the visible disk. Several B-class flares were observed during the period from an area of plage near N12E25. No Earth-directed CMEs were observed in available coronagraph imagery.

Forecast: Solar activity is expected to be at very low levels throughout the forecast period (30 May-01 Jun). A chance remains for an isolated C-class flare on 30 May as Region 2659 rotates around the west limb.

Energetic Particle

24 hr Summary: The greater than 2 MeV electron flux was at normal to moderate levels this period. The greater than 10 MeV proton flux remained at background levels throughout the period.

Forecast: The greater than 2 MeV electron flux is expected to be at normal to moderate levels on day one (30 May) with the potential to reach moderate to high levels by days two and three (31 May-01 Jun). This increase is in response to the enhanced near-Earth solar wind environment associated with the passage of the 23 May CME. The greater than 10 MeV proton flux is expected to persist at background levels throughout the forecast period (29-31 May).

Solar Wind

24 hr Summary: Solar wind parameters, as measured by the DSCOVR spacecraft, reflected continued but waning influences from the 23 May CME. Solar wind speeds gradually increased from near 400 km/s to 530 km/s during the summary period. Total field was elevated early to values near 15 nT, then gradually decreased to near 8 nT by the end of the period. The Bz component had a few periods of a sustained southward orientation, with a maximum value of -13. The phi angle was predominantly positive.

Forecast: Solar wind parameters are expected to gradually transition from the trailing end of the 23 May CME back towards nominal conditions by early on day one (30 May). Background solar wind parameters are expected on days two and three (31 May-01 Jun) with the return to a nominal solar wind regime.

Geospace

24 hr Summary: The geomagnetic field reached active conditions due to a sustained period of southward Bz.

Forecast: The geomagnetic field is expected to be at quiet to unsettled levels on day one (30 May) as CME effects wane. Generally quiet conditions are expected for days two and three (31 May-01 Jun) with the return of a nominal solar wind regime.

Don’t forget to visit our live space weather and radio propagation web site, at: http://ift.tt/17yXOGK

Live Aurora mapping is at http://ift.tt/2lYUS2h

If you are on Twitter, please follow these two users: + http://ift.tt/1iWH4ta + http://ift.tt/1wJXm19

Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

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Daily solar report: Current Sunspot Cycle 24 Activity and Space...

Daily solar report: Current Sunspot Cycle 24 Activity and Space Weather

Sunspot count: Sun Spots: 16 as of 05/29/2017 10.7-cm Radio Flux: 76 SFU (SFU=Solar Flux Units) Estimated Planetary A-index (Ap): 10 | K-index (Kp): 1

Solar Wind: 524 km/s at 6.0 protons/cm3, Bz is 2.0 nT (May 30, 2017 at 1820 UT)

X-ray Solar Flares: 6h hi [B6.8][1440Z 05/29] 24h hi [B6.8][1440Z 05/29]

Background X-ray Level, Last Six Days

May 29 2017 :: B1.0 May 28 2017 :: B1.1 May 27 2017 :: B1.3 May 26 2017 :: B1.0 May 25 2017 :: A8.7 May 24 2017 :: A8.0

Global HF Propagation Conditions for 1800Z on 30 May, 2017 High Latitude: Normal Middle Latitude: Normal Low Latitude: Normal

Geomagnetic Latitude Ranges: High: 60-90 degrees, Middle: 20-60 degrees, Low: 0-20 degrees

For live data and images, visit http://SunSpotWatch.com

This report has been prepared by your space weather and radio propagation reporter, Tomas ( amateur radio operator, NW7US, http://NW7US.us )

Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

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Today’s Sun, seen through a filter of...

Today’s Sun, seen through a filter of ‘visible’ light (remember: NEVER look directly at the Sun!), as viewed by the Solar Dynamics Observatory (SDO), by the Helioseismic Magnetic Imager (HMI). This image is known as a 'continuum’ image; a continuum image is formed by filtering portions of the visible light part of the spectrum. The SDO HMI is designed to study oscillations and the magnetic field at the solar surface, or photosphere.

The continuum images allow us to track the evolution of sunspots. These images are important as they allow us to better understand the dynamic nature of the solar atmosphere.

View live data and images at http://SunSpotWatch.com

We’re on Facebook: http://NW7US.us/swhfr

Twitter feeds:
http://ift.tt/1iWH4ta and http://ift.tt/1wJXm19

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VK9MAV – Marion Reef/Diamond Islets, OC-267

NEWS UPDATE — Andy, VK5MAV updates that he will be active from Marion Reef, Coral Sea Islands, OC-267 as VK9MAV between June 11-16, 2017. QRV on HF bands. Also plans activity from Whitsundays Island OC-160 during June 17-18, 2017. QSL via VK5MAV direct, OQRS Club Log or via RN3RQ buro. MAY 19 — I’ve finally […]

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Today’s graph, plotting the SESC sunspot number, the...

Today’s graph, plotting the SESC sunspot number, the 10.7cm Radio Flux, and the Estimated Planetary A Index, for the last 30 days.

The numbers are:

   Date    | Sunspots | 10.7-cm Flux |  Ap 
==========================================
2017/05/29 |     16   |     76       |  10
2017/05/28 |     20   |     79       |  51
2017/05/27 |     21   |     82       |  14
2017/05/26 |     22   |     80       |   3
2017/05/25 |     19   |     76       |   4
2017/05/24 |     15   |     78       |   4
2017/05/23 |     47   |     76       |   8
2017/05/22 |     55   |     74       |  10
2017/05/21 |     35   |     74       |   9
2017/05/19 |     24   |     72       |  11
2017/05/18 |     24   |     72       |  11
2017/05/17 |     13   |     71       |   8
2017/05/16 |     11   |     72       |   9
2017/05/15 |      0   |     71       |  14
2017/05/14 |      0   |     71       |  10
2017/05/13 |      0   |     70       |   4
2017/05/12 |      0   |     69       |   7
2017/05/11 |      0   |     69       |   6
2017/05/10 |      0   |     69       |   6
2017/05/09 |      0   |     69       |   6
2017/05/08 |     11   |     71       |   6
2017/05/07 |     23   |     72       |   8
2017/05/06 |     26   |     73       |   5
2017/05/05 |     31   |     74       |   6
2017/05/04 |     29   |     74       |   7
2017/05/03 |     15   |     75       |   4
2017/05/02 |     25   |     77       |   5
2017/05/01 |     11   |     75       |   5

For complete live data and images visit http://SunSpotWatch.com

Be sure to share this post, to spread the love!

Get the space weather and radio propagation self-study course, today. Visit http://nw7us.us/swc for the latest sale and for more information!

Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

Get your copy of the self-study space weather and radio propagation course: http://nw7us.us/swc

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VK9MAV Marion Reef Island. From DXNews.com

Andrey, VK5MAV will be active from Marion Reef, Coral Sea Islands, IOTA OC - 267 11 - 16 June 2017 as VK9MAV.

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Did you know? Here’s a space weather and radio...

Did you know? Here’s a space weather and radio propagation educational tidbit – from http://SunSpotWatch.com – at 14:00 UTC on 2017-05-30:

The peak electron density of the ionosphere usually occurs in its ‘F region’. The ionosphere’s F-region is divided into two regions known as F1 and F2, though a third sub-region has been observed over the equator during certain conditions.

The F1 region is the lower of the 2 F-regions of the ionosphere and isn’t always present.

The F-regions of the ionosphere are ionized with extreme ultraviolet light (EUV).

Don’t forget to visit our live space weather and radio propagation web site, at: http://SunSpotWatch.com

See the live aurora mapping is at http://ift.tt/2lYUS2h

If you are on Twitter, please follow these two users:

• http://ift.tt/1iWH4ta

• http://ift.tt/1wJXm19

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TX5JF & TX5JF/MM – French Polynesia

Jean-Pierre, F6CTF announces he will be active from French Polynesia during June to September 2017 as TX5JF and TX5JF/MM. He plans to operate from different IOTA as he travels and will be QRV on 80-10m. QSL via H/c, eQSL.

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Southgate Amateur Radio News

Southgate Amateur Radio News

Today’s Sun (artificially-colored in yellow) seen at the...

Today’s Sun (artificially-colored in yellow) seen at the 171-angstrom wavelength (Extreme Ultraviolet, or EUV), as viewed by the Solar Dynamics Observatory (SDO), by the Atmospheric Imaging Assembly (AIA).

At this wavelength, at a wavelength not seen by the un-aided eye, we observe the Sun with the 17.1 nm (171 A) filter. This Extreme Ultraviolet (EUV) waveband is used to monitor the corona and upper transition region. With this filter, we can see the myrid of massive magnetic field lines, from simple to complex, that weave and twist throughout the Sun.

The image is a ‘false color image’, meaning that observed data are in a range outside of what human eyes can see, so the data are digitally recast into colors that emphasize physically important features. This view is created from data gathered by the Solar Dynamics Observatory (SDO) satellite that flies above Earth’s atmosphere in an inclined geosynchronous orbit.

Emissions captured in this image come from iron (Fe), a trace element in the solar atmosphere that emits Extreme Ultraviolet (EUV) light when heated to temperatures in excess of one million deg K. In the solar corona the temperatures are so high that most chemical elements have lost many of their electrons. Some of the remaining electrons still attached to the atom emit EUV radiation in narrow wavebands or lines.

The 17.1 nm filter, or channel, is dominated by emissions from highly ionized iron: 8 times ionized (missing 8 electrons) iron–Fe IX. The roman numeral descriptors are consistent with spectral notation: the level of ionization for a given roman numeral is one unit larger that the actual number of missing electrons. The temperatures associated with this level of ionization is about 6 x 10^5 K.

The bright regions in this image correspond to regions of closed magnetic field loops that trap the hot, emitting plasma. Large bright regions are often called active regions. The dark regions correspond to cooler temperatures and possibly to locations where magnetic field lines open into the heliosphere, and thus, do not trap hot plasma.

View live data and images at http://SunSpotWatch.com

We’re on Facebook: http://NW7US.us/swhfr

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Latest TEC map from NASA. What is TEC? Total Electron Content...

Latest TEC map from NASA. What is TEC? Total Electron Content (or TEC) is an important descriptive quantity for the ionosphere of the Earth. TEC is the total number of free electrons integrated between two points, along a tube of one meter squared cross section, i.e., the electron columnar number density. Affected by solar activity, Total Electron Content (TEC) describes the total number of free electrons present within one square meter between two points (i.e. between the receiver and satellite involved in measuring TEC).

These maps are also used to monitor ionospheric weather, and to nowcast ionospheric storms that often occur responding to activities in solar wind and Earth’s magnetosphere as well as thermosphere.

View live data and images at http://SunSpotWatch.com

Follow: http://ift.tt/1iWH4ta and http://ift.tt/1wJXm19

Facebook: http://NW7US.us/swhfr

And: Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

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TX5JF TX5JF/MM French Polynesia. From DXNews.com

Jean, F6CTF will be active from French Polynesia June - September 2017 as TX5JF and TX5JF/MM.

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OY/K2HVN Faroe Islands EU-018

Bill K2HVN will be active from Faroe Islands, IOTA EU-018, 13 to 26 June 2017 as OY/K2HVN.
Working on 40 – 10m in CW and SSB.
QSL via home call.

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3B7 St Brandon [Press Release]

Flo F5CWU informs DxCoffee redears:

“Last January, we revealed our new project: a DX expedition to St Brandon archipelago – 3B7. Initially planned on October 2017, it is finally the period of March-April 2018 which was selected. It presents a maximum of favorable conditions.

Since the announcement, we have worked on many subjects by following our usual roadmap. Although we’re already familiar with this kind of preparation, it is far from being a routine because each project is different. This new adventure does not make exception, and has its batch of characteristics. That’s all these preparatory tasks achieved during months which will condition success once on the air.

A qualified and very motivated team was made up. Our only and single objective will be to satisfy the amateur radio community.
As for Tromelin and Juan de Nova operations, the conditions of propagation, analyzed finely, will dictate our traffic. We know quite well this zone of the world and its characteristics; thus it will be a goal to satisfy the worldwide DX’ers and more especially those of the most delicate areas to contact: West Coast of America, Japan, and Oceania in particular.

We secured the transport by the payment of 50% of the invoice; that marks the point of nonreturn of the project. We are happy to count right now important actors of the amateur radio community among our sponsors. Soon, we will start contacting the clubs and associations to seek financial support, but as of now, you can support us with in an individual donation. As in the past, we endeavour to maintain the costs to their strict minimum without reducing the equipment engaged, nor the duration of the expedition. However, in spite of this permanent optimization, we need your support in addition to the already important part payed by the operators.

The website is now online, and will be fed in the coming weeks with articles about the preparation. A Facebook and Twitter account is also available.
We are impatient to talk with you about this new project during the upcoming hamfests.”

web site: http://ift.tt/2r6OZlj

 

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WIA: 2017 AGM Award Now Available:

The 2017 AGM award is now available to those who qualify. To apply for your award you must use the WIA online award system and upload your log with all qualifying QSO. Don't forget that you must "Verify DXCC" before any of them count. Then select "Show Award Status" and select "2017 AGM". If you qualify you should have an "Apply" link shown.

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WIA: Draft of New Radiocommunications Legislation Released:

The long-awaited Radiocommunications Bill 2017 -- a draft of what will become a new Radiocommunications Act -- was released on 18 May, along with a raft of supporting papers and fact sheets; 17 in all. The Exposure Draft of the Radiocommunications Bill 2017 comprises 21 Parts and runs to 217 pages. However, it is incomplete, as the subject of broadcasting is to be covered separately, later. The Department of Communications and the Arts is seeking stakeholder feedback, with a closing date for submissions of 30 June 2017. For those interested, the Bill package needs to be read in conjunction with the Department's "Spectrum Pricing" paper. A single licensing system is promoted as the centrepiece of the Bill. The current system of apparatus, class and spectrum licensing will disappear. The new system is promoted as providing " . . a more administratively streamlined approach for users in regards to licensing, planning, allocation and renewal, and [to] give users greater certainty of process." Under the new framework, the key characteristics of a licence -- including such parameters as allocated frequencies or frequency bands, permitted transmitter power, and transmission bandwidths, as well as other technical and administrative details -- will be specified on the licence itself. The Department of Communications and the Arts say this parameters-based licensing will provide greater clarity for the user. The Bill provides for licences to be issued for terms up to 20 years. Amateur radio licensing and licence conditions are not mentioned in the Bill as these are matters that will be covered by what is known as subordinate legislation - the regulations set out in a licence conditions determination document. Likewise, licence fees and taxes are not included in the Bill. To regulate the use of spectrum without a licence -- currently covered under Class licensing -- 'Spectrum authorisations' will be developed and issued by the ACMA. According to the Department of Communications and the Arts, "Spectrum authorisations will not have to be applied for and no fees will be payable. The core feature of authorisations will be that they are intended to allow radiocommunications devices to be operated in certain parts of the spectrum on a shared basis, subject to common conditions.

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Activating VU7KP – Bangaram Island (Laccadive Islands). From DXNews.com

After successful activation of VU7AG in 2013 and VU7KV in 2014, and presenting about the trip at many a meetings, folks in the DX community have asked for an opportunity to go there as a part of the team.

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Today’s Sun (artificially-colored in purple) seen at the...

Today’s Sun (artificially-colored in purple) seen at the 211-angstrom wavelength (Extreme Ultraviolet, or EUV), as viewed by the Solar Dynamics Observatory (SDO), by the Atmospheric Imaging Assembly (AIA).

At this wavelength, at a wavelength not seen by the un-aided eye, we observe this full-disk AIA image through the 21.1 nm (211 A) filter. This Extreme Ultraviolet (EUV) waveband is used to monitor active regions in the solar corona.

The image is a ‘false color image’, meaning that observed data are in a range outside of what human eyes can see, so the data are digitally recast into colors that emphasize physically important features. This view is created from data gathered by the Solar Dynamics Observatory (SDO) satellite that flies above Earth’s atmosphere in an inclined geosynchronous orbit.

Emissions captured in this image come from iron (Fe), a trace element in the solar atmosphere that emits Extreme Ultraviolet (EUV) light when heated to temperatures in excess of one million deg K. In the solar corona the temperatures are so high that most chemical elements have lost many of their electrons. Some of the remaining electrons still attached to the atom emit EUV radiation in narrow wavebands or lines.

The 21.1 nm filter (also called channel or bandpass) is dominated by emissions from highly ionized iron: 13 times ionized (missing 13 electrons) iron–Fe XIV. Other ionization levels of iron also contribute. The roman numeral descriptors are consistent with spectral notation: the level of ionization for a given roman numeral is one unit larger that the actual number of missing electrons. Additionally there may be some contribution from hot thermal plasma when solar flares are present. The temperatures associated with this level of ionization is about 2 x 10^6 K.

The bright regions in this image correspond to regions of closed magnetic field loops that trap the hot, emitting plasma. Large bright regions are often called active regions. The dark regions correspond to cooler temperatures and possibly to locations where magnetic field lines open into the heliosphere, and thus, do not trap hot plasma.

With this image, we can monitore active regions.

View live data and images at http://SunSpotWatch.com

We’re on Facebook: http://NW7US.us/swhfr

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Latest TEC map from NASA. What is TEC? Total Electron Content...

Latest TEC map from NASA. What is TEC? Total Electron Content (or TEC) is an important descriptive quantity for the ionosphere of the Earth. TEC is the total number of free electrons integrated between two points, along a tube of one meter squared cross section, i.e., the electron columnar number density. Affected by solar activity, Total Electron Content (TEC) describes the total number of free electrons present within one square meter between two points (i.e. between the receiver and satellite involved in measuring TEC).

These maps are also used to monitor ionospheric weather, and to nowcast ionospheric storms that often occur responding to activities in solar wind and Earth’s magnetosphere as well as thermosphere.

View live data and images at http://SunSpotWatch.com

Follow: http://ift.tt/1iWH4ta and http://ift.tt/1wJXm19

Facebook: http://NW7US.us/swhfr

And: Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

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Today’s Sun (artificially-colored in red) seen at the...

Today’s Sun (artificially-colored in red) seen at the 304-angstrom wavelength (Extreme Ultraviolet, or EUV), as viewed by the Solar Dynamics Observatory (SDO), by the Atmospheric Imaging Assembly (AIA).

At this wavelength, at a wavelength not seen by the un-aided eye, we can see the Sun through the 30.4 nm (304 A) filter. This Extreme Ultraviolet (EUV) waveband is used to monitor the chromosphere and lower transition region. It is useful to see plasma and filament activity, including filamet eruptions and coronal mass ejections (CMEs).

The image is a “false color image’, meaning that observed data are in a range outside of what human eyes can see, so the data are digitally recast into colors that emphasize physically important features. This view is created from data gathered by the Solar Dynamics Observatory (SDO) satellite that flies above Earth’s atmosphere in an inclined geosynchronous orbit.

Emissions captured in this image come from helium (He), the second most abundant element in the solar atmosphere. Singly ionized Helium (He II) emits Extreme Ultraviolet (EUV) light when heated to temperatures of ~70,000 deg K. In the upper solar atmosphere the temperatures are so high that most chemical elements have lost many of their electrons. The remaining electron, which is still attached to the atom, emits EUV radiation in narrow wavebands or lines when it is in an excited state.

The 30.4 nm filter (also called channel or bandpass) is dominated by emissions from singly (once) ionized helium which has missing 1 electron–He II. The roman numeral descriptor is consistent with spectral notation: the level of ionization for a given roman numeral is one unit larger that the actual number of missing electrons. The temperatures associated with this level of ionization is range from 6 x 10^4 K to 8 x 10^4 K.

The bright regions in this image correspond to regions of closed magnetic field loops that trap the hot, emitting plasma. Large bright regions are often called active regions. The dark regions correspond to cooler temperatures and possibly to locations where magnetic field lines open into the heliosphere, and thus, do not trap hot plasma.

View live data and images at http://SunSpotWatch.com

We’re on Facebook: http://NW7US.us/swhfr

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St Brandon DXpedition – 3B7

UPDATE by Seb F5UFX, Team Leader — Last January, we revealed our new project: a DXpedition to St Brandon archipelago – 3B7. Initially planned on October 2017, it is finally the period of March-April 2018 which was selected. It presents a maximum of favourable conditions. Since the announcement, we have worked on many subjects by […]

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Here is the current forecast discussion on space weather and...

Here is the current forecast discussion on space weather and geophysical activity, issued 2017 May 29 1230 UTC.

Solar Activity

24 hr Summary: Solar activity was at low levels. Region 2659 (N13W80, Dao/beta) produced a C3/Sf flare at 28/1928 UTC, the strongest of the period. Despite an increase in x-ray activity, the region continued a trend of gradual decay and consolidation. No Earth-directed CMEs were observed in available coronagraph imagery.

Forecast: Solar activity is expected to be at very low levels throughout the forecast period (29-31 May). There is a chance for additional isolated C-class flare activity on days one and two (29-30 May) as Region 2659 approaches the west limb.

Energetic Particle

24 hr Summary: The greater than 2 MeV electron flux was at normal to moderate levels this period in response to enhanced geomagnetic field activity associated with the influence of the 23 May CME. The greater than 10 MeV proton flux was steady at background levels throughout the period.

Forecast: The greater than 2 MeV electron flux has potential to reach high levels over the next three days (29-31 May) in response to the enhanced near-Earth solar wind environment associated with the passage of the 23 May CME.

The greater than 10 MeV proton flux is expected to persist at background levels throughout the forecast period (29-31 May).

Solar Wind

24 hr Summary: Solar wind parameters, as measured by the DSCOVR spacecraft, reflected continuously weakening enhancement from the 23 May CME. Total magnetic field strength varied between 9-17 nT. The Bz component was mostly positive after 28/1500 UTC with another rotation towards negative at the very end of the period. Solar wind speeds were between 350-375 km/s, with a gradual increase to 400 km/s during the later part of the reporting period. Phi rotated to the positive sector after 28/2300 UTC.

Forecast: Solar wind parameters are expected to gradually transition from the trailing end of the 23 May CME back towards nominal conditions by the end of day one (29 May). Background solar wind parameters are expected on days two and three (30-31 May) with the return to a nominal solar wind regime.

Geospace

24 hr Summary: The geomagnetic field was at quiet to active conditions due to the weakening influence of the 23 May CME.

Forecast: The geomagnetic field is expected to be at quiet to unsettled levels on day one (29 May) as CME effects wane. Generally quiet conditions are expected for days two and three (30-31 May) with the return of a nominal solar wind regime.

Don’t forget to visit our live space weather and radio propagation web site, at: http://ift.tt/17yXOGK

Live Aurora mapping is at http://ift.tt/2lYUS2h

If you are on Twitter, please follow these two users: + http://ift.tt/1iWH4ta + http://ift.tt/1wJXm19

Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

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Daily solar report: Current Sunspot Cycle 24 Activity and Space...

Daily solar report: Current Sunspot Cycle 24 Activity and Space Weather

Sunspot count: Sun Spots: 20 as of 05/28/2017 10.7-cm Radio Flux: 79 SFU (SFU=Solar Flux Units) Estimated Planetary A-index (Ap): 51 | K-index (Kp): 3

Solar Wind: 474 km/s at 2.0 protons/cm3, Bz is 2.0 nT (May 29, 2017 at 1813 UT)

X-ray Solar Flares: 6h hi [C3.3][1922Z 05/28] 24h hi [C3.3][1922Z 05/28]

Background X-ray Level, Last Six Days

May 28 2017 :: B1.1 May 27 2017 :: B1.3 May 26 2017 :: B1.0 May 25 2017 :: A8.7 May 24 2017 :: A8.0 May 23 2017 :: A7.0

Global HF Propagation Conditions for 1800Z on 29 May, 2017 High Latitude: Fair-Normal Middle Latitude: Normal Low Latitude: Normal

Geomagnetic Latitude Ranges: High: 60-90 degrees, Middle: 20-60 degrees, Low: 0-20 degrees

For live data and images, visit http://SunSpotWatch.com

This report has been prepared by your space weather and radio propagation reporter, Tomas ( amateur radio operator, NW7US, http://NW7US.us )

Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

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17/06/2017 – Operators of World Castles Weekend -2017!

Operators of WCW-2017: 

UA-00001	C-101	RK1A	17/18.06.2017	Admiralteystvo	op. Nickolay RV1AQ
UA-00008	C-108	RZ1CWC/P	17.06.2017	Koporje	3 QSO valid for Koporje Castle Award
UA-00008	C-108	R1CBN/P	17.06.2017	Koporje	3 QSO valid for Koporje Castle Award
UA-00008	C-108	RN1CW/P	17.06.2017	Koporje	3 QSO valid for Koporje Castle Award
UA-00008	C-108	UA1CIO/P	17.06.2017	Koporje	3 QSO valid for Koporje Castle Award
UA-00020	C-120	UA1AIR	17/18.06.2017	Kronshtadt Fortress
UA-00074	C-311	R1155RW	17/18.06.2017	Rostov Veliky Kremlin	op. R3MAI Club station
UA-00074	C-311	RG50RW	17/18.06.2017	Rostov Veliky Kremlin	op. R3MAI Club station
UA-00095	C-602	RU6UR/M	17.06.2017	Astrakhan Kremlin	morning
UA-00203	F-109	R1CBN	18.06.2017	Fort Krasnaya Gorka
UA-00255	U-101	RZ1CWC/P	18.06.2017	Karelsky Fortified	CW  only
UA-00256	U-102	RX1CQ/P	17/18.06.2017	Karelsky Fortified
UA-00323	C-408	R4RL	17/18.06.2017	Tower of Chertovo Gorodische
UA-00337	R-103	R1OAI	17/18.06.2017	Kargopol
UA-00349	R-304	UA3DCZ	17/18.06.2017	Radonezh
UA-00349	R-304	RK3DAJ	17/18.06.2017	Radonezh
UA-00349	R-304	RG50SP	17/18.06.2017	Radonezh	50 years of
UA-00543	C-770	RU6UR/M	17.06.2017	Gorodische Saray-Batu	afternoon

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Amateur Radio News - Ham Radio Library

Amateur Radio News - Ham Radio Library

ZL4YL New Zealand WPX CW 2017. From DXNews.com

Xenia Berger, ZL4YL in CQ WW WPX CW Contest 27 - 28 May 2017.

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Today’s Sun, seen through a filter of...

Today’s Sun, seen through a filter of ‘visible’ light (remember: NEVER look directly at the Sun!), as viewed by the Solar Dynamics Observatory (SDO), by the Helioseismic Magnetic Imager (HMI). This image is known as a 'continuum’ image; a continuum image is formed by filtering portions of the visible light part of the spectrum. The SDO HMI is designed to study oscillations and the magnetic field at the solar surface, or photosphere.

The continuum images allow us to track the evolution of sunspots. These images are important as they allow us to better understand the dynamic nature of the solar atmosphere.

View live data and images at http://SunSpotWatch.com

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Here is this week’s space weather and geophysical report,...

Here is this week’s space weather and geophysical report, issued 2017 May 29 0600 UTC.

Highlights of Solar and Geomagnetic Activity 22 - 28 May 2017

Solar activity was at very low levels to low levels over the period. Low levels were observed on 28 May due to a C3/Sf flare at 28/1928 UTC and a C1/Sf flare at 28/2313 UTC from Region 2659 (N13, L=041, class/area Dao/220 on 28 May). Other events included an approximate 25 degree filament eruption centered near N04W03 which was observed lifting off in H-alpha imagery beginning at 22/1900 UTC. An associated partial-halo CME was observed with the majority of the ejecta off the western limb in SOHO/LASCO C2 imagery beginning at 23/0512 UTC. WSA-Enlil modelling of the event showed an Earth-directed component with the associated CME.

No proton events were observed at geosynchronous orbit.

The greater than 2 MeV electron flux at geosynchronous orbit was at high levels from 22-27 May with a peak flux of 26,098 pfu observed at 22/1650 UTC. Electron flux dropped to normal levels on 28 May due to the arrival of the 23 May CME.

Geomagnetic field activity ranged from quiet to G3 (Strong) storm levels over the period. The period began under the declining influence of a negative polarity coronal hole high speed stream (CH HSS). Solar wind speeds declined from approximately 570 km/s to near 300 km/s by 27 May while total field was between 3 nT and 7 nT. Quiet to unsettled levels were observed on 22-23 May with quiet levels from 24 May through most of 27 May. Beginning at 27/1447 UTC, a small shock was observed indicating the arrival of the 23 May CME. Total field increased from 3 nT to 10 nT while the solar wind increased from 303 km/s to 353 km/s. Although solar wind speed remained fairly steady between 350 km/s and 380 km/s, another increase in total field was observed with the transition into the magnetic cloud at 27/2000 UTC. Total field reached a maximum of 23 nT at 27/2230 UTC before it slowly declined to near 13 nT by the end of the period. The Bz component deflected southward to -20 nT beginning at 27/2036 UTC and remained negative until 28/1442 UTC. A geomagnetic sudden impulse was observed at 27/1536 UTC (19 nT at the Boulder magnetometer) indicating the arrival of the CME. The geomagnetic field responded with a period of G2 (Moderate) storm levels late on 27 May followed by G1-G3 (Minor-Strong) storm levels through midday on 28 May. A decrease to quiet to active levels was observed during the second half of 28 May.

Forecast of Solar and Geomagnetic Activity 29 May - 24 June 2017

Solar activity is expected to be at very low levels throughout the forecast period with a chance for further isolated C-class flares on 29-30 May due to flare potential from Region 2659.

No proton events are expected at geosynchronous orbit.

The greater than 2 MeV electron flux at geosynchronous orbit is expected to be at normal to moderate levels with high levels likely from 29-30 May due to CME influence. High levels are also likely from 16-24 Jun due to CH HSS influence.

Geomagnetic field activity is expected to be at quiet to active levels on 29 May due to waning CME effects. Mostly quiet conditions are expected from 30 May through 09 Jun. From 10-19 Jun, unsettled to active levels are expected with G1 (Minor) geomagnetic storm levels likely on 16 Jun due to recurrent CH HSS effects. Mostly quiet conditions are expected to return from 20-24 Jun.

Don’t forget to visit our live space weather and radio propagation web site, at: http://ift.tt/17yXOGK

Live Aurora mapping is at http://ift.tt/2lYUS2h

If you are on Twitter, please follow these two users: + http://ift.tt/1iWH4ta + http://ift.tt/1wJXm19

Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

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R4WBF 9 year old Contester. From DXNews.com

Sergey, R4WBF in CQ WW WPX CW Contest 27 - 28 May 2017.

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Today’s graph, plotting the SESC sunspot number, the...

Today’s graph, plotting the SESC sunspot number, the 10.7cm Radio Flux, and the Estimated Planetary A Index, for the last 30 days.

The numbers are:

   Date    | Sunspots | 10.7-cm Flux |  Ap 
==========================================
2017/05/28 |     20   |     79       |  51
2017/05/27 |     21   |     82       |  14
2017/05/26 |     22   |     80       |   3
2017/05/25 |     19   |     76       |   4
2017/05/24 |     15   |     78       |   4
2017/05/23 |     47   |     76       |   8
2017/05/22 |     55   |     74       |  10
2017/05/21 |     35   |     74       |   9
2017/05/19 |     24   |     72       |  11
2017/05/18 |     24   |     72       |  11
2017/05/17 |     13   |     71       |   8
2017/05/16 |     11   |     72       |   9
2017/05/15 |      0   |     71       |  14
2017/05/14 |      0   |     71       |  10
2017/05/13 |      0   |     70       |   4
2017/05/12 |      0   |     69       |   7
2017/05/11 |      0   |     69       |   6
2017/05/10 |      0   |     69       |   6
2017/05/09 |      0   |     69       |   6
2017/05/08 |     11   |     71       |   6
2017/05/07 |     23   |     72       |   8
2017/05/06 |     26   |     73       |   5
2017/05/05 |     31   |     74       |   6
2017/05/04 |     29   |     74       |   7
2017/05/03 |     15   |     75       |   4
2017/05/02 |     25   |     77       |   5
2017/05/01 |     11   |     75       |   5
2017/04/30 |     33   |     77       |   6

For complete live data and images visit http://SunSpotWatch.com

Be sure to share this post, to spread the love!

Get the space weather and radio propagation self-study course, today. Visit http://nw7us.us/swc for the latest sale and for more information!

Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

Get your copy of the self-study space weather and radio propagation course: http://nw7us.us/swc

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Southgate Amateur Radio News

Southgate Amateur Radio News

JW/DL2JRM – Svalbard

Rene, DL2JRM will be active from Svalbard as JW/DL2JRM between November 10-13, 2017. QRV on HF bands. QSL via H/c.

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Did you know? Here’s a space weather and radio...

Did you know? Here’s a space weather and radio propagation educational tidbit – from http://SunSpotWatch.com – at 14:00 UTC on 2017-05-29:

What is the ionosphere? The ionosphere (the scientific term, ‘ionosphere’, is never used as a proper noun, so don’t capitalize it) is the region of Earth’s upper atmosphere. It lies between about 50 km and several Earth radii, hundreds of kilometers out. For radio work, the ionosphere is defined as the region between abt 50 km and 1000 km.

Don’t forget to visit our live space weather and radio propagation web site, at: http://SunSpotWatch.com

See the live aurora mapping is at http://ift.tt/2lYUS2h

If you are on Twitter, please follow these two users:

• http://ift.tt/1iWH4ta

• http://ift.tt/1wJXm19

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Today’s Sun (artificially-colored in yellow) seen at the...

Today’s Sun (artificially-colored in yellow) seen at the 171-angstrom wavelength (Extreme Ultraviolet, or EUV), as viewed by the Solar Dynamics Observatory (SDO), by the Atmospheric Imaging Assembly (AIA).

At this wavelength, at a wavelength not seen by the un-aided eye, we observe the Sun with the 17.1 nm (171 A) filter. This Extreme Ultraviolet (EUV) waveband is used to monitor the corona and upper transition region. With this filter, we can see the myrid of massive magnetic field lines, from simple to complex, that weave and twist throughout the Sun.

The image is a ‘false color image’, meaning that observed data are in a range outside of what human eyes can see, so the data are digitally recast into colors that emphasize physically important features. This view is created from data gathered by the Solar Dynamics Observatory (SDO) satellite that flies above Earth’s atmosphere in an inclined geosynchronous orbit.

Emissions captured in this image come from iron (Fe), a trace element in the solar atmosphere that emits Extreme Ultraviolet (EUV) light when heated to temperatures in excess of one million deg K. In the solar corona the temperatures are so high that most chemical elements have lost many of their electrons. Some of the remaining electrons still attached to the atom emit EUV radiation in narrow wavebands or lines.

The 17.1 nm filter, or channel, is dominated by emissions from highly ionized iron: 8 times ionized (missing 8 electrons) iron–Fe IX. The roman numeral descriptors are consistent with spectral notation: the level of ionization for a given roman numeral is one unit larger that the actual number of missing electrons. The temperatures associated with this level of ionization is about 6 x 10^5 K.

The bright regions in this image correspond to regions of closed magnetic field loops that trap the hot, emitting plasma. Large bright regions are often called active regions. The dark regions correspond to cooler temperatures and possibly to locations where magnetic field lines open into the heliosphere, and thus, do not trap hot plasma.

View live data and images at http://SunSpotWatch.com

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HamRadioNow's first day at 2017 Hamvention | Southgate Amateur Radio News

HamRadioNow's first day at 2017 Hamvention | Southgate Amateur Radio News

dxer ham radio dx news

dxer ham radio dx news

Latest TEC map from NASA. What is TEC? Total Electron Content...

Latest TEC map from NASA. What is TEC? Total Electron Content (or TEC) is an important descriptive quantity for the ionosphere of the Earth. TEC is the total number of free electrons integrated between two points, along a tube of one meter squared cross section, i.e., the electron columnar number density. Affected by solar activity, Total Electron Content (TEC) describes the total number of free electrons present within one square meter between two points (i.e. between the receiver and satellite involved in measuring TEC).

These maps are also used to monitor ionospheric weather, and to nowcast ionospheric storms that often occur responding to activities in solar wind and Earth’s magnetosphere as well as thermosphere.

View live data and images at http://SunSpotWatch.com

Follow: http://ift.tt/1iWH4ta and http://ift.tt/1wJXm19

Facebook: http://NW7US.us/swhfr

And: Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

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E51XYL Rarotonga Island OC-013

Shirley VK5YL will be active Rarotonga Island, IOTA OC-013, 10 to 17 June 2017 as E51XYL.
Working on 20m in SSB.
QSL via home call.

 

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TX5EG Oceania IOTA Tour

11 to 19 June: Atoll Ahe, IOTA OC-131, King George Islands (Locator  BH65VM)

• Operators: F6BCW, F6DTZ, F6IPT, F1MNQ and F1TCV.

29 June to 17 July: Huahine Island, IOTA OC-067, Leeward Islands (Locator BH43LH)

• Operators: F6BCW, F6DTZ, F6IPT, F5UOW, F1MNQ and F1TCV.

29 July to 6 August: Hiva Oa Island, IOTA OC-027, Marquesas Islands (Locator CI00LE)

• Operators: F6BCW, F6DTZ, F1TCV and K3EL.

15 August to 5 September: Moorea Island, IOTA OC-046, Windward Islands (Locator BH52BM)

• Operators: F6BCW, F6DTZ and F1TCV.

QSL via F6BCW direct, bureau or Eqsl.

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Signals from Space Annapolis Royal Students Learn Ham Radio for June Launch

Annapolis West Education Centre student Abigail Bonnington holds a video camera hardly bigger than a sugar cube. It's attached to a small transmitter that will send signal to a laptop. It stopped working and now Penney and Bonnington are troubleshooting. It has to be operational or replaced by sometime in June when the Annapolis Royal Space Agency launches its second 'package' deep into the stratosphere -- 30 or 40 kilometres up. Penney is with the Annapolis Valley Amateur Radio Club and has been working with the students since the fall. "I was approached by them to see if amateur radio had any part to play in their balloon project, and of course it does," said Penney. "We can provide location information, pictures, telemetry -- things like that -- live TV picture. And the ground search team can use radio to keep in touch and coordinate searching for the balloon." It was Bonnington, a space agency veteran, who got in touch with the ham radio club and asked for help. "So we came down and gave them the talk on amateur radio and they were suitably impressed and decided it would be nice to work together," said Penney. So ham radio is the new thing in this year's project. With no cell signal or any type of WiFi up in space, radio signal is the only thing that works to send live TV back to Earth. Or as Penney says: "A live video camera connected to a transmitter that will operate the amateur radio bands and will transmit a picture back to mission control here. Live TV -- from the edge of space."

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Amateur Radio Roundtable Live Tuesday:

Join Katie Breen Allen, Dave Casler, and me Tuesday night for Amateur Radio Roundtable at 8:00 PM Central (May 30) on W5KUB.COM

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Today’s Sun (artificially-colored in purple) seen at the...

Today’s Sun (artificially-colored in purple) seen at the 211-angstrom wavelength (Extreme Ultraviolet, or EUV), as viewed by the Solar Dynamics Observatory (SDO), by the Atmospheric Imaging Assembly (AIA).

At this wavelength, at a wavelength not seen by the un-aided eye, we observe this full-disk AIA image through the 21.1 nm (211 A) filter. This Extreme Ultraviolet (EUV) waveband is used to monitor active regions in the solar corona.

The image is a ‘false color image’, meaning that observed data are in a range outside of what human eyes can see, so the data are digitally recast into colors that emphasize physically important features. This view is created from data gathered by the Solar Dynamics Observatory (SDO) satellite that flies above Earth’s atmosphere in an inclined geosynchronous orbit.

Emissions captured in this image come from iron (Fe), a trace element in the solar atmosphere that emits Extreme Ultraviolet (EUV) light when heated to temperatures in excess of one million deg K. In the solar corona the temperatures are so high that most chemical elements have lost many of their electrons. Some of the remaining electrons still attached to the atom emit EUV radiation in narrow wavebands or lines.

The 21.1 nm filter (also called channel or bandpass) is dominated by emissions from highly ionized iron: 13 times ionized (missing 13 electrons) iron–Fe XIV. Other ionization levels of iron also contribute. The roman numeral descriptors are consistent with spectral notation: the level of ionization for a given roman numeral is one unit larger that the actual number of missing electrons. Additionally there may be some contribution from hot thermal plasma when solar flares are present. The temperatures associated with this level of ionization is about 2 x 10^6 K.

The bright regions in this image correspond to regions of closed magnetic field loops that trap the hot, emitting plasma. Large bright regions are often called active regions. The dark regions correspond to cooler temperatures and possibly to locations where magnetic field lines open into the heliosphere, and thus, do not trap hot plasma.

With this image, we can monitore active regions.

View live data and images at http://SunSpotWatch.com

We’re on Facebook: http://NW7US.us/swhfr

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Latest TEC map from NASA. What is TEC? Total Electron Content...

Latest TEC map from NASA. What is TEC? Total Electron Content (or TEC) is an important descriptive quantity for the ionosphere of the Earth. TEC is the total number of free electrons integrated between two points, along a tube of one meter squared cross section, i.e., the electron columnar number density. Affected by solar activity, Total Electron Content (TEC) describes the total number of free electrons present within one square meter between two points (i.e. between the receiver and satellite involved in measuring TEC).

These maps are also used to monitor ionospheric weather, and to nowcast ionospheric storms that often occur responding to activities in solar wind and Earth’s magnetosphere as well as thermosphere.

View live data and images at http://SunSpotWatch.com

Follow: http://ift.tt/1iWH4ta and http://ift.tt/1wJXm19

Facebook: http://NW7US.us/swhfr

And: Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

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Leigh and I are at our Son’s wedding renewal ceremony in...

Leigh and I are at our Son’s wedding renewal ceremony in which he and his bride, Sarah, are renewing their vows.

#wedding #renewal #vows #marriage #love #Sunday

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Today’s Sun (artificially-colored in red) seen at the...

Today’s Sun (artificially-colored in red) seen at the 304-angstrom wavelength (Extreme Ultraviolet, or EUV), as viewed by the Solar Dynamics Observatory (SDO), by the Atmospheric Imaging Assembly (AIA).

At this wavelength, at a wavelength not seen by the un-aided eye, we can see the Sun through the 30.4 nm (304 A) filter. This Extreme Ultraviolet (EUV) waveband is used to monitor the chromosphere and lower transition region. It is useful to see plasma and filament activity, including filamet eruptions and coronal mass ejections (CMEs).

The image is a “false color image’, meaning that observed data are in a range outside of what human eyes can see, so the data are digitally recast into colors that emphasize physically important features. This view is created from data gathered by the Solar Dynamics Observatory (SDO) satellite that flies above Earth’s atmosphere in an inclined geosynchronous orbit.

Emissions captured in this image come from helium (He), the second most abundant element in the solar atmosphere. Singly ionized Helium (He II) emits Extreme Ultraviolet (EUV) light when heated to temperatures of ~70,000 deg K. In the upper solar atmosphere the temperatures are so high that most chemical elements have lost many of their electrons. The remaining electron, which is still attached to the atom, emits EUV radiation in narrow wavebands or lines when it is in an excited state.

The 30.4 nm filter (also called channel or bandpass) is dominated by emissions from singly (once) ionized helium which has missing 1 electron–He II. The roman numeral descriptor is consistent with spectral notation: the level of ionization for a given roman numeral is one unit larger that the actual number of missing electrons. The temperatures associated with this level of ionization is range from 6 x 10^4 K to 8 x 10^4 K.

The bright regions in this image correspond to regions of closed magnetic field loops that trap the hot, emitting plasma. Large bright regions are often called active regions. The dark regions correspond to cooler temperatures and possibly to locations where magnetic field lines open into the heliosphere, and thus, do not trap hot plasma.

View live data and images at http://SunSpotWatch.com

We’re on Facebook: http://NW7US.us/swhfr

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Here is the current forecast discussion on space weather and...

Here is the current forecast discussion on space weather and geophysical activity, issued 2017 May 28 1230 UTC.

Solar Activity

24 hr Summary: Solar activity was very low. Region 2659 (13W64, Dao/beta) produced several B-class x-ray enhancements. Minor consolidation and decay was observed in its trailer spot. No Earth-directed CMEs were observed in available coronagraph imagery.

Forecast: Solar activity is expected to continue at very low levels over the next three days (28-30 May) with a chance for C-class flare activity.

Energetic Particle

24 hr Summary: The greater than 2 MeV electron flux reached high levels this period with a peak flux of 13,200 pfu observed at 27/1535 UTC. The greater than 10 MeV proton flux was steady at background levels throughout the period.

Forecast: The greater than 2 MeV electron flux is expected to be at normal to moderate levels on days one (28 May) due to elevated geomagnetic field activity associated with the arrival of the 23 May CME. High flux levels are likely to return on days two and three (29-30 May) as CME effects subside.

The greater than 10 MeV proton flux is expected to persist at background levels throughout the forecast period (28-30 May).

24 hr Summary: Solar wind parameters were at background levels until around 27/1445 UTC when a minor shock associated with a CME from 23 May arrived. Solar wind speed sharply increased from around 300 km/s to around 350 km/s at 27/1445 UTC, followed by an increase to a peak value of 463 km/s at 27/2243 UTC. Through the sheath, total magnetic field strength (Bt) ranged from 1-20 nT. (Bt) increased to a peak of around 23 nT and Bz deflected southward reaching -15 to -20 nT during the transition into the magnetic cloud between roughly 27/2000-2200 UTC. Afterward, a slow taper in the strength of the magnetic cloud was observed with values for Bt reaching 14 nT and Bz reaching near -1 nT by the end of the period.

Forecast: Solar wind parameters are expected to remain enhanced on day one through midday on day two (28-29 May) under the continued influence of the 23 May CME. A slow return to near-background solar wind values are expected late on day two through day three (29-30 May) with the return of a nominal solar wind regime.

Geospace

24 hr Summary: The geomagnetic field was quiet until the 27/1500-1800 synoptic period when the geomagnetic field became unsettled with the arrival of the 23 May CME. G2 (Moderate) geomagnetic storm levels, first observed during the 27/2100-2400 UTC period, increased to a peak ofG3 (Strong) storm levels for the 28/0300-0600 UTC period. Activity decreased to G2 (Moderate) and G1 (Minor) storm levels for the following two synoptic periods. Despite relatively slow wind speeds, sustained southward Bz of around -20 Bz provided near-optimal coupling with the Earths magnetic field which produced the strong geomagnetic response observed during the reporting period.

Forecast: The geomagnetic field is expected to reach G1 (Minor) geomagnetic storm levels on day one (28 May) due to continued CME influence. Quiet to active levels are expected on day day two (29 May) as effects from the CME wane. Mostly quiet conditions are expected on day three (30 May) as a nominal solar wind regime returns.

Don’t forget to visit our live space weather and radio propagation web site, at: http://ift.tt/17yXOGK

Live Aurora mapping is at http://ift.tt/2lYUS2h

If you are on Twitter, please follow these two users: + http://ift.tt/1iWH4ta + http://ift.tt/1wJXm19

Check out the stunning view of our Sun in action, as seen during the last five years with the Solar Dynamics Observatory (SDO): https://www.youtube.com/watch?v=zXN-MdoGM9g

We’re on Facebook: http://NW7US.us/swhfr

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