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Kaʻū News Briefs Dec.15, 2024

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Kaʻū Hospital & East Hawai'i Health Clinic staff and volunteers put together the Da Grinch float for Pāhala Town Lighted Christmas Parade on Saturday. Photo by Stacyn Sakuma

Official Grand Marshall of Pāhala Town Lighted Christmas Parade, Wayne Kawachi, his arms open wide to represent the non-profit 'O Ka'ū Kākou, the truck for the float provided by John Masters and Kaʻū Auto Repair. Photo by Julia Neal

NON-PROFITS AND PUBLIC ENTITIES SERVING KAʻŪ took to the streets of the village for the Pāhala Town Lighted Christmas Parade on Saturday along with businesses, churches, school groups, ranchers and families.

Fire Engine 11 lit up the Pāhala Town Lighted Christmas Parade on Saturday night. Photo by Julia Neal
The Emergency Medical Services ambulance joins the Pāhala Town Lighted Christmas Parade. Photo by Julia Neal
State House of Representatives member Jeanne Kapela meets parade goers in her convertible. Photo by Julia Neal
Ruby Basque-Jordan, office manager for Kaʻū's Representative in the state House, gets ready to drive the Rep. Jeanne Kapela
and her daughter Ualani. Photo by Julia Neal
Riena Kaupu, Sheryl Sebastian, Janessa Jara, Erin Santos, Mark Peters and Jenn Abalos, the CU Hawai'i Credit Union team,
puts finishing touches on their Candyland float prior to the start of the parade. Photo by Julia Neal
Kaʻū Coffee Growers CoopPresident Gloria Camba with Lorie Obra of Rusty's Hawaiian and Kaʻū Coffee farmer Donna Gascon. Photo by Julia Neal
Kaʻū Multicultural Society, which collects historical documents, photos and items from sugar plantation days, ranching and coffee farmers to celebrate the cultural diversity of Kaʻū, joined the Pāhala Town Lighted Christmas Parade. Photo by Julia Neal
Pāhala Hongwanji Taiko drummers, ready to roll through Pāhala Town Lighted Christmas Parade. Photo by Julia Neal
See more on Pāhala Town Lighted Christmas Parade participation by schools, businesses, paniolo and more, as well as the Taro Festival and other holiday events in upcoming Kaʻū News Briefs.

To read comments, add your own, and like this story, seefacebook.com/kaucalendar. See upcoming events, print edition and archive at kaunews.com.

INTERFEROGRAMS, THE IMAGES CREATED BY RADAR SATELLITES, are the subject of the latest Volcano Watch, the weekly articlewritten by USGS scientist and affiliates at Hawaiian Volcano Observatory:
Interferograms show how the ground has changed shape, or deformed, over time. Today, we’ll dive into one of the trickiest parts of interpreting interferograms: the perspective of satellites.
    Volcanologists use interferograms to detect unrest by observing how the surface of a volcano is deforming in response to migrating magma beneath the ground. We can see changing subsurface magma reservoirs, their connections, and new paths magma creates as it travels closer to the surface.          While interferograms can be beautiful and informative, they are also difficult to interpret.
A Volcano Watch article from June 2019 discussed how to read the repeating cycles of color, called fringes (which often make bullseye or butterfly wing patterns), to figure out how much ground movement is occurring. To summarize quickly: count the fringes, starting from the outside of the feature towards the inside. Keep track of the sequence the color is cycling: is it red-yellow-blue or blue-yellow-red? Use the figure key to work out which direction the ground is moving, either towards or away from the satellite. The change in distance between the ground and satellite is called “range change”. Multiply the number of fringes by the range change value of a single fringe (also given in the figure key) and you’ve calculated displacement and its direction. Or have you? In reality, it’s a bit more complicated.
Color graphic showing how interferogram images are generated
Panels A and B show what an interferogram would look like for a simple expanding spherical magma chamber from an ascending and descending orbital perspective. The star shows the true center of the inflating magma source. The arrow and bar denote satellite flight direction and look direction respectively. Each fringe represents approximately 1.55 cm. Panels C and D show the same event in a cross-section view. The black lines and arrows show the displacement as viewed by the SAR satellite in its line-of-sight (LOS), while the grey lines and arrows show the ground displacement physically occurring. The key in panel C gives the scale of the arrows. Notice in the ascending case, the deformation pattern is shifted and skewed west while the descending case shows the opposite. USGS Image
 
   To create interferograms, two Synthetic Aperture Radar (SAR) images (separated in time by a few weeks) are combined from satellites orbiting around the Earth. If the ground has moved enough within the timespan of the two images, fringes will be visible in the interferogram. Where this gets tricky is how the satellite looks at the surface of the Earth. SAR satellites don’t look straight down, they look to the side, often about 30 degrees from vertical. What effect does this have on interferogram interpretation?
    If an area on the ground moved exactly upwards by 5 inches, from a SAR satellite’s perspective less than 5 inches of range change will be recorded. But why is this? Let’s pretend someone is shining a flashlight at you. If they shine it directly at you, it’s quite blinding! But if they tilt the light just a bit off-center, the light will still be visible, but not nearly as blinding. If the light is tilted fully away from you, you may see nothing at all. The intensity of the light hasn’t changed, but your perspective has.
   Going back to the example above, a similar phenomenon is happening but instead of light intensity, we’re measuring range change. If the motion of the ground is tilted away from the SAR satellite’s look direction, less of the actual motion will be measured than is physically occurring. If the ground were to move 5 inches directly toward the satellite, then it would indeed record 5 inches of range change. In this manner, the direction of the ground motion is important, as is the orientation of the satellite.
    To illustrate how satellite orientation affects an interferogram, we’ve created a simple model that shows a spherical inflating magma body (like an inflating balloon underground) and its effect on the surface viewed from multiple satellite perspectives. In these models, the magma body is in the exact center (white star), but that’s not what we see. We instead see a bullseye that looks somewhat skewed and shifted either to the West or the East depending on the viewing geometry.
USGS Volcanoes🌋 (@USGSVolcanoes) / X

    This is due to the phenomena we just discussed. Since SAR satellites look to the side, the range change that we see as fringes is only a part of the actual motion of the ground if that motion is not in line with the satellite’s line-of-sight. Since inflation results in the ground moving upwards and outwards, there will be some motion that is captured and other motion that is missed or minimized. For example, if motion is perpendicular (or close to perpendicular) to the line-of-sight, the satellite will see barely any motion at all, just like the decrease in intensity as a light is being shined away from you. This results in the entire measured deformation pattern to be shifted, as outwards perpendicular motion away from the satellite will be small while motion towards the satellite will be larger.
    Interferograms posted by the USGS Hawaiian Volcano Observatory will provide an arrow denoting the satellite flight direction and a perpendicular bar that shows its look direction. Using this information and your newfound knowledge of SAR perspectives, you can more accurately interpret how a volcano is deforming. In a future “Volcano Watch” article, we’ll discuss how perspective changes more complex signals such as propagating dikes (spoiler alert: it gets even more complicated).

Volcano Activity Updates
   Kīlauea is not erupting. Its USGS Volcano Alert level is ADVISORY.
   Over the week ending last Thursday, earthquake rates beneath Kīlauea summit and upper and middle East Rift Zone decreased and were less than half that of the previous week. About 70 earthquakes were located beneath the summit, and less than 100 were located in the upper to middle East Rift Zone. Ground deformation rates in the summit region showed steady inflation over the past week, while ground deformation rates near the September 15-20 middle East Rift Zone eruption site have slowed. Future intrusive episodes and eruptions could occur with continued magma supply.
    Mauna Loa is not erupting. Its USGS Volcano Alert Level is at NORMAL.
    Two earthquakes were reported felt in the Hawaiian Islands during the week ending last Thursday: a magnitude-3.6 event 44 km (27 mi) SW of Captain Cook at 30 km (19 mi) depth on Dec. 10 at 6:45 a.m. HST and a magnitude-3.3 event 18 km (11 mi) SE of Pāhala at 32 km (20 mi) depth on Dec. 9 at 4:26 p.m. HST.
    HVO continues to closely monitor Kīlauea and Mauna Loa.

To read comments, add your own, and like this story, see facebook.com/kaucalendar. See upcoming events, print edition and archive at kaunews.com.




Volcano Art Center Gallery inside Hawai'i Volcanoes National Park.







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