38 Saying, Blessed be the King that cometh in the name of the Lord: peace in heaven, and glory in the highest.
39 And some of the Pharisees from among the multitude said unto him, Master, rebuke thy disciples.
40 And he answered and said unto them, I tell you that, if these should hold their peace, the stones would immediately cry out.
41
And when he was come near, he beheld the city, and wept over it.
Based
on the Bible verses above, I have long believed that someday scientists will
discover powerful properties in rocks, quartz crystals and silicon. Quartz and
silicon have revolutionized the computer industry. I do not believe crystals
have “New Age” powers. However, I think some day we will discover that rocks
and stones are singing the praises of almighty God. This is why I found the
information below about earthquake lights so interesting.
The
scientists mentioned in the article below did recognize the influence of Scalar
and HAARP waves on locations where earthquakes have occurred, e.g. Fukushima,
Japan.
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| Earthquake lights in Mansfield, Ohio? |
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| Earthquake lights in Mansfield, Ohio |
January 6, 2014 Brian Howard of National Geographic reported that a
historic earthquake with monstrous destruction may be in the works near
Mansfield, Ohio as residents and local TV report strange lights emanating from
the ground. This phenomenon has been seen before in many places just days or
hours before a massive earthquake. This story is NOT intended to frighten or
panic anyone, but it can't hurt to make some emergency preparations with food,
water, medications, flashlights, batteries, radios, blankets and such just in
case. Rare flashes of light that are sometimes seen around earthquakes are not caused
by birds, or planes, or UFOs—all of which had been previously used to explain
the phenomena known as earthquake lights. Instead, the lights are caused by
electrical properties of certain rocks in specific settings, report scientists in a new paper. Sometimes
called earthquake lightning, the lights can take "many different shapes,
forms, and colors," says study coauthor Friedemann
Freund, an adjunct professor of physics at San Jose State University
and a senior researcher at NASA's Ames Research Center. Freund says common
forms of earthquake lights include bluish flames that appear to come out of the
ground at ankle height; orbs of light called ball
lightning that float
in the air for tens of seconds or even minutes; and quick flashes of bright
light that resemble regular lightning strikes, except they come out of the
ground instead of the sky and can stretch up to 650 feet (200 meters).
Historic Sightings
Over
the centuries, there have been many reports of earthquake lights, both before
and while the ground is shaking. Just seconds before the 2009 L'Aquila, Italy,
earthquake, people saw four-inch (ten-centimeter) flames of light flickering
above a stone street. On November 12, 1988, people reported a bright
purple-pink globe of light along the St. Lawrence River in Quebec, 11 days
before a powerful quake. People also reported seeing a faint rainbow of light
before the great 1906 quake in
San Francisco and
lights before the devastating 1811-12 New Madrid
earthquakes in
Missouri. Freund and colleagues studied such historic accounts going all the
way back to the year 1600 and published their findings in Seismological Research Letters.
UFO Fodder
"In
the past, people often interpreted [earthquake lights] in religious terms, and
in modern times they thought of UFOs, although there is a completely rational
physical explanation that we are working on," Freud says. Jim Conacher
thought he was seeing UFOs when he spied seven yellow, luminous globes floating
on a mountain on Tagish Lake in Canada's Yukon Territory in the early 1970s. A
retired Canadian government agriculture inspector, Conacher took a photo of the
lights, which circulated widely as purported evidence of a UFO encounter.
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| Earthquake orbs |
Photograph
by Jim Conacher
Earthquake
lights are captured in this photo taken at Tagish Lake, in the Yukon Territory,
in 1972
Freund
and colleagues noticed that the timing of Conacher's photo seemed to place it
just a few hours before the nearby Cross Sound earthquake of July 1, 1973,
which measured 6.7 on the Richter scale.
For
many years, sightings of earthquake lights were dismissed by the serious
geology community. But in the mid-1960s, during a series of earthquakes in
Nagano, Japan, scientists made photos of earthquake lights that were clearly
tied to the geologic activity. Since then, an increasing number of the
phenomena have been captured on film and video, Freund said, in part because of
the rise of surveillance cameras.
For
example, cameras caught clear images of earthquake lights in Pisco, Peru, in
August 2007, during a magnitude 8 earthquake there.
How Earthquake Lights Form
Over
the past few years, various theories have been proposed for how earthquake lights
form, including the disruption of the Earth's magnetic field by tectonic stress
and the so-called piezoelectric effect, in which quartz-bearing rocks produce
voltages when compressed in a certain way. But Freund and colleagues now report
that what causes earthquake lights appears to be an entirely different
electrical process. "When nature stresses certain rocks, electric charges
are activated, as if you switched on a battery in the Earth's crust," he
says. The types of rocks that are particularly given to the phenomenon are
basalts and gabbros, which have tiny defects in their crystals. When a seismic
wave hits, electrical charges in the rocks may be released. In some areas,
basalts and gabbros are present in vertical structures called dikes, which
formed as magma cooled along vertical faults and may reach as deep as 60 miles
(97 kilometers) underground. These dikes may funnel electrical charges along,
the scientists wrote. "The charges can combine and form a kind of
plasma-like state, which can travel at very high velocities and burst out at
the surface to make electric discharges in the air," Freund added. Those
discharges are what make the colorful light shows. The right conditions for
lights exist in less than 0.5 percent of earthquakes worldwide, the scientists
estimate, which explains why the phenomena are relatively rare. Earthquake
lights seem to be most common in Italy, Greece, France, Germany, China, and
parts of South America, though they have been observed in Japan, North America,
and elsewhere. The
lights can occur weeks before major earthquakes, Freund noted, or during actual
shaking. They have been recorded at distances of up to 100 miles (160
kilometers) from the epicenter.
Predicting Earthquakes?
Freund
is working with other scientists on a global earthquake forecasting system and
says scientists have started including earthquake lights as an indicator that a
tremblor might be coming. He avoids the term "prediction" because
"it implies too much precision." "If we see two, three, or four
characteristic phenomena, then it looks like there might be an
earthquake," he said. He admitted that earthquake lights tend to be rare,
but added, "If they are observed, let's watch out." But others say
that the lights will be of limited use for such forecasts. "Earthquake
lights are unlikely to be very helpful with earthquake prediction because they
don't seem to be reported all that often," says Bruce Presgrave, a
geophysicist with the U.S. Geological Survey's National Earthquake Information
Center. Earthquake lights have already been used to help predict
quakes. Just before Italy's L'Aquila earthquake in 2009, a man in his kitchen
saw bright flashes of light. Because he had reportedly
read about earthquake lights before, he moved his family to a safer
place. In China in 1976, a geologist took shelter after seeing lights, which
were followed by the deadly Tangshan quake. Still, Freund says the lights are a
small part of his broader work involving the electrical conductivity of rocks. "I
wasn't interested in earthquakes in the beginning, but then I realized that
electrical phenomena are being activated by stress in the rocks," he says.
"Earthquake lights are the tip of the iceberg, the most extreme expression
of these phenomena, but underneath there are lots of other aspects, and we are
considering measuring these in the context of forecasting." As a next
step, Freund hopes to reproduce earthquake lights in a laboratory. He also
wants to better understand what causes the outburst of energy that leads to
visible light.
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