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Speaker 1: Thanks for listening to the best of Coast to Coast podcast,

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Speaker 1: Insider to catch up on what you may have missed

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Speaker 1: from Coast to Coast. Now here's a highlight from Coast

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Speaker 1: to Coast AM on iHeart Radio and welcome back to

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Speaker 1: Coast to Coast dr Sky with us Stephen Kate. Stephen,

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Speaker 1: there is a way to predict cycles of eclipses that

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Speaker 1: apparently happened every two and twenty three months or so.

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Speaker 1: It's the Seris system. What is that? This is fascinating

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Speaker 1: and good to be back here, you know, a long

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Speaker 1: time ago, and this is where we have to give

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Speaker 1: credit to the ancients. How they did this is still

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Speaker 1: the greatest of mysteries because today with advanced computers, even

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Speaker 1: calculating to the tenth or million millisecond of how these

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Speaker 1: eclipses started. Something that's been around for a long time

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Speaker 1: is the subject of say Ros cycles. There were a

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Speaker 1: cycle of repetitive eclipses every eighteen years and eleven days.

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Speaker 1: Dot dot dot as we go across the page. Now

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Speaker 1: what that means if we put this in perspective to

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Speaker 1: this particular total solar eclipse that we're having, This one

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Speaker 1: is a siros, and there's literally hundreds of these say

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Speaker 1: ros is that astronomers have calculated on into like even

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Speaker 1: twenty four thousand years from now. This particular eclipse that

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Speaker 1: we're going to see here in August one, literally somewhat

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Speaker 1: ten days, eight hours and some odd change away, is

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Speaker 1: part of a serros called one has seventies sevent eclipses

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Speaker 1: inside that particular serros. This is number twenty two. And

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Speaker 1: think about this. It started back on January the fourth

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Speaker 1: of sixteen thirty nine with a partial eclipse of the Sun.

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Speaker 1: Will end successfully on April the seventh. One. Of course,

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Speaker 1: we're long gone to the infinite in three thousand and

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Speaker 1: nine a d. So the point is these repetitive cycles,

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Speaker 1: there's so many of them. This particular eclipse has a

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Speaker 1: relationship to one that took place in over Europe. And

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Speaker 1: what's really fascinating about this is in a calendar year,

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Speaker 1: you theoretically can get up to about seven eclipses, but

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Speaker 1: usually it's less than that. And if you take this timeline,

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Speaker 1: and this is very interesting, between nine and the year

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Speaker 1: three thousand a d there's going to be almost to

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Speaker 1: the number twelve thousand solar eclipses of that total. Get

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Speaker 1: a lot of this to show how really infrequent these are,

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Speaker 1: but maybe not so. There are three thousand, one hundred

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Speaker 1: and seventy three total solar eclipses within that period of time,

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Speaker 1: and only five hundred and sixty nine of those are

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Speaker 1: the rarest and strangest of all eclipses called a hybrid eclipse.

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Speaker 1: And folks may want to know what's that when unfortunately

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Speaker 1: the moon is too small, meaning at apogee or farthest

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Speaker 1: away from us. If you take this phenomenon, if you

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Speaker 1: take let's say a nickel and put a dime on

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Speaker 1: top of it, the dime would be the moon. It's

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Speaker 1: smaller than the diameter of the nickel, so you get

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Speaker 1: this annulus of light around it. But in this particular case,

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Speaker 1: with hybrid eclipses, George, this is even stranger. You have

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Speaker 1: just a bare amount of sunlight streaming around the full Sun,

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Speaker 1: and then as the Sun and Earth move, it transforms

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Speaker 1: itself like a magical transformer, from a very very fine

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Speaker 1: annular eclipse back to total. But say, roses are the

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Speaker 1: science behind this sacred geometry, And George, I still go

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Speaker 1: back to this and don't even have an answer, and

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Speaker 1: I don't I wonder out there. I mean, all the

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Speaker 1: great guests you have on the show talking about the

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Speaker 1: predictability of eclipses that go back, unfortunately to two Chinese

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Speaker 1: individuals who failed to predict the solar eclipse along time

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Speaker 1: ago and be seen and High and Hoe. They did

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Speaker 1: not understand okay lated eclipses, and sadly, probably atle like

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Speaker 1: North Korea, they were executed for failure to provide the

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Speaker 1: emperor with this longevity thing. In those days, eclipses might

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Speaker 1: have been looked at as a good thing. But unfortunately,

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Speaker 1: and we now know, one of the old total eclipses

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Speaker 1: or some eclipses of the sun happened back on October BC. Sorry,

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Speaker 1: High and Ho they're not around to tell the story,

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Speaker 1: of course, and didn't live. Sounds like Santa's elves or something,

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Speaker 1: but no, seriously, sero cycles. To put it in perspective,

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Speaker 1: these are the repetitive cycles of eclipses. And you may

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Speaker 1: be wondering, folks, as you're listening in George, why don't

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Speaker 1: we see with this so called sacred geometry, why do

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Speaker 1: we not see an eclipse of this particular earth, I

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Speaker 1: mean of the Sun and the moon every calendar month.

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Speaker 1: And the simple answer is list very few of these

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Speaker 1: eclipses crossed these nodal points, since the Moon is inclined

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Speaker 1: a little bit above or but this is perfect point right.

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Speaker 1: And then finally this is I think this is what

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Speaker 1: really on this particular show. I think the people get

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Speaker 1: very introspective on this subject. And of course you know best.

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Speaker 1: But when you take a look at sacred geometry, figure

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Speaker 1: this out, folks. The moon is two thousand, one hundred

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Speaker 1: and fifty nine miles across. It's the diameter of distance

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Speaker 1: slave from Phoenix to New York City, an object that's small,

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Speaker 1: with the sun almost a little about eight hundred and

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Speaker 1: sixty five thousand miles. How does that happen here in

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Speaker 1: the Solar system on a regular basis? Where else I

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Speaker 1: should say, does it happen. But here on the Earth

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Speaker 1: we have this sacred geometry that happens ever so often.

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Speaker 1: The ever so often is coming up in ten days.

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Speaker 1: And George, this is the sad part. The Moon is

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Speaker 1: slipping away from us a few centimeters a year. We

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Speaker 1: know that. So we'll no longer have eclipses of the

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Speaker 1: Sun in about six hundred million years. How about that.

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Speaker 1: That's fantastic. So now let me ask you some other

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Speaker 1: space questions. October twelfth of this year, an asteroid that

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Speaker 1: could be forty two hundred feet is going to pass

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Speaker 1: within forty miles from the planet. Yes, that's pretty darn

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Speaker 1: close it is. And George, as you know, I mean

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Speaker 1: we talk every Monday, right, we talk every Monday? And

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Speaker 1: how many times do we lead off where you lead

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Speaker 1: off with a news story? Here goes another asteroid, but

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Speaker 1: this one write it down, folks, remember it tc like

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Speaker 1: Tom Charles, number four is an Apollo class asteroid that

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Speaker 1: orbits the Sun every six nine days. And as you

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Speaker 1: reported accurately, at least the best information we can read

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Speaker 1: out there on the web. We don't always believe everything

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Speaker 1: we read. But the point is this geo stationary satellite

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Speaker 1: it rounded off the miles. This house size asteroid is

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Speaker 1: going to slip through hopefully, not know any closer than that.

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Speaker 1: But George, I've heard other numbers too. I mean this

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Speaker 1: is and really digging into this, I've heard closest as

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Speaker 1: potentially for two miles or as far away, and get

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Speaker 1: a load of the far away. It's still within the

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Speaker 1: zone of the Earth's I call it the Earth's ring.

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Speaker 1: Look at how many geostationary satellites. The Earth has a

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Speaker 1: ring like Saturn, and even though it doesn't have a

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Speaker 1: ring made from planetary material, it's man made. That's close.

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Speaker 1: They say that if it did hit the planet, it

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Speaker 1: would cause great level of impact damage. What does that mean, Well,

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Speaker 1: this is where the uncertainty lies. The Chillia Bin object,

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Speaker 1: which was probably on the order of sixty feet plus

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Speaker 1: that screamed through the skies back in February. That's injured people,

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Speaker 1: but you bet, and it actually the most people need

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Speaker 1: to know this, Most of the damage did not occur

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Speaker 1: from impact material. It happened from the incredible air sonic boom.

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Speaker 1: The concussion we call concussion, the shock wave, a compression

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Speaker 1: wave through the atmosphere. Now, if this object was sixty

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Speaker 1: six ft across, and they did recover some particular parts

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Speaker 1: of Chilia Binsk. But in this case, George, it's really

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Speaker 1: anybody's guess. And I always used this example, not just

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Speaker 1: here in Arizona, but across the audience. I think they'll

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Speaker 1: appreciate this foreign wide the eat Arizona meteorite Crater. I'm

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Speaker 1: not a tourism director for Arizona, but if you happen

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Speaker 1: to come out here in Arizona, folks, stop and see

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Speaker 1: just forty miles to the east of Flagstaff, near two Guns,

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Speaker 1: that's the name of the town, this amazing preserved fossil,

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Speaker 1: allegedly a two hundred foot object. Nico Liron screamed and

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Speaker 1: ripped the sky apart some fifty thousand years ago and

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Speaker 1: made a one mile ish crater that's only two hundred

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Speaker 1: feet across, and he came in at an oblique angle.

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Speaker 1: So could you imagine if something like that came straight

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Speaker 1: down the point? Is even an object like TC two

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Speaker 1: thousand and twelve TC four, Well, that could cause uh,

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Speaker 1: that could cause a lot of people to have a

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Speaker 1: very bad day. Saying it mildly, I think so too. Okay, Now,

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Speaker 1: Cassini diving towards Saturday. Next month, NASA's Cassini spacecraft will

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Speaker 1: end a thirteen year mission to Saturn by plunging into

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Speaker 1: the body of the ring planet. But first Cassini is

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Speaker 1: going to skim the atmosphere about five times. This has

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Speaker 1: been a very successful mission, hasn't it. George. Dr Caroline Porco,

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Speaker 1: who you probably had on the show, you know, so

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Speaker 1: involved with this Cassini mission. It is outstanding. And as

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Speaker 1: we go about our busy lives on planet number three here,

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Speaker 1: just remember the good folks at GPL and other space

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Speaker 1: related organizations. Of course NASA, we have learned so much

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Speaker 1: about this planet. Galileo, when he first looked at this

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Speaker 1: planet in the telescope, never fully comprehended that it was

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Speaker 1: a ring. He thought there were two massive satellites along

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Speaker 1: the equatorial plane. His simple, you know, telescope could not

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Speaker 1: reveal the detail. But with Cassini thirteen years in kicking strong,

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Speaker 1: eventually the object runs out of propellant and eventually, in

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Speaker 1: another sad way, they may even be running out of funding,

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Speaker 1: who knows. But what's happening is the ring system of center.

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Speaker 1: It is literally an intricate pattern of moving debris in

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Speaker 1: various orbital planes. In other words, that doesn't move as

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Speaker 1: one sheet. It's like you couldn't drive a car around

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Speaker 1: it like it's a race track or a vehicle. It's

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Speaker 1: made up of objects that may be as small as pebble,

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Speaker 1: little grains of sand and pebble, all the way up

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Speaker 1: to maybe even sizes of SUVs and maybe even the

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Speaker 1: chunks of the size of homes. But it's looking to

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Speaker 1: explore the dynamics of this ring system because George, well,

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Speaker 1: within those rings, we're finding these tiny shepherd moons and

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Speaker 1: it's so cool. If you look at cassen these images,

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Speaker 1: you see these tiny little specks that look like dandruff

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Speaker 1: in the sky, but they're little satellites maybe a half

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Speaker 1: a mile, maybe a couple of hundred feet. And what

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Speaker 1: they do is they bring out ten drills of material

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Speaker 1: from the rings and gravitationally pull them. So Cassini is

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Speaker 1: going to skim as you mentioned the atmosphere some five times.

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Speaker 1: It's going to look and penetrate through there. But what's

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Speaker 1: going to happen. Sadly, it meets its demise as it

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Speaker 1: goes into Mother's Saturn, most phenomenal planet George, look at

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Speaker 1: the top of the planet. The hexagonal storms that we've seen.

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Speaker 1: Oh my gosh, that is just totally bizarre. I'll always

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Speaker 1: remember the first time I had a telescope, cold Detroit

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Speaker 1: night and I'm out there looking at the stars and

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Speaker 1: planets and I see Saturn and with that small three

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Speaker 1: inch refractor television telesphope telescope, Steven, I could see the

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Speaker 1: rings just kind of floating out there. He was gorgeous.

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Speaker 1: It's amazing. And you know, we do this a lot.

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Speaker 1: We do programs in Sedona all over the place, and

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Speaker 1: I highlight Sedona because of their dark sky laws that

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Speaker 1: they have and there who keep the sky's dark. We

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Speaker 1: show this and no matter where we are here in Phoenix,

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Speaker 1: we're traveling around the country. You're right, you see this.

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Speaker 1: And somebody says to me, Okay, take the thing out

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Speaker 1: of inside of your telescope. You've got like a little

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Speaker 1: thing hanging inside there. Right, it looks not unreal, like surreal,

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Speaker 1: but it's amazing. And think about this. The diameter of

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Speaker 1: the ring system of Saturn is technically the largest object

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Speaker 1: in the Solar System. From ring edge to ring edge,

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Speaker 1: it's a d seventy thousand miles plus stupid Jupiter, of

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Speaker 1: course eighty five or eighty six thousand miles eight, depending

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Speaker 1: on who you ask. But you're right and what you see, George,

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Speaker 1: and I'm watching this a few nights to go here.

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Speaker 1: We have monsoons still pretty strong here in Arizona this

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Speaker 1: time of year, like most people know. But as you

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Speaker 1: look at the Ring system, just about five or six

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Speaker 1: ring diameters away, there's another strange object that's even visible

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Speaker 1: in a three inch refractor and maybe even a smaller scale.

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Speaker 1: It's Titan, the largest satellite of Saturn towards That's an

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Speaker 1: amazing world. It's got oceans made of octane, sure does.

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Speaker 1: It's incredible. Listen to more Coast to Coast a m

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Speaker 1: every weeknight at one a m. Eastern and go to

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Speaker 1: Coast to Coast am dot com for more