December 25, 2021
Nibiru is a pain in the ass. When the Annage arrived here between 450,000 and 432,000 years ago, Earth was in the midst of an ice age. They set up shop in ancient Shumer, on what is now the floor of the Persian Gulf. The end of the last ice age came rather abruptly, and it was catastrophic for the Annage.
I don’t put much stock into Noah's “40 days and nights”—it was more likely 40, or even 400 years in length. Whatever the true number, Noah’s story is likely the result of abrupt climate change that caused sea levels to rise by hundreds of feet. This makes sense when we consider that glaciers miles high at both poles were melting.
There is some geological evidence suggesting that as Nibiru nears Earth, we see an increase in volcanic and tectonic activity. It is thought that the end of the last ice age was triggered by Nibiru’s passage. The resultant volcanic and tectonic upheaval, caused by its gravitational pull, led to massive ice loss and rising sea levels.
When we look at our article “Where Are You?”—a scientific paper using statistics to search for Nibiru—we're given an approximate timeline for locating the “planet of millions of years.” It’s likely it will be discovered within the next ten years. As exciting as that is, I’m just as eager to determine where it is in its orbit: perihelion (closest point) or aphelion (farthest point). Regardless of its current position, we still feel its gravitational effects on Earth through geological changes.
As for the events surrounding Noah’s flood, it is believed the greatest water damage—tsunamis and the like—came from the south. Other accounts suggest the floods were caused by meltwater runoff from rivers. Remember, these events occurred at the end of an ice age. The mountains around the Horn of Africa would have been snowcapped, and yes, there would have been rivers running through the desert.
The only thing in the south big enough and icy enough to cause such chaos is the continent of Antarctica. The flood may have been caused by massive ice sheets sliding off the continent—an event not unlike what we’re witnessing today. Although we can’t be certain, I believe today’s scenario is a combination of both Nibiru’s approach and human-caused global warming.
Three and a half billion years later, there are still continent-sized chunks of solid rock floating around in Earth’s mantle. I believe these are undigested remnants of Nibiru’s moon, left over from the planetary collision. As the weight and pressure on Earth's crust ease due to melting glaciers, the planet will continue to "burp"—meaning volcanic activity is likely to increase.
This is particularly relevant in Antarctica. As of May 2020, we know of 138 dormant volcanoes there. Unfortunately, as with all volcanoes, there is no reliable way to forecast if or when they will erupt.
During the worst of Noah’s crisis, the Annage—under instruction from Enlil/El Shaddai—took refuge aboard their shuttles and orbiting satellites, crowding 600 or more aboard and leaving millions of us to drown. Millions died then. The numbers could be far worse now—perhaps not by drowning, but by the cumulative effects of global climate change, as described in the Old Testament.
Here is some data on what’s happening in Antarctica. As the Earth warms due to climate change, glaciers are beginning to shift. Researchers believe that landscapes sloping inland will increase the speed at which glaciers move. Because a canyon has been found beneath the Denman Glacier, scientists can better anticipate how nearby ice will move in the future.
However, other powerful forces of nature are also at play. While the canyon may accelerate glacier movement, other geographical features can counteract this. This, in turn, may reduce the impact on sea levels. One example is the Transantarctic Mountains, which separate eastern and western Antarctica and span more than 2,000 miles.
Multiple glaciers have formed near these mountains and flow into the Ross Sea. Their movement is hindered by a large sheet of floating ice. While there's concern that this sheet may melt, it currently remains intact. By doing so, it prevents the glaciers from advancing, helping keep sea levels steady.
The BedMachine project recently revealed new findings that ease previous concerns. Earlier models suggested that if the ice sheet melted, glacier flow into the Ross Sea would increase. Fortunately, data from the project suggests otherwise. By studying the terrain beneath the ice, researchers discovered a high ridge running below. This ridge could slow or even halt glacier movement into the sea—even if the ice melts.
This could significantly impact the Ross Sea ice shelf. By slowing glacier drainage, the movement of the ice shelf—and thus water levels in the Ross Sea—would also be affected. Researcher Mathieu Morlighem has expressed optimism. He believes that even if the shelf were to melt or collapse, it likely wouldn’t seriously affect East Antarctica.
If something serious does ever happen in this region, it won’t be because of the Ross Sea ice shelf. That’s certainly good news, especially given how long it's been a concern.
Unfortunately, there’s also bad news. Across the icy continent lies the Amundsen Sea—part of the vast Southern Ocean surrounding Antarctica. Discovered in 1920 by Captain Nils Larsen, the sea itself isn’t the problem—it’s what’s flowing into it.
A massive glacier is continually flowing into the Amundsen Sea.We don’t know how long this has been happening, but the glacier is estimated to be the size of the United Kingdom. It has become one of the fastest-moving ice shelves in the region, shifting more than a mile each year. And it shows no signs of slowing down. In fact, it may be accelerating.
If this trend continues, no one knows how fast it could move before it finally collapses. This glacier is known as the Thwaites Glacier, named after Fredrik T. Thwaites, a geomorphologist and glacial geologist from the University of Wisconsin. His father, Reuben Gold Thwaites, was a prominent historian.
In the 1970s, Terry Hughes—professor emeritus at the University of Maine—was one of the first to predict the glacier’s collapse. His prediction was validated by a 2001 study using satellite radar data, which showed the glacier was out of balance and steadily moving. Thwaites has also earned the nickname “Doomsday Glacier” due to the potential impact it could have on global sea levels.
Unlike the Ross Sea, the land beneath Thwaites lacks any supportive ridges. Only two ridges are nearby, both miles away. Once the glacier passes them, there may be no way to stop it.
As the University of Washington study predicted, the question is no longer if Thwaites collapses—but when.
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