by Michael J. Oard

The woolly mammoth is the poster child for the Ice Age just as the polar bear is the poster child for global warming. A woolly mammoth is likely a member of the elephant kind with long hair up to 1 meter long, a hump on its head and top of its back, and a sloping lower back.1 It was once thought the woolly mammoths did not have oil glands in their skin, disastrous in a cold climate, but better samples show they did have them.2 The woolly mammoth lived all across the mid and high latitudes of the Northern Hemisphere during the Ice Age. Both the Ice Age and the many millions3 of woolly mammoths buried in Siberian permafrost, permanently frozen sediment, have been major uniformitarian mysteries for about 200 years4 despite numerous theories. Another type of mammoth, the Columbian mammoth, lived farther south in the United States and Central America.

Woolly mammoths lived alongside woolly rhinoceroses, cave bears, cave lions, saber-tooth tigers, ground sloths, dire wolves, the “Irish elk,” various types of horses, several types of bison, and many others. The Northern Hemisphere, even Siberia during the Ice Age, was considered to be like the Serengeti of Africa. Dale Guthrie of the University of Alaska in Fairbanks has called it the “mammoth steppe,” characterized by a wet spring and a dry summer with tall grass. Except for the carnivores, the Ice Age animals were grazers.

At the end of the Ice Age, many of the animals over 100 pounds (45 kg) as well as many carrion birds went extinct or disappeared from entire continents. There was a 70% loss in North America, 40% in Eurasia, 80% in South America, 90% in Australia, and only 20% in Africa. According to the uniformitarian paradigm, most of these animals were extinct by the end of the “last” ice age. Today, secular scientists think that within the past 2.6 million years of the Pleistocene there were about 50 ice ages of various severities.5 Between these ice ages or “glacials” were “interglacials,” warm periods after the ice melted. According to them, we are living in an interglacial period called the Holocene.

Uniformitarian scientists have argued over the cause of the mass extinction. Three possibilities have been suggested: 1) climate change, the “overchill hypothesis”; 2) man killed them in a great slaughter, the “overkill hypothesis”; or 3) man’s diseases killed them off, the “overill hypothesis.” Man is considered as a possible cause because mass extinction happened only near and after the last ice age, when man supposedly came on the scene. There is very little evidence for man’s role. Only a small number of human/mammal interactions have been found, such as spear points found in mammoth bones.

To make matters worse for the uniformitarian paradigm, the mass extinctions happened when conditions were improving. The ice sheets were melting, the climate was warming, and more territory was opening up. Mainstream science has always believed the extinctions took place during cold spells with the last die off occurring during the short cold spell of the Younger Dryas, except for Australia, that ended about 10,000 years ago. But recently several researchers claim the extinctions happened during warm periods.6 They now say most of the animals died well after the worst cold spell, called the “Last Glacial Maximum” or LGM, which is dated at 19,000 to 23,000 years ago and before the Younger Dryas.

Scientists recently discovered the existence of warm and cold periods during the “last” glacial period. These warm and cold periods are of short duration, supposedly on the order of a hundred to several thousand years long with the Younger Dryas being the last (fig. 1). The cold periods are called stadials and the warm periods interstadials. The evidence for these stadials and interstadials was found in Greenland ice cores and is thought to represent “abrupt climate changes,” a new paradigm in ice age research. The temperature change is supposed to be up to 20°C over much of the Northern Hemisphere and have occurred within just a few years to a few decades.7 It is interesting that after this discovery, scientists found stadials and interstadials in other records of the late Pleistocene, whereas they were rare before.8 The researchers fit the extinctions into these abrupt climate changes, mostly into the warm phases.9 But all these extinction dates depend upon a complete sample of Pleistocene fossils and very precise dates. Although what exactly would be an accurate representation of the samples from that layer would be difficult to assess, we know at least that the assumptions on which the dates are based are flawed, even if they seem precise.

Reporters could not help but throw in the global warming scare:

Although there’s still more work to do, Cooper hopes his findings might help to illustrate the importance of considering our own climate today. “If we’re right, and these warming events are the key problem,” he said, “it’s quite obvious that the current global warming trends are very worrying, because they in many ways represent the conditions of the start of an interstadial.”10

If we had no control over the past warming events, what makes people think we are the total cause of global warming and can stop a supposed new interstadial? The reality is that present-day global warming is extremely small, mostly due to natural forces, and climate model projections are greatly exaggerated.11

Within the uniformitarian paradigm, the Northern Hemisphere glacial and stadial periods were times of extreme cold, on the order of 10 to 20°C (18–36ºF) colder than the present day climate. Logically, the extreme cold should have caused mass death, but instead the new evidence points to extinction happening when the climate warmed. It is good to remember the warmer temperatures in the mid and high latitudes would not have been overly warm for the animals since the ice sheets were still melting. Ice sheets would cause cold pools of air to form since sunlight is reflected off of the ice. So to say the animals died from excessive heat, which would not have been warmer than today, is unreasonable.

The uniformitarian paradigm of ice ages struggles with mysteries they have not been able to resolve after 200 years of research. Changing the uniformitarian assumption of millions of years and accepting a global flood provides a straightforward solution.12 The conditions that existed after Noah’s Flood set the stage for the Ice Age. During the Flood there was a tremendous amount of volcanism and tectonic activity, which greatly tapered off after the Flood. The high amount of particulates in the atmosphere from the waning explosive volcanic activity partially blocked the sunlight for years. This made for very cool summers.

The oceans would be much warmer after the Flood from the heat that was added by the fountains of the great deep and underwater volcanism. Warm oceans, especially at the mid and high latitudes, had a very high rate of evaporation. The cool air over mid- and high-latitude continents and huge evaporation from the warm ocean caused heavy precipitation. The snow and ice would first build up in higher latitudes, such as Antarctica and central Canada, the latter far from the warm, moist onshore flow. The air is warmed by the warm ocean water, but as the air moves inland, it cools. The lowlands of Siberia would not have glaciated because of warm, moist air from the oceans, explaining another mystery of the Ice Age. Mild winters and heavy precipitation would have supported forests early in the Ice Age because of the onshore flow. The forests would give way to a grassland as the Ice Age wore on and the air became drier due to cooler ocean temperatures.

In the post-Flood model, the winters would have been much warmer than they are today and the summers much cooler because of warmer ocean temperatures and volcanic particles. Around the globe there would have been far greater precipitation caused by the warmer ocean temperatures as modeled by Dr. Larry Vardiman.13 Until the end of the Ice Age, there was very little contrast between the seasons. For the first part of the Ice Age the warmer winters allowed many animals to pass through Siberia into the lowlands of Alaska and the Yukon. From there they would have traveled southeast down an ice-free corridor on the east side of the Rocky Mountains, and continued into the southern United States, Central America, and South America. Eventually the corridor was blocked. Ice Age fossils give support to the mild winters and the small contrast between the seasons, even at high latitudes, but contradict the uniformitarian model.14

The post-Flood Ice Age was very dynamic. As the oceans cooled and volcanism waned, the climate trended toward the present. The summers became warmer and melted the ice, causing sometimes catastrophic melting. The Lake Missoula flood is an example of the extensive flooding that sometimes took place.15 Winters gradually cooled to below today’s climate.

Freshwater tends to float on salt water, as noted when the Mississippi River water spreads to off the coast of Georgia.16 Seawater is very difficult to freeze, but a top layer of freshwater would freeze rapidly during deglaciation. The high-latitude oceans would freeze rapidly, greatly reinforcing the already cold winters and drying out the atmosphere even more. As the lower latitudes warmed, the higher latitudes became even colder, especially with the presence of ice sheets. Because of these forces, the late Ice Age winter climate would have been very cold and very windy with “dry” storms and much blowing dust. These extreme storms would have had a disastrous effect on the large mammals, causing the mass extinctions noted around the globe during deglaciation.

At the end of the Ice Age, giant dust storms would have occurred in Siberia, as evidenced by thick windblown sediments. These dust storms would easily cover up dead animals and thus account for why the bones and tusks of the mammoths are so well preserved. Moreover, the strongly developing permafrost and the cold air would quickly freeze the remains within the windblown sediments. This accounts for how they were entombed into rock-hard permafrost. Blowing dust would cause some mammoths to suffocate and die in a general standing position as some have been found (fig. 2).17

Some carcasses, of which there is a very small number compared to the skeletons, remained frozen with partially decayed stomach contents. The reduced state of decay is mostly because elephant digestion takes place after the stomach.18 The remains must be frozen moderately fast, but a snap freeze in not required. Some carcasses show broken limb bones from either trying to extricate themselves from the dust packing around them or by permafrost faulting.

The woolly mammoth, which lived across the mid and high latitudes of the Northern Hemisphere, is one of dozens of animals that went extinct at the end of the Ice Age. Uniformitarian scientists have been unable to explain this mass extinction. Whereas animals were believed to have died during cold periods, a new theory suggests instead they died during warm periods. However, this theory is unreasonable because it is normally cold that stresses animals. With the existence of ice sheets, these “warm periods” would have been cooler than or at best similar to today and less stressful than very cold winters. The post-Flood rapid Ice Age can explain the huge number of Ice Age animals because winters were mild and summers cool early in the Ice Age. The mass extinction occurred because, near the end of the Ice Age, winters became much colder and drier than today, causing strong, windy dust storms. It is these powerful dust storms that can explain the extinctions and the data from Siberia. Figure 2 summarizes how dust storms and faulting permafrost can account for all the many mysteries of the extinction of the woolly mammoths, especially in Siberia.