The Earth is older than 6-10k Years old

When molten rock cools, forming what are called igneous rocks, radioactive atoms are trapped inside. Afterwards, they decay at a predictable rate. By measuring the quantity of unstable atoms left in a rock and comparing it to the quantity of stable daughter atoms in the rock, scientists can estimate the amount of time that has passed since that rock formed.

Ideally each ring can be precisely dated to the year of its growth. As a result, dendrochronology has served as the standard for the last 10,000 years by which other methods such as radiocarbon are calibrated. Most tree species typically produce annual growth rings characterized by a light-colored earlywood band that grades into a dark-colored latewood band. The following year’s growth ring is sharply demarcated from the preceding year’s growth ring. Although many trees generate rings of approximately constant thickness from year to year, trees sensitive to stressful changes in environmental conditions such as temperature and humidity will produce rings that vary in thickness from year to year. Growth is generally promoted by higher average temperature and high precipitation. It is the sensitive tree species that are the best suited to dendrochronological dating because, to determine when a tree lived and died, portions of its ring pattern are matched to ring sequences with similar relative thickness variations in a standard master chronology

Ice cores provide the most direct and highly resolved records of (especially) atmospheric parameters over these timescales. They record climate signals, as well as forcing factors of global significance such as greenhouse gases and of more regional significance such as atmospheric aerosol content. Until now, ice-core data have been available only for the past 420 kyr, with the longest record coming from Vostok in East Antarcticahese data indicated the similarities of the last four glacial terminations. They showed that glacials and interglacials had similar bounds in the measured properties over the last four cycles. Most tellingly, they showed the very close association between greenhouse gases 

South African rocks studied by geologist Ken Eriksson contain ancient tidal deposits indicating that at some point in the past, the Moon orbited "25-percent closer to Earth than it does today."The distance between the Earth and the Moon is 384,403 kilometers, so for Ken Eriksson's work to fit with a YEC timescale the Earth would have to have been receding at a speed greater than 15 kilometers per year. However, the Moon is currently receding from the Earth at a rate of 3.8 centimeters per year.

More recent work on Precambrian sediments gives more precise numbers. From Neoproterozoic (620 million years ago) "tidal rhythmites" in Elatina and Reynella, Australia, the Moon's major axis had a value 0.965 ± 0.005 times its present-day value. That implies an average recession rate of 2.17 ± 0.31 cm/yr, a little more than half the present-day rate of 3.82 ± 0.07 cm/yr. Going back further to banded iron formations in Western Australia in the Paleoproterozoic (2450 Mya), one finds a major-axis ratio of 0.906 ± 0.029, and an average recession rate of 1.24 ± 0.71 cm/yr over most of the Proterozoic So for whatever reason, the Moon is now outspiraling relatively rapidly.

1. First, Snelling has oversimplified the processes of rock deformation by stating that it is either ductile deformation of soft rocks, or plastic deformation of soft rocks. It is one thing to simplify a scientific concept for the sake of writing for a general audience, but Snelling has completely mislead his readers on this one.

Snelling states that only soft sediments are capable of ductile deformation; that soft sediments will deform like clay, while solid rocks are brittle and only capable of fracture. In reality, most solid rocks are capable of either brittle or ductile deformation, depending on the conditions. Factors that determine which will happen include the type of rock, the amount and type of stress applied to the rock; lithostatic pressure (due to the weight of overlying rocks), temperature, strain rate (fast or slow deformation), type of cement holding the grains together, and fluid pressure.

At low temperatures and pressures, such as those encountered at Earth’s surface, almost all rocks deform in a brittle manner. If one applies sufficient stress to these rocks, they will break. As one goes deeper in the Earth’s crust, temperature and pressure increases, and rocks are more likely to behave in ductile rather than a brittle fashion.  Some rock types can deform by folding at depths of less than one kilometer if stress is applied slowly. With increasing depth and temperature, more rock types can deform by folding rather than faulting.

The Tapeats Sandstone is presently buried beneath up to two kilometers of sediment, and was likely buried more deeply than this at the time of deformation.

2. A second problem for Snelling’s argument is that there are a variety of mechanisms by which a solid rock can bend rather than break. Think of a layer of sandstone, such as the Tapeats Sandstone at the base of the Grand Canyon Paleozoic sedimentary pile. A layer such as this can be folded without significant fracturing by several means:

1. Intergranular movement — individual sand grains slide past each other
   
2. Intragranular deformation — internal distortions within individual grains, often at the atomic level
   
3. Recrystallization — atoms are rearranged at the atomic level, often in the presence of fluids.
   

Snelling completely ignores these, even though any of them could have been in operation at the time of deformation.3. A third—and very serious—problem for Snelling’s argument is the nature of soft-sediment deformation. He tries to show that intense folding in the Tapeats Sandstone is the result of soft-sediment deformation. But if the Tapeats and overlying formations had been soft at the time of deformation, soft-sediment deformation and slumping would have occurred on a much larger scale than what is seen at this location in the Grand Canyon.

When layers of solid rock deform, they maintain their integrity as distinct layers. For example, whether folded or faulted, the Redwall Limestone of the Grand Canyon retains its identity as a distinct layer, without mixing with other rock units. Soft sediments, on the other hand, can respond to stress in a number of ways. In addition to folding, a results of deformation of soft sediments includes different types of soft sediment deformation and differential loading structures, such as intense localized folding, diapirs, sand pillows, and clastic dikes These structures are formed because of the inherent instability of a stack of unconsolidated sediments of varying densities and water contents.Soft sediment deformation structures are common within individual layers of the geologic column, having been formed when these layers were unlithified. For the young-Earth creationists to make their case, however, they need to be able to demonstrate that soft sediment deformation is present in the geologic record on a massive, inter-formational scale. It would not be enough to point out isolated instances of soft-sediment deformation within layers.

4. Related to the problem of soft-sediment deformation is the problem with slumping. If this stack of sediments—a few thousand meters thick—were faulted as in Figure 1, one would expect the upper layers to slide downhill under the influence of gravityAs a rule, this sort of thing is not observed in the geological record, and where it is (e.g. Heart Mountain, Wyoming) it clearly occurred in the solid state.

A new study reveals that the water in many comets may share a common origin with Earth’s oceans, reinforcing the idea that comets played a key role in bringing water to our planet billions of years ago.

“dinosaur soft tissue is closely associated with iron nanoparticles in both the T. rex and another soft-tissue specimen from Brachylophosaurus canadensis, a type of duck-billed dinosaur. They then tested the iron-as-preservative idea using modern ostrich blood vessels. They soaked one group of blood vessels in iron-rich liquid made of red blood cells and another group in water. The blood vessels left in water turned into a disgusting mess within days. The blood vessels soaked in red blood cells remain recognizable after sitting at room temperature for two years.”

“lava flows that have occurred in the present have been tested soon after they erupted, and they invariably contained much more argon-40 than expected. For example, lava flows on the sides of Mt. Ngauruhoe, New Zealand, known to be less than 50 years old, yielded “ages” of up to 3.5 million years.”

He goes on to conclude, “it is logical to conclude that if recent lava flows of known age yield incorrect old potassium-argon ages due to the extra argon-40 that they inherited from erupting volcanoes, then ancient lava flows of unknown ages could likewise have inherited extra argon-40 and yield excessively old ages.”

“the radioactive decay of uranium in tiny crystals in a New Mexico granite yields a uranium-lead “age” of 1.5 billion years. Yet the same uranium decay also produced abundant helium, but only 6,000 years worth of that helium was found to have leaked out of the tiny crystals.

This means that the uranium must have decayed very rapidly over the same 6,000 years that the helium was leaking. The rate of uranium decay must have been at least 250,000 times faster than today’s measured rate.”

According to Snelling, “Because of such contamination, the less than 50-year-old lava flows at Mt. Ngauruhoe, New Zealand, yield a rubidium-strontium “age” of 133 million years, a samarium-neodymium “age” of 197 million years, and a uranium-lead “age” of 3.908 billion years!”

“Dr. John Baumgardner, with the cooperation of others, has used world-class computer modeling to show how the subduction (sinking into the mantle) of the ocean floor could have happened at a quick pace. As the region of cold ocean crust near the continents began to sink into the mantle, it pulled the rest of the seafloor with it. New magma rose up replacing the old along what are the mid-ocean ridges today. In just a matter of weeks, the continental plates could have separated and settled near their present positions.”

“As the magma rose to replace the spreading seafloor, it would have produced massive jets of steam carrying large amounts of water high into the atmosphere. This matches the description in the Bible and provides a mechanism to explain where all of the water for the Flood came from.
Another effect would be flooding across the continents. As the hot, lower-density magma rose, the new ocean floor would have floated higher than the original ocean crust, displacing the water and forcing it onto the continents. This explains how marine creatures were deposited in thick and extensive layers across the continents and how fossils of marine organisms wound up on the tops of the mountains. The secular uniformitarian model has great difficulty explaining these features.”

“[In order to date visually,] Scientists must visually compare the appearance of growth rings, noting where some rings appear thicker or thinner. They then match the patterns in dead trees to other trees. In this way, scientists establish a hypothetical series of rings, some thin and some thick, going back thousands of years for each species.”

“this involves massive layers of questionable interpretation. Matching growth rings between different wood samples is called “cross-dating” or “cross-matching.” Though it seems this matching would be easy, counting growth rings is tedious, and visually cross-matching similar ring patterns and specific growth rings from sample to sample is highly subjective. There can be major variations from tree to tree in a forest and, accordingly, in the wooden beams used to build houses. “

“So scientists don’t rely on visual comparisons. They use radiocarbon (14C) dating of growth rings to obtain their approximate age. Then they match this information to the associated pattern of rings in the master tree-ring chronology. However, ironically, radiocarbon dating is calibrated and corrected using tree-ring chronologies. So conclusions about tree-ring ages depend on radiocarbon dating, which depends on tree rings, which depends on radiocarbon dating. Neither tree-ring counting nor radiocarbon dating is conclusive alone.”

“Consider the World War II fighter plane abandoned on a Greenland glacier in 1942. When history buffs tried to recover the plane 46 years later, they were astonished to find that more than 250 feet (75 m) of ice had already entombed it. That 250 feet held many more layers than the 50 it should have had if only one layer had accumulated every year.

And we don’t have to be scientists to know that snow usually leaves more than one layer a year. Snow layers are visible every time snow falls through the winter months. When you clear your driveway or sidewalk of snow, you can see snow layers in the banks of accumulated snow you just shoveled through.”

“He and his graduate students tested alternative possibilities. They examined computer records of known storms to simulate their behavior if the surface of the ocean were hotter, as it was in the early decades after the Flood. (Remember those hot volcanic waters that were released from “the fountains of the great deep” at the start of the Flood? They would have raised the ocean water temperatures considerably.)
These researchers found that huge storms would have swept across polar regions, dumping many inches of snow every week. As the surface melted between these storms, 20 or more ice layers could easily have accumulated every year during the first century or two after the Flood. The same time period saw many dust-producing volcanic eruptions, as supervolcanoes rocked the earth and the planet settled into relative quiet after the cataclysmic upheavals of the Flood. So most of the ice core layers would probably have accumulated during the turbulent centuries of the post-Flood Ice Age.”

“another serious procedural error is that there is no distinction in the amount of Helium diffused that separates 3Helium from 4Helium. One may wonder why such a detail would matter; after all, Helium is Helium, right? Most of the 3Helium would not have been caused by decay while most-if not all-of the 4Helium would be the result of decay, so to simply state that a certain amount of Helium diffused from the rock would be inaccurately representing the facts.”

“In the scientific study of continental movement, we learned that there are submarine spreading zones marked by intermittent basalt eruptions that force the continents apart. We also know that the Earth's magnetic field occasionally reverses polarity. As the rock of submarine basalt ridges cools, it records the magnetic polarity of the planet. Basalt on continents does the same thing, but not quite so well. Below is a map of the magnetic reversals recorded from a submarine spreading zone, and the corresponding map of these polarity changes from a stacked series of continental basalts;”

““Layers in lake sediments contain pollen that reveals the identity of the plants growing near the lake at any particular time. Like annual layers of Greenland ice cores, those (termed varves) in lake sediment cores can often be counted visually and in both cases, chronology has been confirmed by ash (tephra) from dated eruptions. Change in climate markedly alters the species of pollen in the lake sediment layers reflecting changes in plant ecology. Very marked changes occurred at the termination of the last known glaciation (11,600 years BP) and even the minor cold period at 8,200 years BP was detected by changes in varve pollen species. However, no change was recorded in numerous lake sediment pollen profiles at or near 4,000 years BP.”

“The electrical conductivity measurement determines the d.c. conductance between electrodes on a fresh ice surface. Dielectric profiling determines the conductivity of the ice at higher frequencies. Both were measured in the field at a temperature of -20 ± 2 °C, corrected.to -15 °C. Data were collected at high resolution and averaged to 1 m. Vertical thin sections were prepared in the field at a periodicity of 10 m, then digitized and analysed using an image analysis procedureto determine the mean grain radius. A 3.4 cm × 3.4 cm strip of ice was melted on a hotplate in the field, and fed into various detectors. Aliquots (1.1-m averages) were also collected from this melting device into clean containers, frozen and shipped to Europe for ion chromatographic analysisf major ions (presented for Termination V). All other measurements were made in laboratories in Europe after the ice had been shipped frozen from Dome C. δD was determinedon meltwater from 55-cm-long sections. This record,still discontinuous for some parts, should be considered as preliminary. Also, we used a ‘quick’ mode (each sample is measured twice instead of four times), leading to a typical accuracy of 1.5‰ (1σ), whereas we aim for a final precision of 0.5‰ over the entire core, as currently obtained for EDC96 (the upper 780 m).

Computer models have been constructed to simulate such a giant impact. The results have strained the hypothesis to the breaking point. One of the new dynamical results is that the debris from the collision would rain back down onto Earth instead of remaining in orbit and forming the moon. To hurl the debris far enough from the earth, the impactor would need to be three times the size of Mars. The results of such a collision are hard to understand, much less model. And if the moon did form after such a collision, the orbit would likely be unstable with a distance of only 14,000 miles above the earth and circling it every two hours. Lissauer also noted the unsolved problem of losing the excess angular momentum.

A third problem is that there is too much iridium to fit with the theory. Although asteroids do have iridium in them, they do not normally spread out the iridium upon impact. (In other words, areas around impacts are not iridium-enriched.) In at least one case, the iridium would have taken half a million years to cover the earth, by evolutionary counting.