Paleomagnetism aids research on the Northern Hemisphere Glaciation
Rod Boyce
907-474-7185
April 14, 2023
Ten years ago, a Chinese research vessel floating 2,700 miles off the coast of California reached 16,500 feet below the surface to retrieve a small piece of Pacific Ocean floor.
Researchers say a one-fifth-inch slice of that nodule, which measured 1 by 1.4 inches before it was sliced open for analysis, contains information about the relationship between deep Antarctic waters and the behavior of the Northern Hemisphere Glaciation. That glacial period began approximately 2.7 million years ago.
The research was published Feb. 24 in the journal . Associate research professor Gunther Kletetschka at the University of 蜜桃影像 Fairbanks Geophysical Institute is among the 11 contributors. The research was led by Liang Yi of Tongji University, Shanghai, China.
Information gleaned from the nodule couldn鈥檛 be properly placed on Earth鈥檚 geologic timeline without knowing the nodule鈥檚 precise age.
That鈥檚 where paleomagnetism expert Kletetschka came in. Paleomagnetism is the study of magnetism imprinted on rocks by Earth鈥檚 magnetic field at the time of the rocks鈥 formation.
Kletetschka used a high-resolution magnetic scanner in the 蜜桃影像 Reichardt Building to analyze the slice of the marine ferromanganese nodule.
鈥淭hrough magnetic scanning, we found that the age of this nodule is about 4.7 million years,鈥 he said.
To get that precision, Kletetschka used a method he and others developed and reported in 2020. The process involves magnetic and chemical scanning and analysis of beryllium isotopes and cobalt atom concentration.
The research also revealed the age of the individual layers in the sample鈥檚 interior. The dating was possible because the scanning revealed the changes in Earth鈥檚 north-south magnetic polarity imprinted on the nodule over millions of years.
鈥淲ith the outside of the nodule we see that the magnetic field is in the direction of today's magnetic field,鈥 Kletetschka said. 鈥淏ut when we went about half a centimeter into the nodule, we saw that the polarity had reversed.鈥
A series of rings within the sample disclosed a history of polarity change. Scientists then matched that against the known history of Earth鈥檚 polarity changes. The planet鈥檚 polarity has been reversing every 200,000 to 300,000 years for about the last 20 million years, though it has been more than twice that since the most recent change.
The sample nodule likely grew from a single grain of sand. Kletetschka explained that the ocean bottom contains a lot of iron and manganese. The depths also contain higher levels of free dissolved oxygen, which leads to oxidation of the iron and manganese.
鈥淭his allows some atoms of the iron and manganese to precipitate onto a tiny grain of sand,鈥 he said. 鈥淎nd it continues over the ages, making a nodule that gets bigger and bigger.鈥
For the researchers, marine ferromanganese nodules and other crustal formations of metal oxides become recorders of bottom-water oxygen levels.
Knowing the oxygen level reveals the strength and weakness of what is known as ocean ventilation. The deep Antarctic water, known as Antarctic bottom water, is a key factor in global ocean ventilation.
The ventilation system starts when cold, salty water in the Arctic and North Atlantic drops deep under the surface. The water then moves south to Antarctica and eventually into the Pacific and Indian oceans before returning to the Atlantic.
The paper鈥檚 authors say the record within the Pacific Ocean nodule reflects conditions where Antarctic bottom water originates at the submerged shelf of the Antarctic continent.
With Kletetschka鈥檚 work, researchers were able to place on Earth鈥檚 geologic timeline the oxygen-level indicators revealed by chemical scanning of the nodule鈥檚 rings.
The result is a record of deep-sea ventilation going back 4.7 million years, the age of the nodule.
The researchers say the data provides 鈥渃ompelling evidence鈥 of a link between episodes of low bottom-water oxygen, changes in Antarctic ice sheet volume and decreases in Northern Hemisphere Glaciation ice volume.
ADDITIONAL CONTACT: Gunther Kletetschka, 907-474-7090, gkletetschka@alaska.edu
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