Viking boat burial found in Norway

On one of the last days of the excavation in the market square, archaeologists from the Norwegian Institute for Cultural Heritage Research (NIKU) became aware of a feature with a somewhat special shape.

The boat dates between the seventh and 10th centuries, around the time the Vikings began exploring and raiding Europe 
[Credit: Norwegian Institute for Cultural Heritage Research (NIKU)]

The feature, which was dug into the natural deposits, had been disturbed in several places by later pits and postholes, but it was quite clearly boat-shaped.

"Careful excavation revealed that no wood remained intact, but lumps of rust and some poorly-preserved nails indicated that it was a boat that was buried here", says archaeologist Ian Reed.

The remains of the boat show that it was at least 4 meters long and oriented more or less north-south.

Skeletal remains

The boat contained two long bones, which, like the boat, were oriented north-south.

"This suggests that there was a human skeleton contained within the boat. Because of the poor state of preservation we will have to carry out DNA tests to be 100% certain that the bones are human", says Reed.

The boat is damaged several places by pits and post holes. Cautious excavation has reveiled that there is no wood left 
but clumps of rust and some poorly preserved nails that show that this is probably a boat grave 
[Credit: Norwegian Institute for Cultural Heritage Research (NIKU)]

Sheet bronze and a key

Other finds included a small piece of sheet bronze, located up against one of the bones, as well as what are likely personal items from the grave.

"In a posthole dug through the middle of the boat we found a piece of a spoon and part of a key for a chest. If this is from the grave then it can probably be dated from the 7th to the 10th century", says Reed.

Could it be an Åfjord boat?

The location away from today’s harbor and the fjord suggests that the boat grave dates from the late Iron Age, or perhaps the early Viking Age.

"It is likely a boat that has been dug down into the ground and been used as a coffin for the dead. There has also probably been a burial mound over the boat and grave", says NIKU’s Knut Paasche, a specialist in early boats.

Sketcth of an Åfjord boat [Credit: Nordlandsbåten og Åfjordsbåten av G. Eldjarn og J. Godal, 1988.]

He believes that the boat type is similar to an Åfjord boat, which has historically been a common sight along the Trøndelag coast.

"This type of boat is relatively flat in the bottom midship. The boat can also be flat-bottomed as it is intended to go into shallow waters on the river Nidelven. Boat graves are common from the Iron Age and into the Viking Period, but this is the first time a ship burial from this period has been discovered in Trondheim city centre."

"This is another discovery by NIKU that refers to a Trondheim older than the medieval city. Other Viking settlements such as Birka, Gokstad or Kaupang, all have graves in close proximity to the trading centre", says Paasche.

Work on the boat has now been completed.

Source: Norwegian Institute for Cultural Heritage Research [September 21, 2017]

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Changes in Earth's crust caused oxygen to fill the atmosphere

Scientists have long wondered how Earth's atmosphere filled with oxygen. UBC geologist Matthijs Smit and research partner Klaus Mezger may have found the answer in continental rocks that are billions of years old.

Matthijs Smit of the University of British Columbia examines ancient rocks from the 
deep crust in Norway during the summer of 2017 [Credit: Matthijs Smit]

"Oxygenation was waiting to happen," said Smit. "All it may have needed was for the continents to mature."

Earth's early atmosphere and oceans were devoid of free oxygen, even though tiny cyanobacteria were producing the gas as a byproduct of photosynthesis. Free oxygen is oxygen that isn't combined with other elements such as carbon or nitrogen, and aerobic organisms need it to live. A change occurred about three billion years ago, when small regions containing free oxygen began to appear in the oceans. Then, about 2.4 billion years ago, oxygen in the atmosphere suddenly increased by about 10,000 times in just 200 million years. This period, known as the Great Oxidation Event, changed chemical reactions on the surface of the Earth completely.

Smit, a professor in UBC's department of earth, ocean & atmospheric sciences, and colleague, professor Klaus Mezger of the University of Bern, were aware that the composition of continents also changed during this period. They set out to find a link, looking closely at records detailing the geochemistry of shales and igneous rock types from around the world -- more than 48,000 rocks dating back billions of years.

"It turned out that a staggering change occurred in the composition of continents at the same time free oxygen was starting to accumulate in the oceans," Smit said.

Before oxygenation, continents were composed of rocks rich in magnesium and low in silica -- similar to what can be found today in places like Iceland and the Faroe Islands. But more importantly, those rocks contained a mineral called olivine. When olivine comes into contact with water, it initiates chemical reactions that consume oxygen and lock it up. That is likely what happened to the oxygen produced by cyanobacteria early in Earth's history.

However, as the continental crust evolved to a composition more like today's, olivine virtually disappeared. Without that mineral to react with water and consume oxygen, the gas was finally allowed to accumulate. Oceans eventually became saturated, and oxygen crossed into the atmosphere.

"It really appears to have been the starting point for life diversification as we know it," Smit said. "After that change, the Earth became much more habitable and suitable for the evolution of complex life, but that needed some trigger mechanism, and that's what we may have found."

As for what caused the composition of continents to change, that is the subject of ongoing study. Smit notes that modern plate tectonics began at around the same time, and many scientists theorize that there is a connection.

Smit and Mezger published their findings today in the journal Nature Geoscience. The research was funded by the Natural Sciences and Engineering Research Council.

Source: University of British Columbia [September 18, 2017]

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Norwegians find well-preserved Viking-era sword

A Norwegian archaeologist says a well-preserved, if rusty, iron sword dating to the Viking era has been found in southern Norway.

A sword found in the mountains of Norway belonged to a Viking who died more than 1,000 years ago 
[Credit: Espen Finstad, Secrets of the Ice/Oppland County Council]

Lars Holger Piloe says the nearly one-meter-long (3-foot) sword was found slid down between rocks with the blade sticking out, and may have been left by a person who got lost in a blizzard and died on the mountain from exposure.

Einar Åmbakk holding the sword, just moments after it was discovered 
[Credit: Espen Finstad, Secrets of the Ice/Oppland County Council]

Piloe said Thursday the sword, dating from about 850-950 A.D., was found in Lesja, some 275 kilometers (170 miles) north of Oslo.

Piloe said the sword's preservation was likely due to the quality of the iron, as well as the cold, dry conditions. It was found in late August by two men who were on a reindeer hunt some 1,640 meters (1 mile) above sea level.

Source: The Associated Press [September 14, 2017]

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The enigma of early Norwegian iron production

Ancient Norwegians made top-quality iron. But where did the knowledge to make this iron come from? A professor emeritus from the Norwegian University of Science and Technology may have solved this riddle.

Where did the expertise to smelt iron ore come from? And how did it actually get to Norway to begin with? 
[Credit: Colourbox]

For centuries, people in Norway’s Trøndelag region, in the middle of the country, made large amounts of first-class iron out of bog ore for use in weapons and tools. Production peaked at about 40 tonnes a year at around 200 AD. With production levels this high, it is likely that they exported iron to the European continent as well.

But where did the expertise to smelt the ore come from? And how did it actually get to Norway to begin with?

Arne Wang Espelund, a professor emeritus at the Norwegian University of Science and Technology’s (NTNU) Department of Materials Science and Engineering, has been interested in iron making since the 1970s.

He himself has helped to smelt iron with a method described in the 1700s by Ole Evenstad in Stor-Elvdal, just north of Lillehammer.

However, this method is different than techniques used in Norway for roughly 900 years until about 600 AD, when plague and an economic downturn in Europe caused everything to grind to a halt and the art of making iron was forgotten. At the moment, no one really knows how Iron-Age Norwegians learned to make iron.

Espelund, however, has found some clues. And they lead to the Roman Empire.

A furnace in Austria

Scientists in Austria have found a furnace with exactly the same measurements and design as furnaces in Norway. This part of Austria belonged to the Roman Empire.

Scientists in Austria have found a furnace with exactly the same measurements and design as furnaces in Norway 
[Credit: Brigitte Cech]

The archeologist Brigitte Cech found a furnace in Semlach, a village that during Roman times was in Noricum. The furnace dates from around 100 AD.

“It’s an exact copy of furnaces in Trøndelag. It has the same dimensions and a side opening,” says Espelund.

It’s true that the slag pit is built of clay, while those in Norway were made of stone. And this particular furnace in Austria is younger than the oldest Norwegian furnaces of the same design. But even older furnaces are found nearby, in Populonia in Italy and Burgenland in Austria.

Espelund believes it could be a very exciting project for a master’s student to investigate other aspects of the furnaces.

“I believe the technology for extracting iron must have originated outside of Norway,” he says.

His opinion is reinforced by the fact that no one has yet found any evidence of experimentation with making iron in Norway. That means ancient Norwegians would have mastered the art of making high-quality iron with as little as 0.2 per cent carbon contamination — without any evidence of trial and error. That is, unless they learned the art somewhere else.

The Romans’ forefathers

It was perhaps the Etruscans who were the first in Europe to learn to make iron. They lived in what is now Italy and Corsica from around 700 before our time bill. Etruscans dominated Rome at the empire’s the beginning. However, there is also evidence of iron production in Turkey from 4000 years ago.

Slag pit, Heglesvollen, Norway [Credit: Arne Espelund]

The Celts improved the metal by adding some carbon and thus making steel. The technique spread over the Roman Empire. And perhaps even to Norway.

In Norway iron was made from bog ore. The ore was gathered in the spring, while the smelting was done in the autumn. In sparsely populated Norway, where much is preserved, there are hundreds of places with evidence of this production, from areas where the ore was collected to places where the iron was extracted from the ore.

Solving the puzzle with chemistry

Today, the most common sign of ancient iron production is the slag heap. Chemical analyses of these slag heaps is a central part of understanding how the ore was smelted.

Furnaces, often four in a row, with the equally large slag piles indicating that all the furnaces were run as a unit
 simultaneously. Each furnace ran on a cyclical program, until the slag pit was full [Credit: Inkalill]

Espelund is actually a mining engineer, not an archaeologist. However, in this situation that may be something of an advantage. He’s quite used to chemical analyses and the natural sciences, which can help make an important contribution in a subject that Espelund believes is often somewhat descriptive.

Archaeologists often describe their finds in impressive details. Espelund would like to thank NTNU archaeologists for their trustworthy cooperation out in the field. He, however, has a different approach when he is faced with an archaeological site — he likes to draw on his natural sciences toolbox.

Iron ore contains different oxygen-rich compounds (FeOOH). The raw ore is first heated over an open fire to create Fe2O3.

When placed in a furnace, this raw material is then transformed into very pure iron because carbon monoxide in the furnace reacts with theFe2O3. However, a certain percentage of the iron remains in the slag, as FeO, which ensures the quality of the iron.

Slag

Slag from three places in Norway, and from Iceland, Catalonia and Austria all have a remarkably similar composition.

Places with traces of iron production in Trøndelag, mid-Norway [Credit: NTNU]

The slag consists of about 65 per cent of a mixture of iron oxide (FeO) and manganese oxide (MnO). About 20 percent is silicon oxide (SiO2). This mix is called fayalite and is usually written as (Fe, Mn) 2SiO4.

Espelund has introduced the fayalite fraction (% FeO +% MnO) /% SiO2 (in molar mass) to characterize the slag. This in turn can tell us something about the quality of the ore and provide comparable values between slag from different places.

A high content of SiO2 in the ore makes it impossible to produce iron. The ore in Norway, on the other hand, seems to have maintained good quality.
High production

Heglesvollen in Levanger municipality in Trøndelag in central Norway is one of the most important sites for iron production. Since 1982, four furnaces and 96 tonnes of slag have been found in the area.

This suggests there was a great amount of iron production here that took place over a number of years. The furnaces had been patched and repaired several times.

Archaeologists have found remains of something that could have been an air intake for a furnace that would have been powered by the chimney effect in Vårhussetra in Hessdalen. But this is the only place where this kind of air intake has been found.

“Could it be that parts of the production process were kept secret and that these air intakes were destroyed?” Espelund wonders.

We do not know. But Espelund says that one possible approach could involve five air intakes that would cause a kind of chimney fire that in turn would create high temperatures.

Pine wood

Carbon dating and other analyses of wood suggest that people in Trøndelag relied almost exclusively on pine wood for iron production — or at least they preferred it.

An iron bloom weighing 17 kilograms, typical for iron production in inner Trøndelag around the year 200 CE 
[Credit: Arne Espelund]

“That’s because pine will burn twice,” Espelund says.

First, the wood burns with a high flame. This wood then becomes charcoal that sinks down in the furnace, which can then be burned again and help with the smelting.

Adding wood creates a chimney effect in the furnace, something that combined with air intakes in the correct spots could eliminate the need to use a bellows, which could be exhausting.

Curiosity

Espelund continues to attend conferences to learn more and to contribute to the debate. The 87-year-old will give a talk at the CPSA conference in Prague, in honour of the great archaeologist Radomér Pleiner.

Espelund can’t say enough good things about how he has been treated lately. His travels are financed by a non-fiction fund. He continues to make academic contributions with new publications in this area and in others, some of which he finances himself.

Unfortunately he is no longer very mobile and can no longer go out in the field. He hopes that someone will take up his quest to understand iron production in Norway. Many questions still remain, and he is not sure he will find all the answers.

“You have to be curious,” he said.

Source: The Norwegian University of Science and Technology (NTNU) [September 11, 2016]

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