Everything Everywhere Daily: History, Science, Geography & More - Dendrochronology
Episode Date: September 16, 2025One of the most essential aspects of archeology is dating objects found in the past, and one of the most critical tools in dating historic objects is dendochronology. Dendrochronology, also called ...tree-ring dating, is a scientific method used to determine the age of wood and reconstruct past environmental conditions by analyzing growth rings in trees. However, it isn’t just a matter of counting tree rings; there is a science to it that has allowed us to understand a great deal about our past. Learn more about dendrochronology, how it works, and how it is used on this episode of Everything Everywhere Daily. Sponsors Quince Go to quince.com/daily for 365-day returns, plus free shipping on your order! Mint Mobile Get your 3-month Unlimited wireless plan for just 15 bucks a month at mintmobile.com/eed Stash Go to get.stash.com/EVERYTHING to see how you can receive $25 towards your first stock purchase. ExpressVPN Go to expressvpn.com/EED to get an extra four months of ExpressVPN for free!w Subscribe to the podcast! https://everything-everywhere.com/everything-everywhere-daily-podcast/ -------------------------------- Executive Producer: Charles Daniel Associate Producers: Austin Oetken & Cameron Kieffer Become a supporter on Patreon: https://www.patreon.com/everythingeverywhere Discord Server: https://discord.gg/UkRUJFh Instagram: https://www.instagram.com/everythingeverywhere/ Facebook Group: https://www.facebook.com/groups/everythingeverywheredaily Twitter: https://twitter.com/everywheretrip Website: https://everything-everywhere.com/ Disce aliquid novi cotidie Learn more about your ad choices. Visit megaphone.fm/adchoices
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One of the most essential aspects of archaeology is dating objects from the past,
and one of the most critical tools in dating historic objects is dendrochronology.
Dendrochronology, also called tree ring dating, is a scientific method used to determine the age of wood
and to reconstruct past environmental conditions by analyzing growth rings in trees.
However, it isn't just a matter of counting tree rings.
There's a science to it that has allowed us to understand a great deal about our past.
Learn more about dendro chronology, how it works and how it's used on this episode of Everything Everywhere Daily.
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Dating events and items from the past is an important part of science.
Scientists have provided dates for everything from the age of the universe to items that have been found in ancient tombs.
However, there is no one way to date an object.
There are multiple ways to date things, and depending on what's being dated, researchers
will use a different technique.
In one of the very early episodes of this podcast,
I covered the topic of radiometric dating.
Radiometric dating involves using the known decay rate of radioactive isotopes
to estimate the ages of things like rocks.
Uranium, potassium, and other elements can be used for such dating.
Carbon 14 is another type of dating that doesn't work with rocks
but can be used for organic matter going back about 60,000 years.
But one of the best methods for dating,
more recent objects, things which go back hundreds or a few thousand years, is using tree rings,
or dendrochronology. Long before dendrochronology became a formal science, people noticed that
trees contained rings that seemed to correspond to years of growth. The earliest written reference
we have comes from the ancient Greek philosopher, Theophrastus, a student of Aristotle,
who wrote around 300 BC about the annual nature of tree ring growth. He observed that trees
added layers every year, although he didn't fully grasp the potential of using these rings to
understand past conditions. Ancient civilizations likely understood this connection intuitively.
Indigenous people across North America, for instance, used tree age estimates for practical
purposes long before European contact. They could judge the age of trees for construction
purposes and understood that larger, older trees had lived through more seasons. However, these
early observations remain practical rather than scientific, lacking the systematic approach that
would later define dendrochronology. During the Renaissance, Leonardo da Vinci made remarkably pre-escent
observations about tree rings in his notebooks around the year 1500. He noticed that rings were
thicker in wet years and thinner in dry ears, essentially identifying the fundamental principle
that would later make dendro chronology possible. The friend scientist, Henri Louis duamel
Dumontso conducted some of the first controlled experiments on tree growth in the 1740s.
He wounded trees and observed how they healed, proving that trees added new layers of wood
each year from the outside. His experiments provided the first rigorous proof that each ring
indeed represented one year of growth, a fact that had been assumed but never scientifically demonstrated.
During this period, European foresters began developing more systematic approaches to understanding
tree age. German forestry schools, which were among the most advanced in the world,
started teaching students to count rings to determine timber age for practical forest
management. This represented the first institutionalized use of tree ring counting,
although it still remained focused on practical rather than historical applications.
The 19th century brought increasingly sophisticated observations that set the stage for modern
dendro chronology. Charles Babbage, better known for his work on mechanical computers, made
important observations about tree rings and climate in the 1830s. He suggested that tree rings
might preserve records of past climatic conditions. The German-American scientist Jacob Kusseler
and the Russian scientist Federer Shevdov also made major advances in the understanding of tree
rings in the 19th century. The transformation of dendrochronology into a formal science is largely
credited to the American astronomer Andrew Douglas. Douglas, who had worked at the Lowell Observatory
in Arizona was interested in the relationship between sunspot cycles and climate. Around 1901,
he began studying tree rings in the American Southwest to see whether they could record fluctuations
in rainfall and temperature. His meticulous observation showed that tree rings reflected not only
annual growth, but also long-term environmental cycles. By comparing samples from living and dead
trees, he developed the technique of cross-stating, which allowed him to extend chronologies
far beyond the lifespan of any single tree.
Douglas's work culminated in the beam expeditions,
a series of efforts to collect beams from Puebloan ruins across Arizona and New Mexico.
Archaeologists had long struggled to date these structures precisely,
relying on relative dating methods like pottery styles.
Using dendrochronology, Douglas was able to assign exact calendar years to major sites
such as Pueblo Bonito in Chaco Canyon and Batatakanin in Navajo National Monument.
The breakthrough came in 1929 at the Botanic and Rune in Arizona.
Douglas identified a piece of charcoal that bridged the gap between his modern and
archaeological chronologies.
The single sample, dubbed H.H.39, allowed him to date hundreds of archaeological sites
across the southwest with unprecedented precision.
The moment of this discovery was so significant that it's known in archaeological circles as
the day that time stood still.
the day when absolute dates became available for southwestern prehistory.
In 1937, Douglas founded the laboratory of tree ring research at the University of Arizona,
which became the global center for dendrochronology. The lab formalized methods of preparing samples,
cross-dating, and building master chronologies. During this period, dendrochronology expanded
beyond the southwest to Europe, where scholars like Bruno Herber and Germany and later researchers in
Scandinavia and the British Isles applied it to historical buildings and climate studies.
By mid-century, continuous chronologies covering thousands of years had been established in places
like Germany and Ireland. From the 1960s onward, dendrochronology became a fully
interdisciplinary tool. In archaeology, it was used to date Viking ships, medieval churches,
and historical timber frame buildings across Europe. In climatology and environmental science,
researchers used ring width and density variations to reconstruct past routes, floods,
volcanic eruptions, and temperature changes.
So dendrochronology is important, but how exactly does it work?
There is more to it than just counting the rings on trees.
And we have to start with the rings themselves.
Trees produce rings because of how their growth responds to seasonal and environmental changes
in temperate and some subtropical regions.
The ring pratern is the result of cambial activity, that is, the work of the cambium layer,
a thin sheaf of living cells between the wood or xylem and the bark or floam.
This cambium generates new xylem shells inward and new floam shells outward,
and the way it produces these shells varies over the course of a year.
When the growing season begins in spring and early summer, water and nutrient availability,
are usually high, and trees prioritize rapid transport of water to support new leaves.
The Cambium produces large diameter xylem cells with thin walls. These cells conduct water
efficiently, but are structurally weaker. Under a microscope, this early wood appears as a lighter
band. As the season progresses and growth slows, the cambium produces smaller diameter zylam
cells with thicker walls. These are denser, stronger, and less efficient for water transport,
but they provide mechanical support for the tree. This latewood appears darker and more compact.
The transition from light early wood to dark latewood creates the visible ring boundary.
One cycle of early wood plus latewood represents one year of growth in most climates.
The amount of growth in a ring will be dependent upon the climate.
climate conditions in any given year, which is why some rings are thicker and some are thinner.
In some parts of the world, such as the tropics, where they don't have clear seasons, you do not
see clear rings inside of trees. If you were to cut down a tree, you could just count the rings
to go back in time to when the tree sprouted. However, the real key to dendrochronology is
cross-dating. Without cross-dating, the furthest we could go back with tree-ring dating is the
oldest tree that we could cut down. Because tree ring widths are determined by climate,
all trees from all species in the same area should have a similar pattern of thick and thin rings.
You can also make comparisons going back in time. Suppose one living tree grew from 1800 to 1900,
and another dead log spans from 1700 to 1820. If both show the same sequence of narrow and wide
rings from 1800 to 1820, then the two chronologies can be overlapped, extending the record back to
1700. By repeating this with many overlapping specimens, dendrochronologists can construct a continuous
master sequence spanning thousands of years. The master chronology can then be used as a reference.
Any piece of wood, say from a beam from an archaeological site, can be cross-stated by aligning
its ring pattern against the master sequence. This gives a precise felling year and sometimes down
to the exact season if bark edges are also preserved. In principle, dendrochronology can provide
exact year-by-year dating as long as you have a continuous, unbroken sequence of overlapping samples.
This method is not limited by the lifespan of individual trees. Instead, it's limited by how many
logs, timbers, or preserved trees can be linked together in a sequence.
There is, of course, a catch to all of this.
There isn't a single universal master sequence that can be used for everything in the world.
One region might have a drought in the same year that another region is wet.
So you have to create multiple master sequences unique to each area.
And this means that the dating for each area depends on what archaeological wood can be found
and what trees exist in that region.
For example, the original master chronology developed by,
Andrew Douglas, based on ponderosa pine and Douglas firs, extends about 2,000 years.
However, in California, individual living bristlecone pines in the White Mountains are nearly
5,000 years old, and dead wood preserved in the same environment has allowed researchers to
build a chronology of about 9,000 years. In Europe, Irish oak and German oak pine sequences
are among the longest continuous chronologies we have. The Irish oak chronology
runs back about 7,400 years, and the German oak chronology has been extended to about 12,000
years, covering much of the period since the last ice age. At the start of the episode, I mentioned
that there were multiple ways to date objects. Many of these techniques can be used to help
calibrate the other. Because dendrochronology can provide a high degree of accuracy down to a
given year, it's been used to calibrate carbon-14 dating. I'll cover the technology.
carbon-14 dating more comprehensively in a future episode, but carbon-14 is created in the upper
atmosphere by cosmic rays. It's then ingested by living organisms and then slowly decays over
time. However, the amount of carbon-14 that's created annually is not constant. Events called Miaki
events are spikes in carbon-14 production, which can be found in the dendrochronological record.
There have been five such events recorded in 71-76 BC,
5259 BC, 660 BC, 774, and 993.
It is believed that these events were the result of massive solar flares that hit the Earth.
Knowing these spikes in Carbon 14 can then better help calibrate tree ring records.
Modern gender chronology has become truly international,
with active research programs on every continent except Antarctica.
International organizations like the Tree Ring Society founded in 1974,
have helped standardized techniques and facilitate collaboration between researchers all over the
world. The establishment of the International Tree Ring Data Bank has created a global repository of
regional Tree Ring chronologies, making data available to researchers worldwide and enabling
large-scale comparative studies. This collaborative approach has revealed global patterns in climate
variability and has helped scientists understand how different regions respond to major climate events.
Dendrochronology is a vital part of our ability to understand the past.
It has its limitations, but despite those, it is perhaps the most powerful tool we have
for being able to date and understand our past.
So long, of course, as it's made out of wood.
The executive producer of Everything Everywhere Daily is Charles Daniel.
The associate producers are Austin Otkin and Cameron Kiefer.
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