Opinion
Tyler Austin Harper is an assistant professor of environmental studies at Bates College. Amanda Shendruk is a Post visual opinions journalist.
For months, the looming box office war between “Barbie” and “Oppenheimer” has provided endless social media fodder. The flood of jokes, which have taken the form of Twitter threads and movie poster mash-ups, cash in on the supposedly radical difference between these two films: One is a grave, highly stylized biopic of the man who helped invent nuclear weapons, while the other is a whimsical live-action movie about a child’s toy. “Barbenheimer,” as the internet phenomenon has been dubbed, has generated its own Wikipedia page, not to mention an entire cottage industry of merchandise.
(Images from Redbubble, Twitter and Teepublic)
(Images from Redbubble, Twitter and Teepublic)
(Images from Redbubble, Twitter and Teepublic)
(Images from Redbubble, Twitter and Teepublic)
As an unabashed enthusiast of all things lowbrow, I’ve delighted in the campy, mindless confection of Mattel-meets-mushroom-cloud content that this nuclear meet-cute has produced. As an environmental studies professor who has spent a lot of time studying the history of science and technology, however, I’ve found “Barbenheimer” strikes a darker chord.
The underlying premise of all the jokes — that these films come out on the same day but are about hilariously different subjects and have wildly different tones — is misguided. The two movies actually have a fundamental, and disturbing, common ground. J. Robert Oppenheimer, the man behind our nuclear age, and Barbie — a toy that takes more than three cups of oil to produce before it lingers in landfills around the world — both tell the story of the dawn of our imperiled era.
“Barbie” and “Oppenheimer” each offer a window into the creation of the Anthropocene, the suggested term for our present geological epoch, in which human beings have become the most significant influence on the natural environment at a planetary scale.
That story began 4.5 billion years ago, when Earth formed into a rocky mass from a swirling mixture of dust and gas. Those rocks now hold important markers of our planet’s history.
But we don’t need to go that far back. The Cambrian period, when multicellular life started to proliferate, began only a few hundred million years ago. The start of the Cambrian — or any geological time frame — is decided when there’s a clear change in the physical characteristics of rock layers. This change is called a stratigraphic marker.
About 542 million years ago,
a worm-like organism dug burrows around the Earth. The fossilized remains of those burrows are
the stratigraphic marker of
the Cambrian period.
Examples of Stratigraphic markers
Geological periods
What’s Happening
Fossilized burrows
CAMBRIAN
Vast
life forms appear
500 million years ago
ORDOVICIAN
Fossils of small sea
colonies mark the start
of the Devonian period.
SILURIAN
Floating colonies
DEVONIAN
Land plants
evolve
400 million
A type of horrifying jawless eel notes the beginning
of the next period ...
Jawless
eels
CARBONIFEROUS
... and the next ...
Another
jawless eel
300 million
PERMIAN
... and the next.
Yes. More creepy eels
Triassic
200 million years ago
Pangea
breaks apart
Jurassic
Dinosaurs
rule the Earth
Cretaceous
100 million
Iridium from an asteriod marks the end of the Cretaceous period.
Asteroid leftovers
PALEOGENE
Non-avian
dinosaurs
go extinct
NEOGENE
QUATERNARY
Our current geological period
is just this little stretch on the timeline.
Periods are divided into smaller time scales — also by stratigraphic markers — called epochs. The Quaternary period has two: the Pleistocene
and Holocene.
2.6 million years ago
PLEISTOCENE
End of the
last ice age
12,000
years ago
HOLOCENE
Our current epoch
Today
Microplastics
or radioactive
isotopes?
Now, experts are debating whether things like microplastics or radioactive isotopes could be the stratigraphic markers of a new epoch: the Anthropocene.
About 542 million years ago,
a worm-like organism dug burrows around the Earth. The fossilized remains of those burrows are the stratigraphic marker
of the Cambrian period.
Examples of Stratigraphic markers
Geological periods
What’s Happening
Fossilized burrows
CAMBRIAN
Vast
life forms
appear
500 million years ago
ORDOVICIAN
Fossils of small sea
colonies mark the start
of the Devonian period.
SILURIAN
Floating colonies
Land plants
evolve
DEVONIAN
400 million
A type of horrifying jawless eel notes the beginning
of the next period ...
Jawless eels
CARBONIFEROUS
... and the next ...
300 million
Another jawless eel
PERMIAN
... and the next.
Yes. More creepy eels
Triassic
Pangea
breaks apart
200 million years ago
Jurassic
Dinosaurs
rule the Earth
Cretaceous
100 million
Iridium from an asteriod marks the end of the Cretaceous period.
Asteroid leftovers
PALEOGENE
Non-avian
dinosaurs
go extinct
NEOGENE
QUATERNARY
Our current geological period
is just this little stretch on the timeline.
Periods are divided into smaller time scales — also by stratigraphic markers — called epochs.
The Quaternary period has two:
the Pleistocene and Holocene.
2.6 million years ago
PLEISTOCENE
End of the
last ice age
12,000
years ago
HOLOCENE
Our current epoch
Today
Microplastics or
radioactive isotopes?
Now, experts are debating whether things like microplastics or radioactive isotopes could be the stratigraphic markers of a new epoch:
the Anthropocene.
About 542 million years ago, a worm-like organism dug burrows around the Earth. The fossilized remains of those burrows are the stratigraphic marker of the Cambrian period.
Examples of Stratigraphic markers
What’s Happening
Geological periods
Fossilized burrows
CAMBRIAN
Vast life
forms
appear
500 million years ago
ORDOVICIAN
Fossils of small sea colonies mark
the start of the Devonian period.
SILURIAN
Land
plants
evolve
Floating colonies
DEVONIAN
400 million
A type of horrifying jawless eel notes the beginning of the next period ...
Jawless eels
CARBONIFEROUS
... and the next ...
300 million years ago
Another jawless eel
PERMIAN
... and the next.
Yes. More creepy eels
Triassic
Pangea
breaks
apart
200 million
Jurassic
Dinosaurs
rule the
Earth
Cretaceous
100 million
Iridium from an asteriod marks
the end of the Cretaceous period.
Non-avian
dinosaurs
go extinct
Asteroid leftovers
PALEOGENE
NEOGENE
QUATERNARY
Our current geological period is just this little stretch on the timeline.
Periods are divided into smaller time scales — also by stratigraphic markers — called epochs. The Quaternary period has two: the Pleistocene and Holocene.
2.6 million years ago
PLEISTOCENE
End of the last ice age
12,000 years ago
HOLOCENE
Our current epoch
Today
Microplastics or
radioactive isotopes?
Now, experts are debating whether things like microplastics
or radioactive isotopes could be the stratigraphic markers
of a new epoch: the Anthropocene.
The Atomic Age began in the red pre-dawn of New Mexico. A group of scientists and soldiers gathered in the barren landscape of the Jornada del Muerto to behold the “Gadget.” Jornada del Muerto — or when literally translated, the “Route of the Dead Man” — is the name bequeathed by the conquistadors to describe this 90-mile stretch of waterless desert. Unknown to the colonizing Spanish, that name would prove prophetic centuries later. At 5:29 a.m. on July 16, 1945, the “Gadget” exploded half an hour before sunrise. Watching a spectacle worthy of a god, Oppenheimer worried that man had become one. Exactly three weeks later, a ball of light consumed the cloudless Hiroshima skyline. That summer marked the first significant introduction of plutonium-239 into the atmosphere.
In the years to follow, the United States, the Soviet Union and the United Kingdom conducted an additional 456 atmospheric nuclear tests, 67 of which took place at the Marshall Islands.
This included the largest U.S. nuclear test ever conducted, code-named Castle Bravo, which hollowed out a mile-wide crater in the Bikini Atoll’s reef. Across the island chain, vaporized radioactive coral descended as fallout, leaving many Marshallese — some of whom had already been evacuated from their homes — with health consequences that continue today.
On Aug. 5, 1963 — 18 years after that day in New Mexico, and one day before the anniversary of the Hiroshima bombing — the United States, the Soviet Union and the United Kingdom banned atmospheric nuclear testing.
Pacific Ocean
Castle Bravo crater
1.5 miles
Bikini Atoll
(Marshall Islands)
(Copernicus Sentinel Data 2017/Gallo/
Getty Images')
Pacific Ocean
Castle Bravo crater
1.5 miles
Bikini Atoll
(Marshall Islands)
(Copernicus Sentinel Data 2017/Gallo/Getty Images)
Pacific Ocean
Castle Bravo crater
1.5 miles
Bikini Atoll
(Marshall Islands)
(Copernicus Sentinel Data 2017/Gallo/Getty Images)
Half a century later, members of the Anthropocene Working Group — a body of scientists tasked with identifying the start of a new, human-influenced geological epoch — began studying the viability of radioactive isotopes produced by nuclear testing as potential stratigraphic markers. They found plutonium-239, which tends to both endure and penetrate the darkest recesses of the ocean, to be a strong candidate.
Sign up for Unboxed, a pop-up newsletter on the best memes, coverage and buzz around the “Barbie” movie.
Yet, the 1950s was not only the decade of plutonium. It was also the decade of plastic.
The war was over, and Americans were being promised “better things for better living … through chemistry.” Only days before Hiroshima was consumed by a second sun, the president of DuPont advised his employees that Americans, drunk on peace and whose homeland was largely untouched by the war, would crave new trinkets and luxuries.
In the 1940s, DuPont had played a part in bringing about the war’s end, producing the plutonium required to make the atomic bomb at its Hanford, Wash., facility. Now that the global conflagration had ended thanks to that plutonium, DuPont turned its attention to plastics and the mass production of consumer goods. The company had begun making polyethylene at scale in 1944, which was soon hailed by Fortune as “the fastest growing plastic on the market.” By 1951, polypropylene would join its ranks as a new wonder material that would help bring about the transformation of consumer manufacturing in that decade.
In the spring of 1959, one of the most famous consumer goods in world history emerged at a New York City toy fair. Produced from polyvinyl chloride — colloquially known as PVC — the inaugural Barbie came in blonde and brunette. More than a quarter of a million dolls were sold in the first year.
Almost 65 years later, Barbie remains one of the most recognizable American brands on the planet, with approximately 100 dolls being sold every minute. Polyethylene, polypropylene and polyvinyl chloride remain the three most common variants of synthetic plastics in the world, and are among the primary “techno-fossils” that help distinguish the Anthropocene from prior epochs in Earth’s past.
Plastic production and nuclear
testing took off after 1950
Global plastics production
Million tons
400
300
200
Polymer resin
and fibers
100
0
1950
2020
Plutonium fallout
PBq m-2
2.0
1.5
Radioactive plutonium
in the environment as
a result of nuclear tests.
1.0
0.5
0
1950
2020
Sources: Our World in Data based on Geyer et al.
(2017) and the OECD Global Plastics Outlook;
C. N. Waters et al. (2016), Science.
Plastic production and nuclear
testing took off after 1950
Global plastics production
Million tons
400
300
200
Polymer resin
and fibers
100
0
1950
2020
Plutonium fallout
PBq m-2
2.0
1.5
Radioactive plutonium
in the environment as
a result of nuclear tests.
1.0
0.5
0
1950
2020
Sources: Our World in Data based on Geyer et al. (2017) and
the OECD Global Plastics Outlook; C. N. Waters et al. (2016),
Science.
Plastic production and nuclear testing took off after 1950
Global plastics production
Million tons
Plutonium fallout
PBq m-2
400
2.0
1.5
300
1.0
200
Radioactive plutonium
in the environment as
a result of nuclear tests.
Polymer resin
and fibers
0.5
100
0
0
1950
2020
1950
2020
Sources: Our World in Data based on Geyer et al. (2017) and the OECD Global Plastics Outlook;
C. N. Waters et al. (2016), Science.
The widespread introductions of plutonium and plastic into the geological record are deeply intertwined. Perhaps the most substantial difference between “Barbie” and “Oppenheimer” lies only in their respective approaches toward their common subject matter — a difference in attitude that ultimately reflects our own. As war rages in Eastern Europe and we find ourselves, again, living in the shadow of the bomb, renewed nuclear anxiety has wrestled with climate anxiety for our collective attention. On one hand, we have the spectacular visibility and exceptionalness of the bomb — its mushroom cloud occupies the fuzzy boundary between the sublime and the satanic. On the other, we have a climate crisis spurred in part by the everydayness of oil-saturated plastic products such as Barbie, goods so omnipresent in our lives that their harms are almost invisible to us — unlike the bomb, they produce delight rather than dread.
In the new “Barbie” film, an older woman imparts a piece of wisdom to Margot Robbie’s titular character: “Humans have only one ending; ideas live forever.” The recent news that scientists have selected a lake in the Canadian wilderness — riddled with traces of pollution, waste and radioactive fallout — as the proposed start to the Anthropocene signals that the immortality of ideas is more than just a pretty thought: It’s a reality in a world where humanity has baked its worst vices into the Earth’s geological record. Despite their apparent differences, both “Barbie” and “Oppenheimer” tell the story of core ideas of the 20th century: accelerating militarism and unbounded consumption, ideas that might well outlive our species in the form of plastic and plutonium’s lingering traces across our fragile planet.