TRICERATOPS: HORNED GIANT OF THE LATE CRETACEOUS

Imagine standing on the edge of a warm, subtropical floodplain 66 million years ago. 

The air hums with insects, dragonflies dart over shallow pools, and cicada-like calls echo through the dense stands of magnolias and cycads. 

A herd of Triceratops horridus moves slowly across the open landscape, their massive, parrot-like beaks tearing into low-growing ferns and palm fronds. Each step sinks slightly into the damp soil, leaving broad three-toed tracks. 

The ground vibrates with the low, resonant bellows they use to keep in contact with one another, a chorus of sound that carries across the plain.

You might catch glimpses of other giants sharing the same world. Herds of hadrosaurs—Edmontosaurus—graze nearby, their duck-billed snouts sweeping back and forth through the vegetation like living lawnmowers. 

Overhead, toothed seabirds wheel and cry, their calls mixing with the shrieks of distant pterosaurs. And lurking at the edges of the scene, half-hidden among the trees, the apex predator Tyrannosaurus rex waits, its presence felt more than seen, a reminder that this landscape is ruled by both plant-eaters and their formidable hunters.

Triceratops was one of the last and largest ceratopsians, measuring up to 9 meters (30 feet) long and weighing as much as 12 metric tons. Its most iconic features were the three horns—two long brow horns above the eyes and a shorter horn on the nose—backed by a broad bony frill. These structures were likely used for defense against predators like T. rex, but also for display within their own species, signaling dominance, maturity, or readiness to mate.

Its beak and shearing dental batteries made Triceratops a highly efficient plant-eater. Unlike many earlier ceratopsians, it possessed hundreds of teeth stacked in dental batteries, capable of slicing through tough, fibrous plants like cycads and palms that flourished in the Late Cretaceous.

Triceratops lived at the very end of the Cretaceous, in what is now western North America, within the region known as Laramidia, a long island continent separated from eastern North America by the Western Interior Seaway. 

Alongside Triceratops, this ecosystem hosted a staggering diversity of dinosaurs, including ankylosaurs (like Ankylosaurus magniventris), duck-billed hadrosaurs, pachycephalosaurs, and smaller predators like Dakotaraptor. Crocodilians, turtles, and mammals also thrived in the wetlands and forests.

Fossil evidence suggests that Triceratops may have lived in herds, though adults are often found alone, hinting at possible solitary behavior outside of mating or nesting seasons. Juveniles, on the other hand, may have grouped together for protection.

Triceratops was among the very last non-avian dinosaurs before the mass extinction event at the Cretaceous–Paleogene (K–Pg) boundary, 66 million years ago. Their fossils are found in the uppermost layers of the Hell Creek Formation, placing them just before the asteroid impact that ended the Mesozoic. Triceratops mark the end of an era, as it were, representing both the culmination of ceratopsian evolution and the twilight of the age of dinosaurs.

Today, Triceratops remains one of the most recognizable dinosaurs in the world and a personal fav—its horns and frill embodying the strange beauty and raw power of prehistoric life. Standing face-to-face with a Triceratops skeleton in a museum is awe-inspiring, but to truly imagine them alive, you must step back into their world: warm floodplains, buzzing insects, herds of plant-eaters, and the constant tension of predators in the shadows.

STEGOSAURUS: PLATED GIANT OF THE JURASSIC

Few dinosaurs are as instantly recognizable as Stegosaurus, with its double row of towering bony plates and spiked tail. 

This impressive herbivore, whose name means “roofed lizard,” roamed western North America about 155–150 million years ago during the Late Jurassic. 

Fossils of Stegosaurus have been found primarily in the Morrison Formation, a magnificent rock unit famous for preserving one of the most diverse dinosaur ecosystems ever discovered.

Stegosaurus could reach up to 9 meters (30 feet) in length but had a disproportionately small head with a brain roughly the size of a walnut. 

Despite this, it thrived as a low-browser, feeding on ferns, cycads, and other ground-level plants using its beak-like mouth and peg-shaped teeth. Its most iconic features were the dermal plates, some nearly a meter tall, running down its back. Their function remains debated—some have proposed they were used for display, species recognition, or thermoregulation.

At the end of its tail, Stegosaurus bore four long spikes, known as the thagomizer. 

Evidence from fossilized injuries on predator bones suggests these were formidable weapons, capable of piercing the flesh of even the largest carnivores.

Stegosaurus did not live in isolation. It shared its world with a cast of iconic dinosaurs and other ancient animals:

• Sauropods such as Apatosaurus, Diplodocus, and Brachiosaurus dominated the floodplains, their long necks sweeping across the tree canopy.
• Predators like Allosaurus and Ceratosaurus stalked the ecosystem, preying on herbivores. The spikes of Stegosaurus would have been a key defense against these hunters.
• Ornithopods, including Camptosaurus and Dryosaurus, grazed alongside Stegosaurus, representing smaller, quicker plant-eaters.
• Early mammals, small and shrew-like, scurried through the underbrush, while flying pterosaurs soared overhead.
• Freshwater systems hosted fish, turtles, and crocodile relatives, rounding out the ecosystem.

Interesting Facts

• The brain-to-body ratio of Stegosaurus is one of the smallest of any dinosaur, fueling the myth that it had a “second brain” in its hips—an idea no longer supported by science.
• Tracks attributed to stegosaurs suggest they may have moved in small groups, possibly for protection.
• Despite its fearsome appearance, Stegosaurus was strictly an herbivore. Its teeth were too weak to chew tough vegetation, meaning it likely swallowed food in large chunks.
• And, being one of my best loved dinosaurs, I chose Stegosaurus as one of my logos for the Fossil Huntress. This gentle giant is one of my all time favourites!

Stegosaurus lived tens of millions of years before the rise of dinosaurs like Tyrannosaurus rex, and remains one of the most beloved prehistoric creatures. Its strange mix of delicate feeding adaptations and heavy defensive weaponry highlights the balance of survival in the Jurassic ecosystem.

For those that love paleo art, check out the work of Daniel Eskridge (shared with permission here) to see more of his work and purchase some to bring into your world by visiting: https://daniel-eskridge.pixels.com/

A DAY IN THE LIFE OF A HADROSAUR

Glorious Parasaurolophus art work by Daniel Eskridge

Morning mist curls along the banks of a wide, slow river. The air is heavy with the earthy scent of wet ferns and moss, tinged with the sweet tang of distant flowering trees. 

Sunlight filters through the canopy of towering conifers, catching the mist in golden rays that dance across the forest floor. 

In the dappled light, a herd of Edmontosaurus—duck-billed hadrosaurs—trundle slowly along the muddy bank. Their broad, flattened snouts graze the lush vegetation as they move, leaves crunching softly underfoot. 

Occasionally, one lifts its head, nostrils flaring as it senses the faint rustle of small mammals or the distant call of a Troodon hunting nearby. The low, resonant calls of the herd echo through the valley—a combination of hums, grunts, and whistling notes, a complex social language that signals alertness or contentment.

Around the herd, the world teems with life. Tiny lizards dart among fallen logs. Feathered dinosaurs like Caudipteryx flit through the branches, their wings rustling against the leaves. In the sky, pterosaurs wheel silently, shadowing the riverbanks, while fish occasionally leap from the water, disturbing the mirrored surface. 

A Tyrannosaurus stalks at a distance, its presence felt more than seen, tension rippling through the herd as they lift their heads in unison, scanning the forest edge. Yet for now, they continue to feed, grazing on conifers, ferns, and flowering plants, their broad dental batteries efficiently shearing tough plant material.

As the sun climbs higher, the herd’s rhythm shifts. Juveniles cluster together near the center of the group, protected by adults forming a loose perimeter. Mothers communicate constantly with low-frequency hums that travel through the ground, letting their young know it is safe to graze. Each hadrosaur maintains a personal space, yet the herd moves as a fluid unit, coordinated by sight, sound, and subtle gestures. 

Occasionally, two adults nuzzle briefly or bump heads—a gentle reinforcement of social bonds within the herd.

By midday, the river becomes a focal point. Hadrosaurs wade into shallow water, stirring the mud with their broad feet, creating a chorus of splashes and grunts. The water’s surface reflects the glittering canopy above, disturbed only by the occasional leap of fish or the landing of a pterosaur. 

Here, the herd drinks, cools down, and reorients itself to the sun’s angle. Younglings playfully chase each other through the shallows, their calls mingling with the rhythmic lapping of water. Predators lurk nearby, and the herd’s vigilance never wavers—any unusual sound or movement triggers a wave of alert postures, heads lifting in unison, tails flicking nervously.

As afternoon wanes, the herd moves toward forested areas, seeking shade. The scent of resin from conifers mingles with the damp earth, masking the smell of predators. The larger adults lead, while subadults and juveniles follow, practicing the complex patterns of herd movement they will rely on for survival. 

The subtle vibrational signals—footsteps, tail swishes, body shifts—help coordinate the group over distances that the eyes alone cannot manage. Within these social structures, older hadrosaurs seem to guide the young, showing where the most nutritious plants grow and signaling which areas are safe.

By evening, the forest becomes alive with nocturnal creatures. Crickets and insects add a constant hum to the air, while small mammals rustle in the underbrush. The herd settles in a sheltered clearing, forming protective clusters. 

Some adults lower themselves to rest, heads tucked under broad forelimbs, while juveniles huddle close, still vocalizing softly, practicing the calls they will use to communicate when they reach adulthood. 

The sounds of the night—rustling leaves, distant predator calls, and the gentle low-frequency hums of the hadrosaurs—create a layered, symphonic soundscape of life at the end of a Cretaceous day.

The world of hadrosaurs was far from solitary—their forests, riverbanks, and floodplains teemed with life, forming a complex and interconnected ecosystem. While the herd grazed, the air vibrated with the calls of feathered dinosaurs like Microraptor flitting between branches, occasionally diving to snatch insects from the foliage. Small mammals—ancestors of shrews and multituberculates—scuttled across the forest floor, their tiny claws stirring the moss and fallen leaves.

Predators lurked at every edge. Tyrannosaurus and Albertosaurus prowled open plains and forest margins, stalking both hadrosaurs and smaller herbivores. Juvenile hadrosaurs, particularly vulnerable, relied on the protective circle of adults, whose heads, tails, and bodies created a living barrier. Even crocodilians patrolled the rivers, their eyes breaking the water’s surface as they waited for an unwary hadrosaur to drink or bathe.

But the landscape was not only danger and vigilance. Insects buzzed among flowering angiosperms, pollinating as they fed, while dragonfly-like odonates skimmed over ponds and streams. Frogs croaked from the damp undergrowth, adding a pulsing rhythm to the daily soundscape. Trees, ferns, and cycads provided more than food; their dense canopies offered shelter from predators and sun, while fallen logs and leaf litter created microhabitats for countless invertebrates.

Seasonal changes added another layer of complexity. During rainy months, riverbanks became muddy feeding grounds, leaving tracks that we find and study today. 

In drier periods, herds migrated across plains and valleys, guided by the scent of water and fresh vegetation. The interplay of predators, prey, plants, and smaller animals created a dynamic, constantly shifting stage where survival depended on vigilance, cooperation, and adaptability.

Through fossil evidence—trackways, bone beds, and stomach content analysis—we can reconstruct this rich tapestry. Imagining the sensory richness: the smell of resin and damp soil, the low hum of a herd communicating, the distant roar of predators, and the flash of feathered wings overhead, gives life to a world that has been silent for 66 million years. 

In that world, hadrosaurs were central actors in a vibrant, thriving ecosystem. Hadrosaurs were not solitary wanderers but highly social beings, capable of complex communication, coordinated group behavior, and protective care of their young. 

The hadrosaurs you see in this post are Parasaurolophus — one of the last of the duckbills to roam the Earth and their great crests were the original trumpets. We now know that their bizarre head adornments help them produce a low B-Flat or Bb. This is the same B-Flat you hear wind ensembles tune to with the help of their tuba, horn or clarinet players.

I imagine them signaling to the troops with their trumpeting sound carried on the winds similar to the bugle-horn call of an elephant.

Imagining a day in their life—from morning grazing along rivers to evening rest in the forest—reveals the richness of their world, teeming with interactions and sensory experiences that echo across millions of years.

For those that love paleo art, check out the work of Daniel Eskridge (shared with permission here) to see more of his work and purchase some to bring into your world by visiting:https://daniel-eskridge.pixels.com/

SEA OTTERS: PLAYFUL TUMBLERS IN KELP

In a kingdom of waves and drifting kelp, the sea otters reign—rolling, tumbling, and spinning like acrobats in the surf. 

With shells for drums and sunlight for spotlight, they turn survival into play, joy into power. Tiny jesters of the ocean, yet fierce enough to hold an entire ecosystem in their grasp.

Sea otters (Enhydra lutris) are more than just charismatic charmers of the Pacific Coast; they are living links to an ancient evolutionary journey. Their playful demeanor hides a lineage that stretches back millions of years, into a fossil record that tells a story of transformation from river to sea.

The tale begins with their ancestors in the family Mustelidae—the same diverse group that gave us weasels, badgers, martens, and wolverines. The earliest otter-like mustelids appeared around 18 million years ago in the Miocene. Among them was Enhydriodon, a giant otter that roamed rivers and wetlands of Eurasia and Africa, weighing over 200 pounds—far larger than today’s sea otters.

By the late Miocene to early Pliocene, otter evolution was branching out. Fossils of Enhydra, the direct ancestor of modern sea otters, show up in the North Pacific around 5 million years ago. Unlike their freshwater kin, these otters were already well adapted to marine life: short, robust limbs for swimming, strong jaws for crushing mollusks, and teeth built for a diet of hard-shelled prey.

By the Pleistocene (2.6 million to 11,700 years ago), sea otters had fully taken to the sea. They developed one of nature’s thickest pelts—up to a million hairs per square inch—allowing them to survive frigid northern waters without relying on the blubber used by seals and whales. Fossil remains and genetic studies suggest that their range was once broader than it is today, extending along vast stretches of the North Pacific Rim.

These adaptations made sea otters not only survivors but keystone species. By preying on sea urchins, they keep kelp forests thriving, shaping entire marine ecosystems with their appetites. Without them, underwater forests collapse into barren urchin wastelands. With them, the kelp sways tall and green, sheltering fish, seabirds, and countless invertebrates.

It is a joy to watch them crack open a clam on its belly or twirl through kelp in a flurry of bubbles. 

From Miocene rivers to Pleistocene shores, for me sea otters embody resilience and adaptation, carrying forward the legacy of their fossil kin.

Sea otters are tender and attentive parents, especially the mothers who cradle their pups on their bellies as they float in the swells. 

A newborn pup’s fur is so dense and buoyant that it cannot dive, so the mother becomes both raft and refuge. 

She grooms the pup constantly, blowing air into its coat to keep it dry and warm, and when she needs to forage, she may wrap her young in strands of kelp to keep it from drifting away. 

This intimate bond, played out on the rolling surface of the sea, is one of the most endearing sights in the animal kingdom—proof that even in the wild’s ceaseless struggle for survival, tenderness finds its place. 

We call these playful relatives, ḵ̓asa, in Kwak'wala, the language of the Kwakwakaʼwakw (those who speak Kwak'wala), First Nations along the Pacific Northwest Coast.

SHAGGY TITANS OF THE GRASSLANDS: BISON

Bison move across the prairie like living storms, vast and steady, with the weight of centuries in their stride. 

Their dark eyes hold a quiet, unwavering depth—as if they’ve looked into the heart of time itself and carry its secrets in silence. Look into the eyes of this fellow and tell me you do not see his deep intelligence as he gives the camera a knowing look.

Shaggy fur ripples in the wind, rich and earthy, brushed by sun and shadow, a cloak woven from wilderness. When they breathe, clouds rise in the cold air, soft and ephemeral, like whispered promises that vanish but leave warmth behind.

There is something profoundly romantic in their presence: strength wrapped in gentleness, endurance softened by grace.  To watch them is to feel the wild itself lean closer, reminding us of a love as vast as the horizon, as eternal as the ground beneath our feet.

When we think of bison today, images of great herds roaming the North American plains come to mind—dark, shaggy shapes against sweeping prairies. But the story of bison goes back far deeper in time. 

These massive grazers are part of a lineage that stretches millions of years into the past, their fossil record preserving the tale of their rise, spread, and survival.

Bison belong to the genus Bison, within the cattle family (Bovidae). Their story begins in Eurasia during the late Pliocene, around 2.6 million years ago, when the first true bison evolved from earlier wild cattle (Bos-like ancestors). 

Fossils suggest they descended from large bovids that roamed open grasslands of Eurasia as forests retreated and cooler, drier climates expanded.

The earliest known species, Bison priscus, or the Steppe Bison, was a giant compared to modern bison, sporting long horns that could span over six feet tip to tip. These animals thrived across Europe, Asia, and eventually crossed into North America via the Bering Land Bridge during the Pleistocene Ice Age.

The fossil record of bison stretches back about 2 million years in Eurasia and at least 200,000 years in North America, where they became one of the most successful large herbivores of the Ice Age. Fossil evidence shows that at least seven different species of bison once lived in North America, including the iconic Bison latifrons with its massive horns, and Bison antiquus, which is considered the direct ancestor of the modern American bison (Bison bison).

Some of the richest fossil bison deposits come from Siberia and Eastern Europe – home to abundant Bison priscus fossils, often preserved in permafrost with soft tissues intact. They are also found in Alaska, USA and in Canada's Yukon region – where Ice Age bison fossils are found alongside mammoth, horse, and muskox remains.

The Great Plains of the United States and Canada are rich in Bison antiquus and later species, often in mass bone beds where entire herds perished. We also find their remains in California and the American Southwest at sites like the La Brea Tar Pits. La Brea preserves bison remains from the Late Pleistocene and their museum of the same name has a truly wonderful display of Pleistocene wolves. Definitely worthy of a trip!

One particularly famous fossil site is the Hudson-Meng Bison Kill Site in Nebraska, where remains of over 600 Bison antiquus dating to about 10,000 years ago provide a window into Ice Age hunting practices and herd behavior.

By the end of the Ice Age, many megafauna species disappeared, but bison endured. Bison antiquus gradually gave rise to the modern American bison (Bison bison), which still carries echoes of its Ice Age ancestors. Though smaller than their Pleistocene relatives, today’s bison remain the largest land mammals in North America.

AINOCERAS OF VANCOUVER ISLAND

A wee baby deep chocolate Ainoceras sp. heteromorph ammonite from Vancouver Island. This adorable corkscrew-shaped ammonite is an extinct marine mollusc related to squid and octopus.  

Within their shells, they had a number of chambers, called septa, filled with gas or fluid that were interconnected by a wee air tube. 

By pushing air in or out, they were able to control their buoyancy in the water column. These little cuties were predators who hunted in Cretaceous seas.

They lived in the last chamber of their shells, continuously building new shell material as they grew. As each new chamber was added, the squid-like body of the ammonite would move down to occupy the final outside chamber. 

Not all ammonites have this whacky corkscrew design. Most are coiled and some are even shaped like massive paperclips. This one is so remarkable, so joyously perfect my internal thesaurus can’t keep up.

I will be heading back to the area where these lovelies are found in late March this year to see if I can find other associated fossils and learn more about his paleo community

15TH BCPA SYMPOSIUM, COURTENAY, BRITISH COLUMBIA

SAVE THE DATE: 15th British Columbia Paleontological Symposium

Florence Filberg Centre, 411 Anderton Avenue, Courtenay, British Columbia, on the Traditional Territory of the K’ómoks First Nation, August 22-25, 2025

CELEBRATING THE PALEONTOLOGICAL BOUNTY OF THE COMOX VALLEY

The conference features over a dozen speakers in paleontology from Vancouver Island, mainland British Columbia, and beyond. 

This year, we’re celebrating Courtenay’s own Traskasaura sandrae—a 12-metre-long marine elasmosaur discovered by Mike Trask along the Puntledge River. The fossil was recently named in the Journal of Systematic Paleontology, earning international recognition.

Traskasaura sandrae is a newly identified genus and species of elasmosaurid plesiosaur, a long-necked marine reptile, discovered in British Columbia, Canada. 

The fossil, found along the Puntledge River on Vancouver Island, are from the Late Cretaceous (Santonian age), roughly 86 to 84 million years ago. Traskasaura sandrae is notable for its robust teeth, potentially adapted for crushing ammonites, and a unique mix of primitive and derived skeletal features, suggesting it was a powerful predator adapted for diving. 

As well as highlighting this significant find and honouring the amazing life of Mike Trask, the symposium has an exciting lineup of scientific presentations, hands-on workshops, a paleontology-themed art exhibition, poster presentations, and guided field trips. 

These events provide exciting opportunities to explore and celebrate the rich geological and paleontological history of Vancouver Island, bringing together world-renowned paleontologists, citizen scientists, fossil enthusiasts, researchers, artists, and the public in a vibrant exchange of ideas and inspiration.

Our Keynote Speaker is Dr. Kirk Johnson, Sant Director of the Smithsonian’s National Museum of Natural History, where he oversees the world's largest natural history collection. 

As a field paleontologist, he has led expeditions in eighteen US states and eleven countries with a research focus on fossil plants and the extinction of the dinosaurs. He is known for his scientific articles, popular books, museum exhibitions, documentaries, and collaborations with artists.

BRITISH COLUMBIA PALEONTOLOGICAL ALLIANCE (BCPA)

The British Columbia Paleontological Alliance (BCPA) is a collaborative network of organisations led by professional and citizen scientists, working to advance the science of paleontology in the province. 

Together, they promote fossil research and discovery through public education, responsible scientific collecting, and open communication among paleontologists, citizen scientists, fossil enthusiasts, researchers, and educators.

Every two years, the BCPA hosts a Paleontological Symposium, bringing together experts and the public from across Canada, North America, and beyond to share the latest research and discoveries related to British Columbia's fossil heritage.  To learn more, visit www.bcfossils.ca.

VANCOUVER ISLAND PALEONTOLOGICAL SOCIETY (HOST ORGANIZATION):

This year, the Vancouver Island Paleontological Society (VIPS) is proud to host the 15th BCPA Symposium in Courtenay, in partnership with the Courtenay and District Museum & Palaeontology Centre. 

Founded in 1992 and based in the Comox Valley, VIPS is a nonprofit society with charitable status in good standing dedicated to fostering public engagement with the natural world through field trips, workshops, symposia, and public lectures that bring science to life for the community. 

COMMUNITY SPONSORSHIP, SILENT AUCTION ITEMS & WELCOME BAGS: 

As host, the VIPS is currently welcoming sponsorship contributions and donations for the symposium's silent auction to help us offset conference costs, including printing, venue rental, catering, insurance, and participant support. We are also seeking items to include in our Welcome Bags for conference attendees, offering an excellent opportunity to showcase local businesses and community spirit. 

Sponsors will be publicly recognised at the conference, within the Courtenay and District Museum, and across our social media platforms. Tax receipts are available for eligible donations.

Sponsorship cheques made out to the Vancouver Island Paleontological Society can be mailed to 930 Sandpines Drive, Comox, BC, V9M 3V3. Attn: 15th BCPA Symposium 2025.

We would be honoured to have your support—your contribution would bring meaningful value to this exciting scientific event. If you have an item to donate to our silent auction or to include in our Welcome Bags, we would be sincerely grateful and can arrange for convenient pickup. 

To get involved or learn more, please contact us at bcpaleo.events@gmail.com—we’d love to hear from you! 

Warm regards on behalf of the 15th BCPA Organising Committee.

PALEONTOLOGY OF HAIDA GWAII

Misty shores, moss-covered forests, dappled light, and the smell of salt air—these are my memories of Haida Gwaii, a land where ancient stories are written in stone.

Formerly known as the Queen Charlotte Islands, the archipelago of Haida Gwaii lies at the far western edge of Canada, where the Pacific Ocean meets the continental shelf. These islands—steeped in the rich culture of the Haida Nation—are not only a cultural treasure but a geologic and paleontological wonderland.

Geologically, Haida Gwaii is part of Wrangellia, an exotic tectonostratigraphic terrane that also includes parts of Vancouver Island, western British Columbia, and Alaska. The region's complex geological history spans hundreds of millions of years and includes volcanic arcs, seafloor spreading, and the accretion of entire landmasses.

The Geological Survey of Canada (GSC) has long been fascinated with these remote islands. Their geologists and paleontologists have led numerous expeditions over the past century, documenting the diverse sedimentary formations and fossiliferous beds. Much of the foundation for this work was laid by Joseph Frederick Whiteaves, the GSC’s chief paleontologist in Ottawa during the late 19th century.

In 1876, Whiteaves published a pioneering paper on the Jurassic and Cretaceous faunas of Skidegate Inlet. This work firmly established the paleontological significance of the archipelago and cemented Whiteaves’ reputation as a global authority in the field. His paper, "On the Fossils of the Cretaceous Rocks of British Columbia" (GSC Report of Progress for 1876–77), remains a key early reference for West Coast palaeontology.

Later, Whiteaves would go on to describe Anomalocaris canadensis from the Burgess Shale—an “unlike other shrimp” fossil that would later be recognized as one of the most extraordinary creatures of the Cambrian explosion.

Whiteaves' early work on the fossil faunas of Haida Gwaii, particularly in the Haida Formation, created a foundation for generations of researchers to follow.

One of our most memorable fossil field trips was to the Cretaceous exposures of Lina Island, part of the Haida Formation. We considered it one of our “trips of a lifetime.” 

With great sandstone beach exposures and fossil-rich outcrops dating from the Albian to Cenomanian, Lina Island offered both scientific riches and stunning natural beauty.

Our expedition was supported and organized by John Fam, Vice Chair of the Vancouver Paleontological Society, and Dan Bowen, Chair of the British Columbia Paleontological Alliance and the Vancouver Island Palaeontological Society. 

Their dedication to fostering collaborative research and building relationships with local Haida communities was key. We were warmly welcomed, and field trips to fossil sites were arranged in partnership with community members and cultural stewards.

The Haida Formation yielded beautifully preserved specimens embedded both in bedding planes and in concretions—hard, rounded nodules that often house exceptionally preserved fossils. Among our finds were:

• Douvilleiceras spiniferum
• Brewericeras hulenense
• Cleoniceras perezianum
• Fossil cycads, evidence of rich Cretaceous plant life

These fossils offered a rare glimpse into an ancient marine ecosystem that once teemed with life. Douvilleiceras, a spiny ammonite, is particularly striking. This genus, first identified by Whiteaves from Haida Gwaii, ranges from the Middle to Late Cretaceous and has been found across Asia, Africa, Europe, and the Americas.  The Haida specimens, from the early to mid-Albian, remain among the most beautiful. It is one of my favourite ammonites of all time and I was blessed to find several good examples of that species.

All of the fossils I collected from Haida Gwaii have been skillfully prepped and donated to the Haida Gwaii Museum in Skidegate, British Columbia. It is a privilege to contribute in a small way to the scientific and cultural understanding of these extraordinary islands.

References and Further Reading:

Whiteaves, J.F. (1876). On the Fossils of the Cretaceous Rocks of British Columbia. Geological Survey of Canada, Report of Progress.

Jeletzky, J.A. (1970). Paleontology of the Cretaceous rocks of Haida Gwaii. Geological Survey of Canada, Bulletin 175.

Haggart, J.W. (1991). New Albian (Early Cretaceous) ammonites from Haida Gwaii. Canadian Journal of Earth Sciences, 28(1), 45–56.

Haggart, J.W. & Smith, P.L. (1993). Paleontology and stratigraphy of the Cretaceous Queen Charlotte Group. Geological Survey of Canada Paper 93-1A.

Carter, E.S., Haggart, J.W., & Mustard, P.S. (1988). Early Cretaceous radiolarians from Haida Gwaii and implications for tectonic setting. Micropaleontology, 34(1), 1–14.

SPIRALING BEAUTY: AMMONITES AS INDEX FOSSILS

Argonauticeras besairei, Collection of José Juárez Ruiz.

An exceptional example of fractal building of an ammonite septum, in this clytoceratid Argonauticeras besairei from the awesome José Juárez Ruiz.

Ammonites were predatory, squid-like creatures that lived inside coil-shaped shells.

Like other cephalopods, ammonites had sharp, beak-like jaws inside a ring of squid-like tentacles that extended from their shells. They used these tentacles to snare prey, — plankton, vegetation, fish and crustaceans — similar to the way a squid or octopus hunt today.

Catching a fish with your hands is no easy feat, as I'm sure you know. But the Ammonites were skilled and successful hunters. They caught their prey while swimming and floating in the water column. Within their shells, they had a number of chambers, called septa, filled with gas or fluid that were interconnected by a wee air tube. By pushing air in or out, they were able to control their buoyancy in the water column.

They lived in the last chamber of their shells, continuously building new shell material as they grew. As each new chamber was added, the squid-like body of the ammonite would move down to occupy the final outside chamber.

They were a group of extinct marine mollusc animals in the subclass Ammonoidea of the class Cephalopoda. These molluscs, commonly referred to as ammonites, are more closely related to living coleoids — octopuses, squid, and cuttlefish) than they are to shelled nautiloids such as the living Nautilus species.

The Ammonoidea can be divided into six orders:

• Agoniatitida, Lower Devonian - Middle Devonian
• Clymeniida, Upper Devonian
• Goniatitida, Middle Devonian - Upper Permian
• Prolecanitida, Upper Devonian - Upper Triassic
• Ceratitida, Upper Permian - Upper Triassic
• Ammonitida, Lower Jurassic - Upper Cretaceous

Ammonites have intricate and complex patterns on their shells called sutures. The suture patterns differ across species and tell us what time period the ammonite is from. If they are geometric with numerous undivided lobes and saddles and eight lobes around the conch, we refer to their pattern as goniatitic, a characteristic of Paleozoic ammonites.

If they are ceratitic with lobes that have subdivided tips; giving them a saw-toothed appearance and rounded undivided saddles, they are likely Triassic. For some lovely Triassic ammonites, take a look at the specimens that come out of Hallstatt, Austria and from the outcrops in the Humboldt Mountains of Nevada.

Hoplites bennettiana (Sowby, 1826).

If they have lobes and saddles that are fluted, with rounded subdivisions instead of saw-toothed, they are likely Jurassic or Cretaceous. If you'd like to see a particularly beautiful Lower Jurassic ammonite, take a peek at Apodoceras. Wonderful ridging in that species.

One of my favourite Cretaceous ammonites is the ammonite, Hoplites bennettiana (Sowby, 1826). This beauty is from Albian deposits near Carrière de Courcelles, Villemoyenne, near la région de Troyes (Aube) Champagne in northeastern France.

At the time that this fellow was swimming in our oceans, ankylosaurs were strolling about Mongolia and stomping through the foliage in Utah, Kansas and Texas. Bony fish were swimming over what would become the strata making up Canada, the Czech Republic and Australia. Cartilaginous fish were prowling the western interior seaway of North America and a strange extinct herbivorous mammal, Eobaatar, was snuffling through Mongolia, Spain and England.

In some classifications, these are left as suborders, included in only three orders: Goniatitida, Ceratitida, and Ammonitida. Once you get to know them, ammonites in their various shapes and suturing patterns make it much easier to date an ammonite and the rock formation where is was found at a glance.

Ammonites first appeared about 240 million years ago, though they descended from straight-shelled cephalopods called bacrites that date back to the Devonian, about 415 million years ago, and the last species vanished in the Cretaceous–Paleogene extinction event.

They were prolific breeders that evolved rapidly. If you could cast a fishing line into our ancient seas, it is likely that you would hook an ammonite, not a fish. They were prolific back in the day, living (and sometimes dying) in schools in oceans around the globe. We find ammonite fossils (and plenty of them) in sedimentary rock from all over the world.

In some cases, we find rock beds where we can see evidence of a new species that evolved, lived and died out in such a short time span that we can walk through time, following the course of evolution using ammonites as a window into the past.

For this reason, they make excellent index fossils. An index fossil is a species that allows us to link a particular rock formation, layered in time with a particular species or genus found there. Generally, deeper is older, so we use the sedimentary layers rock to match up to specific geologic time periods, rather the way we use tree-rings to date trees. A handy way to compare fossils and date strata across the globe.

References: Inoue, S., Kondo, S. Suture pattern formation in ammonites and the unknown rear mantle structure. Sci Rep 6, 33689 (2016). https://doi.org/10.1038/srep33689
https://www.nature.com/articles/srep33689?fbclid=IwAR1BhBrDqhv8LDjqF60EXdfLR7wPE4zDivwGORTUEgCd2GghD5W7KOfg6Co#citeas

Photo: Hoplites Bennettiana from near Troyes, France. Collection de Christophe Marot

ROBIN O'KEEFE: VANCOUVER ISLAND'S ELASMOSAURS

The ancient seas of the Mesozoic teemed with leviathans—fanged predators, armoured fish, and sleek marine reptiles. 

Among them, the elasmosaurs were some of the most striking: long-necked plesiosaurs with serpent-like grace and formidable predatory adaptations. 

Few scientists have done more to illuminate the biology and evolution of these marine reptiles than Dr. F. Robin O’Keefe. 

A vertebrate paleontologist at Marshall University, O’Keefe’s research has ranged across marine reptile phylogeny, functional morphology, and evolutionary innovation. 

O'Keefe will be sharing his research at the 15th BCPA Symposium in Courtenay, August 22-25, 2025.

In recent years, his work has helped to reshape our understanding of elasmosaurs, particularly those found in the fossil-rich rocks of Vancouver Island, British Columbia.

Elasmosaurs (Family: Elasmosauridae) were marine reptiles that thrived during the Late Cretaceous period. Their most distinctive feature was their astonishingly long necks, which in some species accounted for over half their body length. These creatures likely hunted small fish and squid-like cephalopods, using stealth and rapid strikes to seize prey.

Though long thought of as slow-moving and awkward, research led by scientists like O’Keefe suggests a far more dynamic picture—of agile, efficient swimmers with specialized anatomical adaptations.

The Upper Cretaceous marine deposits of Vancouver Island, particularly near the Comox Valley, Courtenay, and Puntledge River areas, are renowned for their abundance of well-preserved marine fossils. These include ammonites, mosasaurs, and notably, elasmosaurs. 

The region is part of the Nanaimo Group, a geologic unit consisting of marine sediments deposited in a forearc basin as the Pacific Plate subducted beneath the North American Plate.

One of the most celebrated finds from this region is a nearly complete elasmosaur discovered by local fossil hunter Mike Trask and his daughter Heather in 1988. The fossil was later excavated and housed at the Courtenay and District Museum and Paleontology Centre. It became the focus of detailed scientific analysis—bringing together local efforts and academic expertise, including that of Robin O’Keefe.

O’Keefe's work on elasmosaurs blends detailed anatomical studies with cutting-edge phylogenetic methods and biomechanical modeling. In collaboration with other researchers and citizen scientists, O’Keefe has used elasmosaur fossils from Vancouver Island to explore big questions in marine reptile evolution: How did they swim? Why did their necks evolve to such extreme proportions? What ecological roles did they fill?

The specimen in question—unearthed near Courtenay in the 1980s and later housed at the Courtenay & District Museum—was one of the most complete marine reptile fossils ever discovered in British Columbia.

O’Keefe’s collaborative approach is also worth noting. His work on Vancouver Island elasmosaurs brought together professional paleontologists, local museums, and amateur fossil collectors. He has praised the community-based model of paleontology in British Columbia, where important discoveries often begin in the hands of citizen scientists and are then scientifically studied through institutional partnerships.

Robin O’Keefe’s work has been instrumental in reframing how scientists understand elasmosaurs—not as clumsy, bizarre sea reptiles but as highly specialized marine predators with a dynamic evolutionary history. 

His research on Vancouver Island’s elasmosaur fossils has revealed new species, resolved evolutionary puzzles, and underscored the importance of community science in paleontology. 

Through detailed anatomical work, phylogenetic analysis, and public engagement, O’Keefe continues to deepen our understanding of the ancient oceans and the creatures that ruled them.

ABOUT F. ROBIN O'KEEFE

Professor F. Robin O’Keefe received his Bachelor’s degree in honours Biology from Stanford University in 1992, and his Ph.D. in Evolutionary Biology from the University of Chicago in 2000. 

He has held a faculty position at Marshall University in West Virginia since 2006, where he has taught over two thousand undergraduates in courses ranging from human anatomy to comparative zoology and earth history. Dr. O’Keefe has successfully mentored 19 Master’s degrees, with two in progress. 

O’Keefe has published widely in journals including Science, Nature, PNAS, Systematic Biology. 

An acknowledged expert on marine reptiles from the age of dinosaurs, O’Keefe was awarded the 2013 Drinko Distinguished Research Fellowship for his work on plesiosaur reproduction. 

O’Keefe has also published on the anatomy and relationships of Permian reptiles from Africa, as well as a series of papers on the evolutionary biology of Rancho La Brea carnivores. Doctor O’Keefe has done paleontological field work in the Caribbean, Madagascar, Niger, China, Europe, South America, and throughout the American West, with current digs in the Cretaceous of Wyoming and Montana.

ALBERTA'S PREHISTORIC GIANTS: THE DINOSAURS

Alberta's Badlands and Dinosaur Hunting Grounds

Alberta, Canada, is one of the most dinosaur-rich places on Earth. 

Its fossil beds are a window into the Mesozoic, showcasing a dazzling array of ancient life from the Late Cretaceous. 

From the thunderous footsteps of Tyrannosaurus rex to the intricate frills of Styracosaurus, Alberta’s badlands are a treasure trove of discovery that has fascinated paleontologists for over a century.

The story of Alberta's dinosaurs begins in the late 19th century. In 1884, geologist Joseph Burr Tyrrell stumbled upon the skull of a carnivorous dinosaur while surveying coal seams near Red Deer River. 

This skull belonged to Albertosaurus sarcophagus, a relative of T. rex—and marked the first significant dinosaur discovery in what is now Dinosaur Provincial Park.

By the early 20th century, Alberta had caught the attention of fossil hunters worldwide. Between 1910 and 1917, the American Museum of Natural History sent Charles H. Sternberg and his sons to excavate Alberta’s badlands. 

Charles Hazelius Sternberg was a legendary fossil hunter and one of the most important figures in Alberta’s early paleontological history. Born in 1850 in Kansas, Sternberg began collecting fossils in the American West before being hired by the American Museum of Natural History to excavate in Canada. 

From 1910 to 1917, he and his three sons worked extensively in Alberta’s badlands, unearthing thousands of dinosaur fossils from the Belly River Group and other Cretaceous formations. He was a paleo legend and, by all accounts, the world's best dad!

Their discoveries included spectacular specimens of ceratopsians like Centrosaurus and hadrosaurs like Corythosaurus. Sternberg’s work helped establish Alberta as a global hotspot for dinosaur research, and his passion for fossils is reflected in his memoir, The Life of a Fossil Hunter (1909), which remains a classic of paleontological literature.

Their expeditions yielded thousands of fossil specimens, including ceratopsians like Centrosaurus and Chasmosaurus, and duck-billed hadrosaurs such as Lambeosaurus and Corythosaurus.

Designated a UNESCO World Heritage Site, Dinosaur Provincial Park is one of the most productive fossil sites in the world. Over 50 species of dinosaurs have been found here, dating from around 76 to 74 million years ago during the Campanian stage of the Late Cretaceous.

The park preserves part of the ancient floodplain of the Western Interior Seaway, a vast inland sea that once split North America in two. The mix of river channels, swamps, and coastal habitats created ideal conditions for fossil preservation.

Famous finds from the park include:

• Gorgosaurus libratus – A fearsome tyrannosaurid predator
• Parasaurolophus walkeri – Known for its stunning cranial crest
• Styracosaurus albertensis – A ceratopsian with magnificent spiked frills

Alberta continues to yield spectacular discoveries. In 2020, a new species of meat-eating dinosaur was unveiled: Thanatotheristes degrootorum, nicknamed the “Reaper of Death.” Discovered by John De Groot along the Bow River, this tyrannosaur roamed Alberta about 79 million years ago—making it the oldest known tyrannosaurid from Canada.

Another remarkable find came in 2011 near Fort McMurray: the best-preserved armored dinosaur ever found, Borealopelta markmitchelli. This nodosaur, discovered by workers in the Suncor Millennium Mine, was so well preserved that its skin, scales, and even possible pigmentation patterns remain visible. The fossil is now housed at the Royal Tyrrell Museum in Drumheller and has revolutionized our understanding of dinosaur defense and coloration.

In 2022, a new species of dome-headed pachycephalosaur, Acrotholus audeti, was described from southern Alberta. It revealed that these head-butting herbivores were more diverse and common than previously thought.

If you're captivated by Alberta's prehistoric past, you’re in luck—there are several world-class institutions where you can see these giants up close:

Royal Tyrrell Museum of Palaeontology (Drumheller)

• Home to over 160,000 fossil specimens, the museum showcases Alberta’s dinosaur heritage with life-sized displays, fossil labs, and immersive exhibits.

Philip J. Currie Dinosaur Museum (Wembley)

• Named after the renowned Canadian paleontologist Philip Currie, this museum focuses on the Grande Prairie region’s dinosaur discoveries, including those from the Wapiti Formation.

University of Alberta Paleontology Museum (Edmonton)

• Located on campus, this museum features a wide array of fossil vertebrates and invertebrates, and often highlights ongoing research from U of A scientists.

Dinosaur Provincial Park Visitor Centre

• Located within the fossil-rich badlands, this center offers interpretive displays and guided hikes to real fossil beds.

Many of Alberta’s groundbreaking discoveries are thanks to Canadian researchers like:

• Philip J. Currie, whose work on tyrannosaurs, especially Albertosaurus, has reshaped our understanding of predator behavior.
• Darla Zelenitsky, whose research on dinosaur reproduction, eggs, and nesting behavior continues to uncover intimate details of prehistoric life.
• François Therrien, a curator at the Royal Tyrrell Museum specializing in carnivorous dinosaur paleoecology.

Alberta's unique geological history, its rich fossiliferous formations—like the Dinosaur Park, Horseshoe Canyon, and Wapiti formations—and a legacy of active fieldwork and public engagement have made it a global hotspot for dinosaur discovery. Whether you're walking the trails of Dinosaur Provincial Park or marveling at life-sized skeletons in the Royal Tyrrell Museum, Alberta offers a front-row seat to the age of dinosaurs.

Fancy a read? Check out these Scientific Papers on some of the research being done:

Currie, P. J. (2003). Allosaurus, Saurophaganax, and other large theropods of the Morrison Formation. In The Carnivorous Dinosaurs. Indiana University Press.

Zelenitsky, D. K., & Therrien, F. (2008). “Oviraptorosaur dinosaurs from Alberta, Canada: Nesting behavior and diversity.” Journal of Vertebrate Paleontology, 28(3), 636-651.

Brown, C. M., Henderson, D. M., Vinther, J., Fletcher, I., Sistiaga, A., Herrera, J., & Summons, R. E. (2017). “An exceptionally preserved three-dimensional armored dinosaur reveals insights into coloration and biology.” Current Biology, 27(16), 2514–2521.e3.

Voris, J. T., Zelenitsky, D. K., Therrien, F., & Brown, C. M. (2020). “A new tyrannosaurine (Theropoda: Tyrannosauridae) from the Campanian Foremost Formation of Alberta, Canada.” Cretaceous Research, 110, 104388.

Evans, D. C., Ryan, M. J., & Anderson, J. S. (2013). “A new basal pachycephalosaurid (Dinosauria: Ornithischia) from the Oldman Formation, Alberta, Canada.” Nature Communications, 4, 1828.

TOP 10 FAMOUS CANADIAN FOSSIL FINDS

Canada, with its vast and varied landscapes, is a treasure trove of prehistoric wonders. 

From towering tyrannosaurs to exquisitely preserved marine creatures, the fossil record here is not only rich—it’s legendary. 

It is hard to choose our best fossils as there are so many. I have my personal favorites, some found by me, some by good friends and others that rank high simply by my having the good fortune to be there at the moment of discovery. 

These ten fossils stand out not only for their scientific value but also for the astonishing stories they tell about life on ancient Earth. Whether entombed in the Rocky Mountains, buried beneath Arctic permafrost, or hidden in coastal cliffs, each discovery shines a light on a world lost to time.

Honorable mentions are many for a list of this type. Dave Rudkin's find of the Isotelus rex, the largest known trilobite definitely ranks. There are some very fetching crabs and ammonites who deserve mention. As does the First Record of an Oligocene Chimaeroid Fish (Ratfish) Egg Capsule from Vancouver Island . 

The isopod found by the deeply awesome Betty Franklin that is getting ready for publication by Torrey Nyborg is another superb example and makes my personal list. He also has an unexpected fossil lobster in the cue to write up that I found in the South Chilcotin many moons ago, so I will add that here to remind him! 

On that note, Dr. Dave Evans has a paper in the works on the first dinosaur from Vancouver Island found by our own Mike Trask that will hopefully be out soon. There is a new paper by Phil Currie et al. on the fossil fauna from the Eager Formation near Cranbrook that bears mentioning as well as the work being done by Chris Jenkins, Chris New with Brian Chatterton on the Upper Cambrian fauna near there. We can add all the finds from Tumbler Ridge, Wapiti Lake and Miguasha National Park as well.

Oh, so many options!     

So, this is by no means a complete list, but if you are wanting to check out the fossil bounty that Canada has to offer, it is a wonderful place to start!

1. Scotty the T. rex (Saskatchewan)

Discovered in 1991 near Eastend, Saskatchewan, Scotty is the largest and most complete Tyrannosaurus rex ever found in Canada—and one of the oldest individuals known of its species. Weighing an estimated 8,800 kg and measuring over 13 meters, Scotty was a bruiser of a predator. The fossil is housed at the Royal Saskatchewan Museum.

Reference: Funston, G. F., Currie, P. J., & Persons, W. S. IV. (2019). An older and exceptional specimen of Tyrannosaurus rex.

2. The Burgess Shale Fauna (British Columbia)

This World Heritage Site near Field, BC, offers a snapshot of the Cambrian Explosion (~508 million years ago), preserving soft-bodied creatures with extraordinary detail. Marrella, Opabinia, and Anomalocaris are just a few of the iconic oddballs discovered here by Charles Walcott in 1909. The site reshaped our understanding of early animal evolution. The fossils from this site have the most wonderous, albeit wacky, body plans see the world over!

Reference: Conway Morris, S. (1986). The community structure of the Middle Cambrian phyllopod bed (Burgess Shale). Paleontology, 29(3).

3. The Courtenay Elasmosaur (British Columbia)

Unearthed by my good friend Mike Trask along the Puntledge River in 1988, this long-necked marine reptile from the Late Cretaceous is one of BC’s most famous fossils—and its first major marine reptile discovery. Now housed at the Courtenay and District Museum, it inspired a new wave of paleontological exploration on Vancouver Island. 

Mike gets the credit for this find and the founding of the first paleontological society in British Columbia (VIPS), the British Columbia Paleontological Alliance (BCPA) and inspired us all with his incredible curiosity and zest for life. He passed earlier this year and is incredibly missed!

Reference: Arbour, V. M., & Trask, M. (2023). A new elasmosaurid from the Late Cretaceous of British Columbia. Canadian Journal of Earth Sciences.

4. Dakota the Dinosaur Mummy (Alberta)

This extraordinary hadrosaur (Edmontosaurus annectens) found in 1999 features fossilized skin and soft tissue impressions. While partially excavated in North Dakota, it crossed into Canadian paleontological territory through the collaborative work between Canadian and American scientists. The mummy-like preservation gives unique insight into dinosaur musculature and skin texture.

Reference: Manning, P. L., et al. (2009). Mineralized soft-tissue structure and chemistry in a mummified hadrosaur. Proceedings of the Royal Society B.

5. Zuul crurivastator (Alberta)

Discovered in 2014 in Montana but now part of the Royal Ontario Museum collection due to fossil trade agreements, Zuul is an astonishingly complete ankylosaur with preserved skin and tail club armor. Named after the Ghostbusters demon-dog, it’s as fierce as it is beautifully preserved.

Reference: Arbour, V. M., & Evans, D. C. (2017). A new ankylosaurid with exceptional soft-tissue preservation. Royal Society Open Science, 4(5).

6. Tiktaalik roseae (Nunavut)

Found on Ellesmere Island in 2004, Tiktaalik bridges the gap between fish and land vertebrates. With its fish-like body and amphibian-style neck and limbs, it's a critical fossil in understanding the water-to-land transition in vertebrate evolution.

Reference: Daeschler, E. B., Shubin, N. H., & Jenkins, F. A. (2006). A Devonian tetrapod-like fish and the evolution of the tetrapod body plan. Nature, 440.

If you have not had the pleasure, also pick up a copy of Shubin's book, Your Inner Fish. It is a classic read with the amazing tale of this fossil's discovery and Shubin's journey in paleontology. 

7. Nodosaur from the Suncor Mine (Alberta)

In 2011, miners at a Fort McMurray oilsands site uncovered the best-preserved armored dinosaur ever found. The 110-million-year-old nodosaur is so well-preserved it looks like a sleeping dragon, with skin impressions, armor, and even stomach contents intact.

Reference: Brown, C. M., & Demarco, N. (2017). The rise of fossil preservation in Alberta’s oil sands. National Geographic, May Issue.

8. The Joggins Fossil Cliffs (Nova Scotia)

These coastal cliffs reveal the Carboniferous "Coal Age" (circa 310 million years ago) with fossilized trees, trackways, and even the oldest known reptile, Hylonomus lyelli. Declared a UNESCO World Heritage Site, Joggins provides unparalleled insight into early terrestrial ecosystems.

Reference: Carroll, R. L. (1964). The earliest reptiles. Journal of Paleontology, 38(1).

9. Parksosaurus (Alberta)

One of the lesser-known but scientifically significant dinosaurs from Alberta, Parksosaurus was a small, agile herbivore named after Canadian paleontologist William Parks. It contributes to our understanding of small ornithopods in the Late Cretaceous of North America.

Reference: Boyd, C. A. (2015). The systematic relationships and biogeographic history of ornithischian dinosaurs. Paleobiology, 41(3).

10. Blue Beach Fossils (Nova Scotia)

The Blue Beach site near Hantsport yields some of the oldest known tetrapod trackways in the world, from the Late Devonian to Early Carboniferous period. These fossils document early vertebrate life coming onto land.

Reference: Mansky, C. F., & Lucas, S. G. (2013). A review of tetrapod trackways from Blue Beach. New Mexico Museum of Natural History Bulletin, 61.

Canada’s fossil discoveries span more than half a billion years of life on Earth. They showcase evolutionary milestones—from the earliest invertebrates to apex dinosaurs, marine reptiles, and the first vertebrates on land. 

The fossils are the Rosetta stones of our country, unlocking the secrets of life's history.

FOSSIL HUNTRESS PODCAST: DEAD SEXY SCIENCE

Geeky goodness from the Fossil Huntress. If you love paleontology, you will love this stream. Dinosaurs, trilobites, ammonites—you'll find them all here!

Close your eyes & fly with me as we head out together to explore Earth's rich history written in her rock. Travel to extraordinary places, sacred sites & unearth mysteries millions of years old on the Fossil Huntress Podcast.

This stream is for those who share an enduring passion for our world's hidden treasures, its wild places & want to uncover her beauty stone by stone.

This is the story of the making of our Earth and the many wonderful creatures who have called it home.

Join in the exploration of the fascinating science of paleontology — that lens that examines ancient animals, plants & ecosystems from wee single-celled organisms to big & mighty dinosaurs. Save the stream to your favorites to listen while you drive, head out fossil collecting or snuggle in for the night!

​To listen now, visit: https://open.spotify.com/show/1hH1wpDFFIlYC9ZW5uTYVL

PORT HARDY: TIME AND TIDE

One of the most beautiful areas of Vancouver Island is the town of Port Hardy on the north end of the island. 

Just outside Port Hardy further south on the west coast is the area known as Fort Rupert or Tsaxis—my home community. 

It was here that the Hudson's Bay Company built Fort Rupert both for trade with the local First Nation population and the allure of potential coal deposits. 

I headed up to the north island this past week to stomp around my old haunts, visit with family and get in a bit of late season kayaking. The town was much as I remembered it. There have been changes, of course. I lived up on Wally's hill above the reserve at Tsaxis beside the old cemetery. 

My wee childhood home is still there and I am very pleased to see that the earthly home of my ancestors is well maintained. The cemetery is groomed and cared for but the land surrounding it is overgrown and it took me a few minutes to orient myself to see where things used to be. Where the old Hudson's Bay Company Fort and its iconic chimney were in relation to the graveyard. 

A lifetimes worth of memories came flooding back. Those from my earliest years and then later when I returned to kayak, fish and scuba dive in these rich waters.

My plans of blissful days kayaking and taking photos of the scenery were altered by hurricane-force winds. Still beautiful, but chilly and choppy.

The beachhead here was clocking 120 km winds so I did a brief visit to the homestead, the graveyard and Jokerville then headed home to light the fire and hunker in as the storm blew through. 

Port Harty and Fort Rupert have an interesting history and how you read it or hear it truly depends on the lens that is applied. This has been the ancestral home to many First Nation groups. Mostly they were passing through and coming here to dig up delicious butter clams, roots, berries and other natural yummy goodness. Years before Port Hardy was settled at the turn of the century it was the home to the Kwakiutl or Kwagu’ł and part of my heritage. 

Alec and Sarah Lyon operated a store and post office on the east side of Hardy Bay. A 1912 land deal promoted by the Hardy Bay Land Co., put the area on the map and increased its population. By 1914, 12 families had settled, built a school, sawmill, church and hotel. 

The community of Port Hardy is situated within traditional Kwagu’ł First Nation territory. It is also home to the Gwa’sala-‘Nakwaxda’xw First Nation. In 1964 all the First Nations communities were amalgamated and forced to relocate from their traditional territories by the federal government, for administrative reasons. 

The First Nation families were told that it would cost less for education, easier for medical help, and the government would help with housing, but it turned out to be a hidden agenda designed to assimilate the various groups into Canadian society — or face extermination. Several years of threats and promises later, the Gwa’sala and ‘Nakwaxda’xw reluctantly gave in to the relocation, but the government didn’t keep their promise for adequate housing. 

There were five homes for over 200 people on the Tsulquate Reservation. The Gwa’sala traditional territory is Smith Inlet and surrounding islands. ‘Nakwaxda’xw traditional territory is Seymour Inlet, the Deserter’s Group, Blunden Harbour, and surrounding islands.

There was limited access to the community until the logging road connecting Port Hardy to Campbell River was paved in December of 1979. As a child, travelling to visit my grandmother in Nanaimo meant eating eating dust behind logging trucks all the way from Hardy to Campbell doing about 40 kilometres an hour, then a stop at the Dairy Queen in Campbell River for a banana split, and on again on the old Island Highway.

Port Hardy’s population grew to a little over 5,000 residents during the Island Copper Mine years (1971-1995). The former mine site is located 16 kilometres south of Port Hardy on the shores of Rupert Inlet. The open-pit porphyry copper mine employed over 900 employees from Port Hardy and the surrounding communities. Today, the former mine has been transformed into a wildlife habitat and pit lake biological treatment system (BHP Copper Inc., 2010). The Quatsino First Nation manage the property and their Economic Development Board is exploring options for its use. 

The Quatsino First Nations have conducted several feasibility studies around the implementation of a puck or brickett mill onsite, utilizing the existing infrastructure, which includes six industrial buildings.

Today, Port Hardy serves as the crossroads for air, ferry and marine transportation networks, and serves as the gateway to the fast-growing Central Coast, the Cape Scott and North Coast Trails, and BC Ferry’s northern terminus for the Discovery Coast run and Prince Rupert. It supports several traditional and emerging sectors and remains rich in natural resources and community spirit.

Every corner of the Port Hardy region is enriched with culture and history. Starting with the two welcome poles in Carrot Park, both carved and replicated by Calvin Hunt, a Kwagu’ł artist who is based in Tsax̱is. 

From here and along the seawall are interpretive signs with Kwak’wala words for various wildlife, such as salmon, bear, wolf, and orca. At the end of this walk is Tsulquate Park. 

From here you can see across Queen Charlotte Strait; the ocean highway and lands of the Kwakwa̱ka̱ʼwakw. Port Hardy was named after Vice-Admiral Sir Thomas Masterman Hardy (5 April 1769 – 20 September 1839) who served as the captain of H.M.S. Victory in the Royal Navy. 

He served at the Battle of Trafalgar and held Lord Nelson at the end of that battle where Nelson died in his arms. Though he never visited this island community, it bears his name today. 

A ten-minute drive from downtown Port Hardy, in the neighbouring community of Fort Rupert, is the village of Tsax̱is. This is the current home of the Kwagu’ł First Nation. Here lies elaborated totem poles and the big house; a venue where First Nations ceremonies take place, such as the potlatch. 

The potlatch is a First Nations constitution that determines our politics, our government, our education, our medicine, our territory, and our jurisdiction. Potlatch is a complex event with several ceremonies, which are still practiced in buildings like the Tsax̱is big house.

On the front porch of the village of Tsax̱is is Tayaguł (Storey’s Beach). Along this waterfront were several villages, which are depicted on map (pictured below) by Mervyn Child, a Kwagu’ł artist. 

Across the way and middle of K’ak’a (Beaver Harbour) are Atłanudzi (Cattle Island), Ḵ’ut’sa̱dze (Peel Island), Ḵ’a̱msa̱x̱tłe (Shell Island), and Uxwiwe’ (Deer Island). Once the words are broken down and translated; the names of these islands are unique to their environment, as they’re part of a story that belongs to the Kwagu’ł.

Where: Port Hardy, British Columbia. 50°43'27"N, 127°29'52"W

FOSSIL HUNTRESS PODCAST: DEAD SEXY SCIENCE

Close your eyes & fly with me as we head out together to explore Earth's rich history written in her rock. Travel to extraordinary places, sacred sites & unearth mysteries millions of years old on the Fossil Huntress Podcast.

This stream is for those who share an enduring passion for our world's hidden treasures, its wild places & want to uncover her beauty stone by stone. This is the story of the making of our Earth and the many wonderful creatures who have called it home. 

Join in the exploration of the fascinating science of palaeontology — that lens that examines ancient animals, plants & ecosystems from wee single-celled organisms to big & mighty dinosaurs.

​Learn about the interwoven disciplines of natural history, ecology, geology, conservation & stewardship of our world. To listen to the stories of the Earth, visit: https://open.spotify.com/show/1hH1wpDFFIlYC9ZW5uTYVL

EXPLORING WRANGELLIA: HAIDA GWAII

Misty shores, moss covered forests, a rich cultural history, dappled light, fossils and the smell of salt air—these are my memories of Haida Gwaii.

The archipelago of Haida Gwaii lays at the western edge of the continental shelf due west of the central coast of British Columbia.

They form part of Wrangellia, an exotic tectonostratigraphic terrane that includes Vancouver Island, parts western British Columbia and Alaska.

The Geological Survey of Canada sponsored many expeditions to these remote islands and has produced numerous reference papers on this magnificent terrain, exploring both the geology and palaeontology of the area.

Joseph Whiteaves, the GSC's chief palaeontologist in Ottawa, published a paper in 1876 describing the Jurassic and Cretaceous faunas of Skidegate Inlet, furthering his reputation globally as both a geologist, palaeontologist as well as a critical thinker in the area of science.

The praise was well-earned and foreshadowed his significant contributions to come. Sixteen years later, he wrote up and published his observations on a strange Mount Stephen fossil that resembled a kind of headless shrimp with poorly preserved appendages. 

Because of the unusual pointed shape of the supposed ventral appendages and the position of the spines near the posterior of the animal, Whiteaves named it Anomalocaris canadensis. The genus name "Anomalocaris" means "unlike other shrimp" and the species name "canadensis" refers to the country of origin.

Whiteaves work on the palaeontology of Haida Gwaii provided excellent reference tools, particularly his work on the Cretaceous exposures and fauna that can be found there.

One of our fossil field trips was to the ruggedly beautiful Cretaceous exposures of Lina Island. We had planned this expedition as part of our “trips of a lifetime.” 

Both John Fam, the Vice Chair of the Vancouver Paleontological Society and Dan Bowen, the Chair of both the British Columbia Paleontological Alliance and Vancouver Island Palaeontological Society, can be congratulated for their efforts in researching the area and ably coordinating a warm welcome by the First Nations community and organizing fossil field trips to some of the most amazing fossil localities in the Pacific Northwest.

With great sandstone beach exposures, the fossil-rich (Albian to Cenomanian) Haida formation provided ample specimens, some directly in the bedding planes and many in concretion. Many of the concretions contained multiple specimens of typical Haida Formation fauna, providing a window into this Cretaceous landscape.

It is always interesting to see who was making a living and co-existing in our ancient oceans at the time these fossils were laid down. We found multiple beautifully preserved specimens of the spiny ammonite, Douvelleiceras spiniferum along with Brewericeras hulenense, Cleoniceras perezianum and many cycads in concretion.

Douvelliceras spiniferum, Cretaceous Haida Formation

Missing from this trip log are tales of Rene Savenye, who passed away in the weeks just prior. While he wasn't there in body, he was with us in spirit. I thought of him often on the mist-shrouded days of collecting. 

Many of the folk on who joined me on those outcrops were friends of Rene's and would go on to receive the Rene Savenye Award for their contributions to palaeontology. There is a certain poetry in that. 

The genus Douvilleiceras range from Middle to Late Cretaceous and can be found in Asia, Africa, Europe and North and South America. 

We have beautiful examples in the early to mid-Albian from the archipelago of Haida Gwaii in British Columbia. Joseph F. Whiteaves was the first to recognize the genus from Haida Gwaii when he was looking over the early collections of James Richardson and George Dawson.

My collections from Haida Gwaii will all be lovingly prepped and donated to the Haida Gwaii Museum in Skidegate, British Columbia.