Robert Day Postdoctoral Fellowship

The University of Queensland has a full time 12 month position in palaeontology and stratigraphy open for applications!

Primary Purpose of Position
To engage in original research in the field of palaeontology or stratigraphic palaeontology. The position will benefit from a larger initiative to strengthen research and training in palaeontology at The University of Queensland and is open to any field of palaeontology, biostratigraphy or palynology. However, preference will be given to applicants who can provide expertise relevant to palaeontological and stratigraphic problems in Queensland. The successful candidate will be part of a diverse team of research professionals and students aimed at fundamental and applied research in these areas. Applicants should also refer to the UQ Academic Criteria for Performance policy. This policy applies to staff at levels A to E, across all of the academic categories – Teaching and Research, Teaching Focused, Research Focused and Clinical Academic.

Duties and responsibilities include, but are not limited to:
• Develop an independent research program with goals to obtain external funding in an appropriate area and as agreed.
• Manage a research program in a field of palaeontology or stratigraphic
• Undertake research into palaeontological and stratigraphic problems in Queensland.
• Conduct research and publish in high quality journals.
• Work with colleagues and postgraduates in the development of joint research
projects with special emphasis on relevance to Queensland.

• Contribute to teaching and supervision at appropriate levels and as required.

Service and Engagement
• Foster the School’s relations with industry, government departments, professional
bodies and the wider community.
• Attend School based meetings and Seminars.
• Any other duties as reasonably directed by your supervisor.

Ensure you are aware of and comply with legislation and University policy relevant to the duties undertaken, including but not exclusive to:
• The University’s Code of Conduct
• Requirements of the Queensland occupational health and safety (OH&S) legislation
and related OH&S responsibilities and procedures developed by the University or
• The adoption of sustainable practices in all work activities and compliance with
associated legislation and related University sustainability responsibilities and
• Requirements of the Education Services for Overseas Students Act 2000, the
National Code 2007 and associated legislation, and related responsibilities and
procedures developed by the University

Selection Criteria
• PhD in the broad area of palaeontology/stratigraphy or equivalent.
• Demonstrated expert knowledge in a relevant area of palaeontology/stratigraphy
including expertise in one or more systematic groups important for Queensland
• Demonstrated track record of success through peer-reviewed publication and/or
conference presentations of original research.
• Demonstrated skills in sample preparation and analysis relevant to research
• A vision for your own research agenda and ability to develop an appropriate research
project that addresses problems in Queensland palaeontology and/or stratigraphy.
• Evidence of a contribution to research, including successful external grant
• Ability to work collaboratively with colleagues.
• Ability to attract independent research funding is desirable.
• Ability to seek and establish collaborations and linkages with external groups such as
other universities, the Queensland Museum and industry.

If you are interested in applying or for more information check out the website ( ) or contact us at

To discuss the role, email Professor Gregory E. Webb at, or Assoc. Professor Patrick Moss at at the University of Queensland.

Egernia gillespieae and the history of Australia’s social skink

Reconstruction of the skull of Egernia gillespiea

Twenty five years ago a large chunk of the Carl’s Creek Limestone at the Riversleigh World Heritage Fossil Area was blown off of the edge of Allan’s Ledge 1990 site. It then began a long journey back to the University of New South Wales PANGEA facility to undergo acid preparation to unlock its valuable secrets. Inside this lump of rock, block 94H, was a partial skull of Egernia gillespieae, the key to timing the origins of Australia’s social skinks.

Egernia gillespieae was named in this new paper out in the Journal of Vertebrate Paleontology, after the palaeontologist, and fossil preparator, Dr Anna Gillespie. Dr Gillespie has been an integral element of the PANGEA lab, responsible for preparing thousands of fossils from Riversleigh World Heritage Area.

Dr. Anna Gillespie

Fossil squamates (lizards and snakes) are rarely recovered so complete from Australian palaeontological excavations. Dr Gillespie’s keen eye, and care for all fossils regardless of their species, size, or where they fit in a skeleton, has meant that an almost complete individual skull representing Egernia gillespieae can be assembled. This is the first Australian fossil skink to be described so completely, most only known from half-mandibles, isolated frontals, or disarticulated post-crania.

Having a near-complete individual skull presents a novel opportunity to examine these elements in context with the living Egernia and their nearest relatives, which include ‘land mullets’, spiny-tailed skinks, bluetongues, and shinglebacks. Egernia gillespieae is most similar to living Egernia striolata, the tree skinks. The paper also examined Australia’s oldest fossil bluetongue lizard, Tiliqua pusilla, which came from another site at Riversleigh and is of a similar age. A number of questions were asked, covering differences in shape and the presence or absence of different features in each species, both alive and extinct. These morphological characters were then analysed with molecular data (DNA and mitochondrial), imploring Parsimony and Bayesian analyses, to find the simplest, and the most likely phylogenetic trees of Australia’s social skinks.

Having fossils to calibrate the family tree of Australia’s social skinks has deciphered that our big bluetongues and pink tongues, Tiliqua and Cyclodomorphus, split from Egernia as early as 25 million years ago. Unexpectedly, we also found that Australia’s smallest living Tiliqua, the pygmy bluetongue, Tiliqua adelaidensis is sister to one of the largest, the shingleback Tiliqua rugosa.

This study, was made possible due to the keen eye of Dr Anna Gillespie, numerous UNSW field teams venturing out to northwestern Queensland to blast the limestone, and a team of palaeoherpetologists from Flinders University and the South Australian Museum. It represents the first step toward unravelling the evolutionary history of Australia most iconic herpetofauna.

Palaeo in the Pub- Megafauna and Palaeoclimates

Come join Flinders University Palaeontology Society for another illuminating evening of palaeo science talks, enjoyed in the casual and comfortable surroundings of The Tav @ Flinders University. Thursday March 28th @ 6:30 pm.

Director of Palaeontology at Flinders University, Professor Gavin Prideaux has spent lots of time in the field, often in the bottom of caves, digging up fossils of Australia’s unique extinct megafauna, and exploring dusty drawers in museum cabinets. His research interests include investigating the links between patterns in Australian mammal evolution, ecology and extinction, and climate- and human-driven environmental changes. His talk will focus on resolving when and why Australia’s megafauna became extinct.

Associate Professor John Tibby, Director of the Sprigg Geobiology Centre at the University of Adelaide, researches past climates and environments, mainly in eastern Australia. A major thrust of this research has been finding ways to understand the independent influence of climate and humans on the landscape. For the past decade or so he has led a project examining the environmental history of the subtropics using records of environmental change from North Stradbroke Island,. south-east Queensland. This talk will focus on discussing the 80,000 year long record from one of these sites – Welsby Lagoon.

Haidee Cadd, PhD candidate, Earth Sciences @ University of Adelaide, is a palaeoecologist interested in understanding how fire, climate and herbivory have interacted to shape Australia’s vegetation. Understanding how vegetation responds to changes in disturbance and climate over long time scales helps contribute to conservation efforts and predicating future changes. Her talk will focus on environmental changes in response to fire and climate from Welsby Lagoon, North Stradbroke Island.

This is a FREE event.
Free nibbles will be provided. Happy Hour Beer Prices. 
Bring your gold coins and try your luck at a raffle for sweet FUPS merch.

See you there!

Prof. Mike Lee awarded the Verco Medal

Congratulations are in order for our very own Matthew Flinders Fellow, Professor Mike Lee

The Verco medal, established by the Royal Society of South Australia is awarded for distinguished scientific work published by a Fellow. It is the highest honour that the Society can bestow. Only those who have made a significant, outstanding contribution to their field of study receive the award. Previous winners include the esteemed Prof Walter Howchin in 1929 (first medal awarded), HG Andrewartha, JB Cleland, and fellow earth scientists & palaeos Reg Sprigg, Michael Archer and Sir Douglas Mawson.

Mike Lee’s area of expertise earning him the Verco medal, covers just about every taxonomic group within palaeontology you can imagine. Mike has helped construct the family trees Cambrian arthropods from Emu Bay (Kangaroo Island), dinosaurs from the US, giant flightless birds from New Zealand, and snakes and lizards of Australia. Despite having worked on such a broad range of animals, Mike has a soft spot for reptiles, having completed his PhD on early turtle body plan evolution (published in Science) and afterwards travelled the world building a large collection of morphological characters for lizards and snakes to unravel their origins (just check out his Google Scholar page). He now acts as primary supervisor for the palaeontology students in our lab who want to work on fossil reptiles, or who are interested in how morphology and molecular evidence can be used to construct family trees. Mike’s true love is Bayesian methods, integrating probability into statistical analyses, which he believes is integral to the future of science.

For those of you who haven’t met Mike yet, he presented our Palaeo in the Pub: Dinosaurs with Wings this year, as well as a Sprigg Lecture at the South Australian Museum on a similar topic. Mike spends most of his days at the Museum but if you are interested in fossil reptiles or want to congratulate him on his award he will be at Flinders on Saturday evening for the Inaugural Wells Palaeontology Lecture & FUPS reception Celebrating 30 years of Palaeontology at Flinders.

Jurassic World: A Fallen Franchise

Okay so the title is a little harsh. I’d like to start this review with the disclaimer that if you were going to go and see this movie DO IT. Do not read a pile of negative reviews and change your mind, any dinosaur screen time is still worth watching regardless of what other people have to say about it! I promise I won’t reveal any major spoilers in this review, I don’t usually do this kinda thing so I’ve kept it short.

Thanks to ol’ mate Professor Flint for bringing me along as his +1. Fun times were had!

So we reach movie #5 in the Jurassic franchise. No one has managed to kill of B D Wong’s infamous Dr Henry Wu character yet so Hollywood can keep making dinosaurs from frog DNA until they manage to create a scene where he doesn’t slip away silently with vials of bright blue fluid in high tech Pelicases. This installment was timely released 25 years since the first film, capitalising on the first generation of fans wanting a hit of that childhood dinosaur nostalgia. Unfortunately, they wont get it. This is not a dinosaur movie, it’s a monster movie. Watching the previews, most of you probably already knew that, but it needs saying again because clearly no one involved in making the film was told enough. As an aspiring palaeontologist I was sitting in the cinema last night waiting for that breathtaking panoramic shot of pure dinosaur majesty somewhere in the film to fill me with that ‘science-is-awesome’ warm-fuzzy feeling like watching the herds of dinos in the first film. But that moment was entirely missing. I think they tried briefly at one point with the first sauropod appearance but it was rather lacking still.

Everything that is wrong or missing in this film ultimately derives from the lack of character development and storytelling. This movie is a string of action-packed-scene to action-packed-scene with very little holding it all together. I was waiting for Dwayne ‘The Rock’ Johnson to jump out from behind some bushes at any moment with dinosaurs under each arm, saving the day. It’s that kind of movie.

There is one true hero in all this though, and praised be, they are a SHE. Yes that’s right. Hollywood managed to make a strong, independent, powerful, FEMALE character that didn’t need no man to complete HER! She opened up a serious can of kick-ass on all the bad guys without needing any help from men with guns and she didn’t do it to save a love interest either. Introducing the one and only: BLUE. 

Blue. The queen of JW’s velociraptors and probably one of the best characters in the whole movie. – Disclaimer to @SUEthetrex: I’m sorry, but it’s true, the velociraptor was better in this film. There, I said it

This movie is entirely worth watching just to see her in action. I won’t give away too much, but the dinosaurs totally make up for the lack of the human character development in this movie. There are a couple of personalities shining through from these guys, even in short roles.

Although there are so many things lacking in this film, I do think there is at least one message that comes through pretty strong. You will pick it up in the first few minutes and it’s the same message scientists having been screaming at you for years: it’s all your fault. The world is messed up, Jurassic World, or the one outside your office window. We did it with our endless thirst for entertainment and consumption regardless of the ultimate consequences (having your body fought over by an Allosaurus and Tyrannosaurus, or swimming in an ocean filled with plastic; same thing). It’s an ugly truth but the movie does point it out fairly bluntly in a few scenes (there may or may not have been some animal-lover tears shed), so kudos deserved there.

I won’t give away much more, go see the movie for yourself. Complain about the missing feathers and oversized mosasaur because you know better. We all enjoy knowing someone with a budget 1000x times bigger than ours is wrong about something. Go watch it anyway because we all love how these films inspired us to become scientists and palaeontologists. Hopefully there are some clever kids in the audiences this year who come out equally as curious about whether or not any dinosaur fossils would be left after that eruption, and if the drowning ankylosaur bloats-and-floats later…


– Kailah (aka Professor Anning in the photo above)

Ancient fossil rewrites the hiss-tory of lizards and snakes

A life scene in the Dolomites region, Northern Italy, about 240 million years ago, with Megachirella wachtleri walking through the vegetation. (Image: © Davide Bonadonna.)

By Research Associate Dr. Alessandro Palci

It’s quite odd how sometimes things unexpectedly come back from our past in circuitous ways. It was the summer of 2000 when, still an undergraduate student, I was touring the Dolomites as part of a field trip organised by the department of Geological Sciences of the University of Trieste (Italy).

It was a sunny spring day, and I was looking down at some Jurassic dinosaur footprints, when I first heard of a small fossil reptile that had recently been found nearby, in 240 million-years-old rocks. The rumour was that someone was already working on its description. I won’t deny that I wished I could be that someone. Unfortunately, I was only an undergraduate student at the time, and a long way to go before my first palaeontological paper would be published.

The fossil was described and published by Silvio Renesto and Renato Posenato in 2003. It turned out that the fossil was preserved in rocks that originated on the bottom of a warm shallow sea. The little reptile was one of very few terrestrial organisms that had been entombed in those marine sediments, which makes its discovery incredibly fortuitous.

Renesto and Posenato named the fossil after its relatively large hands: “mega” and cheiros” are ancient Greek words for “large” and “hand”, respectively. They then classified the reptile as a member of the Lepidosauromorpha, a broad group of reptiles that includes lizards, snakes, tuataras, and many other more distantly related reptiles. Ten years later, in 2013, Megachirella was re-described by Silvio Renesto and Massimo Bernardi, and the authors confirmed the classification of Megachirella as some kind of lepidosauromorph based on a phylogenetic analysis, but did not resolve its affinities very precisely.

Another four years went by, and in the summer of 2017 I flew to Calgary, to attend the 77th annual meeting of the Society of Vertebrate Paleontology. International meetings are a great opportunity for networking, but also for catching up with old friends spread around the world. One of these friends of mine is Tiago Simões, who was finishing his PhD in Systematics and Evolution at the University of Alberta. He told me that he was working on an interesting fossil reptile, what he suspected could be the oldest fossil lizard. He also told me that he was looking for someone who could work on its CT scan data. At the time I had no idea what the mysterious fossil was, but I had considerable experience working on CT scan data, so I offered to help him out.

The restudy of this beautifully preserved specimen of Megachirella wachtleri allowed the authors to re-write the history of all fossil and living lizards and snakes. (Photo: © Science Museum, Trento, Italy)

It turned out that the fossil of Megachirella had been scanned at the ICTP Elettra synchrotron facility in Trieste, Italy, and that was the data that Tiago wanted me to work on. Only now I realize how crazy all this is, it was that very same little fossil reptile I heard about in the Dolomites seventeen years before, and it had somehow finally found its way into my hands. The CT scan data provided a wealth of new information about the little fossil, and this helped us place Megachirella in quite a different and much more interesting light.

Alessandro working on the 3D digital reconstruction of the skull of Megachirella (Photo: Mike Lee)

The three-dimensional digital images generated from the CT scan data allowed us to look through the rock, at parts of the skeleton that were inaccessible before, without incurring in the risk of damaging this unique fossil by removing the embedding rock mechanically. What we discovered was that Megachirella already shows modifications in its skull and limbs that are shared with modern lizards (like for example a triradiate squamosal at the back of the  skull, a mobile quadrate bone bearing the upper jaw joint, an ulnar patella in the elbow, and the loss of the first distal carpal in the wrist), but it also retains some extra bones that were commonplace in early reptiles, and were lost much later in lizard evolution (like gastralia along the belly, and a quaratojugal in the cheek region). We included this new information in a an extensive phylogenetic dataset that Tiago had put together during the course of his PhD, and it turned out that Megachirella is indeed a stem-lizard. The oldest and most primitive lizard known to date, a finding that earned us the cover of the latest issue of Nature.

Megachirella gives us a new window on what the first lizard probably looked like and helps us understand how the anatomy of earlier reptiles gradually changed over time, in little steps, to produce the body shape of lizards that is familiar to us today.

This fossil is important not only because its anatomy bridges a gap between two major groups of reptiles, much like Archeopteryx, but also because it extends the fossil record of lizards back in time by about 70 million years, into the middle Triassic (~240 million years ago). That lizards must have been present in such deep time had been predicted by some molecular studies of modern lizards, based on the speed at which DNA strands accrue mutations over time; however, the oldest known fossil lizards before Megachirella were frustratingly “young”, coming from rocks that originated in the Jurassic, only about 167 million years ago.

Megachirella tells us that lizards were indeed around in the Triassic, and based on a new estimate of the rate of evolution of lizards, we can now place the origin of these reptiles in the late Permian.

So, next time you are out in the field looking for fossils and see a lizard scampering around, think of Megachirella, and that the evolutionary history of this amazing group of reptiles started 260 million years ago, long before the first dinosaurs appeared!

(Adapted from the original article appearing in The Conversation on 31.05.18)

On the hunt for tetrapod footprints

Dr Alice M. Clement


The appearance of the first tetrapods, the limbed vertebrates which today dominate the land, represents one of the greatest ‘steps’ in evolution. Evidence for the first vertebrates with four limbs and digits (fingers and toes) can come from fossilised body parts, or from trace fossils, such as footprints.

The oldest widely accepted tetrapod trackway, and indeed the oldest widely accepted evidence for tetrapods in general, come from intertidal sediments from a quarry near Zachełmie, Poland. These prints, first announced in 2010, have been dated to the Middle Devonian, about 395 million years ago, and more than 18 million years older than the oldest tetrapod body fossils.

The trackways indicate they were made by flat-bodied, lizard-like creatures, some of which must have reached up to 2.5m in length. There are multiple trackways from several individuals, and most importantly, they clearly show the impressions of digits!

A model showing what the makers of the Zachełmie trackways may have looked like in the Geological Museum of the State Geological Institute in Warsaw, Poland. (Photo: A. Clement).

In Australia there have been some similarly impressive finds of trackways in Devonian rocks, including those from Glenisla and Genoa River in Victoria. The Genoa River tracks from far-eastern Victoria, are Late Devonian in age and were the first tetrapod trackways ever described from the “Age of Fishes” when first described in 1972. There is evidence of two different types of animals, clearly showing overlapping and alternating impressions of the fore and hind limbs clearly showing digits.

The Glenisla trackways are more problematic. The trackways were described in 1986, identified on a slab of rock in a homestead courtyard near the Grampians. However there remain persistent doubts over the precise age of the rock, with estimates ranging as far back as the Silurian Period, and the identity of the track maker has been questioned. If these really are tetrapod tracks and the Silurian date is correct, this represents the oldest evidence of limbed vertebrates in the world!

Professor John Long from Flinders University wanted to settle the controversy once and for all and so assembled a team of tetrapod trackway hunters to boldly venture into the remote wilderness of Victoria in search of fresh evidence. His team consisted of the walking encyclopaedia Dr Brian Choo, whizz-kid PhD student Ben King, venerable Swedish Professor Per Ahlberg, and myself.

Tetrapod-trackway hunters, Brian Choo, John Long, Per Ahlberg, Peter Ward and Alice Clement in the Grampians National Park (photo: A. Clement).

Our first stop was the Grampians, where we were joined with an old friend of John’s, Peter Ward, a structural geologist and all-round handy camp guy. In addition to examining the original track-slab at Glenisla homestead, we visited two disused quarries and were able to pinpoint the true provenance of these enigmatic prints, along with the discovery of numerous other trace fossils made by various invertebrates. Of course, being in the Grampians, we were also rewarded with some spectacular views, incredible wildflowers and many friendly kookaburras and shingle-back lizards around our campsite.

After a few days we moved onto Melbourne for a much-need shower and for the chance to examine some old fossil samples collected decades ago from Genoa River, currently housed at The University of Melbourne Geology Department. The specimens contained tantalising material from a number of different types of fish and gave us great hope of finding new specimens in the field.

Prof Per Ahlberg at the University of Melbourne, Geology Department, with a porolepiform specimen from Genoa River.

The Genoa River site is located in spectacular country within the Coopracambra National Park in far-eastern Victoria, some 50km northwest from Mallacoota Inlet. The National Park is a true wilderness and the playground of only the most determined hikers. For us it was either a 25km+ trek up and down cliffs through thick, temperate rainforest with all our gear and supplies, or a slightly more exhilarating transport option: GET TO THE CHOPPER!

The intrepid team before our first flight into the Coopracambra National Park. (Left to right: Dr Brian Choo, Prof John Long, Prof Per Ahlberg, Dr Alice Clement and Mr Ben King.)

Our weather-beaten but highly experienced pilot, Grant Shorland and his wife Ros, helped us reduce our load to just the essentials, and squeeze (just barely) into the 6-seater Écureuil. By following the course of the Genoa River, we were able to identify the area where we hoped to find fossils. However, the forest was so thick and the river often channelled between tall cliff faces, we struggled to find a suitable sandbank on which to be put down.

Even though we had seen the park from the air, it was still a surprise to experience how difficult it was to move through the undergrowth. We soon resorted to rock-hopping and eventually simply wading through the river itself. Genoa River was a spectacular site in which to spend four nights – we were lucky to share our camping spot with a plethora of skinks (Brian can tell you which species), beautifully-coloured water dragons, a few snakes, an easy-going platypus (that let us share his pristine swimming hole), and a deafening chorus of giant cicadas. 

While new tetrapod-trackways remained elusive, we did manage to map the geology of the area, find some fish fossils and even an arthropod trackway suggesting we were on the right track! All of the team were in agreement that any future trips should take inflatable pack-rafts for ease of traversing the beautiful yet wild country of far-East Gippsland!


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Research Group Profile: Dr. Alice Clement

Alice didn’t come to Flinders Palaeontology via the usual route – she travelled half the world to get here, but, as in all the other profiles we have presented here, she just followed her dreams….

Left: Alice with a lungfish at Melbourne Museum


Somewhat unusually for a palaeontologist, I never caught the “dinosaur bug” as a child. I always had a great love for animals and the outdoors, but wasn’t one of those children who knew all the dinosaur names. I was born in England, but my family moved to Australia when I was four years old. My parents were amazed by their new country, and we endeavoured to experience as much of it as we could.

Every school holiday was spent camping in the bush around south-eastern Australia, feeding King Parrots from our hands, diving for abalone off the Victorian coastline, chasing small skinks and being chased back by giant goannas.        I held a special fascination for marine animals, taking a set of Great White Shark jaws to Ascot Vale Primary School for “show and tell”, much to the bemusement of my classmates, and later opting to visit the Tasmanian Aquaculture and Fisheries Institute for my year 10 work experience.


Left: A young Alice enjoying the beaches of her new home country

It was in year 10 that my feelings for science really began to blossom. A particularly enthusiastic and inspiring teacher, Mr MacDonell, opened up my eyes to the fascinating world of science, something that I had only found daunting before then. I then went on to study Biology, Chemistry and Maths Methods, alongside English, Renaissance History and Japanese in my final years of high school (VCE).  I took a year off after high school to go on a two-month camping trip with my father to the Gulf of Carpenteria and Arnhem Land, before moving to Hokkaido, Japan, to teach English for six months.

Upon my return to Australia I enrolled in a double Arts/Sciences bachelor degree at the University of Melbourne so that I could continue my Japanese language studies. Finding the Japanese courses a bitter disappointment, I focussed instead on my Science, going on to do a double major in Zoology and Conservation. It was then that I came to another point in my life that changed my trajectory forever.

Although having not studied any palaeontology at university, I knew I had an interest in evolutionary biology, but wasn’t tempted by any one of the four major themes of research being offered by the Department of Zoology. I spoke to Dr David Young, whose comparative anatomy lectures I had enjoyed most of all, and asked his advice about what to do. David suggested I speak to a palaeontologist he knew who was working at the Melbourne Museum, Prof. John Long.


Right: Alice in the field at the Gogo Formation, WA in 2008

Fortuitously, John was shortly due to give a public lecture at RMIT about his research. I was immediately blown away by the spectacular Gogo fossils he showed. I commenced my Honours project with him shortly thereafter for my first foray into palaeontology. John had a near-complete lungfish fossil from Gogo that had been discovered the year prior, and entrusted me to prepare and describe the specimen. In my Honours project I named my first lungfish, Xeradipterus hatcheri, named for Lindsay Hatcher who had discovered the specimen.

In 2009 I commenced my PhD, again working with John at the Melbourne Museum, but this time enrolled at Australian National University (ANU), Canberra, under the additional guidance of Prof. Tim Senden. I continued my work on fossil lungfish from Australia, going on to describe another two new species and with the opportunity to partake in some incredible fieldwork adventures.

Halfway through my PhD, John threw a spanner in the works and announced he was to move to Los Angeles. This meant that I no longer was to be working alongside one of my supervisors, and ANU started to make more and more grumblings that I should really be working on campus in Canberra. In late 2010 I moved to Canberra, leaving my partner, friends and family behind. In the next 18 months I worked closely with Dr Gavin Young who agreed to come on as an additional supervisor for me. I was also fortunate enough to meet the powerhouse duo of Prof Ken Campbell and Dr Dick Barwick, two giants of Australian palaeontology, and known in particular for their huge body of work on fossil lungfishes. During my PhD I had wonderful opportunities for travel, visiting fossil collections in museums around the world, and meeting scientists whose names I had only read in papers before then. I visited and worked in the Natural History Museums of London, Paris, Stockholm, Edinburgh, LA, Chicago, Washington DC, Philadelphia and New York. There is something truly magical about being granted access to the countless cabinets of priceless treasures held in the world’s best museums.

Above: Alice in the Muséum National d’Historie Naturelle, Paris 2010

On my travels I had met Prof. Per Ahlberg and colleagues at the International Congress on Palaeontology in London 2010, and visited his Evolution and Development lab in Uppsala, Sweden. I immediately fell in love with Sweden and the friendly atmosphere of his working group. After graduating with my PhD in 2012, I hassled Per until he gave me a job. This is my top tip for up-and-coming palaeontologists; there is a lot to be said for persistence! In early 2013 I moved to Sweden and worked with Per and his group for just over two years. There I was very productive scientifically and also made many good friends, including meeting the man who would eventually become my husband, Niels Nielsen.

Above: Alice and Niels visiting Innes National Park, South Australia in 2017

Niels and I moved from Sweden to Australia in late 2015, and I took up my current role, again working with John Long, at Flinders University in Adelaide. Having grown up in Melbourne, Adelaide was a new city for the two of us, and we took great pleasure in exploring the beaches, wineries and burgeoning café culture that our new home had to offer. Now I was working in the largest Vertebrate Palaeontology group in Australia, alongside experts in Mammals (Gavin Prideaux, Rod Wells, Aaron Camens), Birds (Trevor Worthy), Reptiles (Mike Lee) and of course fish! Here I continue my work on fish, using modern scanning and imaging techniques to examine spectacular 3D fossils to answer questions not answerable by more traditional means. 

I am so incredibly fortunate to have a job doing what I absolutely love, constantly learning and discovering things never before known to the human race! Aside from palaeontology, I enjoy being active and have played water polo (badly) for more than half of my life. I still enjoy the camping and the outdoors, travel, as well as sharing good food and wine with friends.

If you would like to learn more about Alice’s research click on the following links:

Alice’s own blog:


Dr. Alice Clement receives Vice-Chancellor’s Award for Early Career Researcher

And the awards keep coming!

Last month Dr. Alice Clement received a Vice-Chancellor’s Award for an Early Career Researcher. 

Alice works on early vertebrate evolution especially  early tetrapods and their closest fish relatives. In particular she has been re-constructing brain morphology using endocasts of the braincases of fossil lungfish (Sarcopterygii: Dipnoi) in comparison with extant lungfish. She was the first to produce the first virtual endocast of any lungfish published, in this case Rhinodipterus kimberleyensis, from the Late Devonian Gogo Formation of Australia.

Congratulations Alice!

Look out early next year for Alice’s Research Group Profile here in the Palaeo Lab’s blog.