Tuesday, 20 January 2015

Pterosaur art you've never seen before! (sort of)

Later this week I’m travelling to the Netherlands to give a talk on pterosaurs at the Museon, The Hague. I’ll be part of a series of public talks on Mesozoic reptile lifestyles celebrating the opening of the Museon's new Dino Jaws exhibition, and it should be a blast. I’ve revisited some of my older pterosaur paintings to add more detail and depth when featuring them in my talk, and thought I’d share the results here. Some of these images aren’t that old really, but, thanks to beefing up my painting rig before Christmas, I find some of my work from even a few months ago can look a lot nicer with just a few hours work. As usual, prints are available of all images shown below.

Arambourgiania: remaining huge in artwork since 2013. See this page for the original.
First up is a tweaked version of my 2013 Arambourgiania, a giraffe, and a standard wife-unit scale bar. There’s not much to say here – I just wanted to put more detail into the pterosaur so it looks better in a close-up panning presentation animation. At some point, hopefully soon, a version of this image featuring two azhdarchids will be published.

An azhdarchid in high-altitude, long distance flight. Original here.
Second, the flying azhdarchid which made a debut at TetZooCon last year. I felt the initial image was a bit flat, so this has more depth added to the background. The depicted animal is a ‘generic’ azhdarchid, although obviously similar to the smaller Quetzalcoatlus species. It’s shown flying rather high – many thousands of feet in the air – on a long-distance flight. Mike Habib and I have droned on about the awesome flight capability of giant azhdarchids for years, and we expect the range and flight speed of smaller azhdarchids – with, say, 5 m wingspans – to be relatively impressive too. They may not have been capable of booming around the planet with the same gusto as their giant cousins, but continent hopping was certainly not beyond them.

The anurognathid Anurognathus ammoni, brought to you by evolutionary processes which wanted Muppets to rule the skies. 
The third reworking shows a species at the other end of the pterosaur size spectrum, the diminutive Anurognathus ammoni. Some readers may recognise this painting from my book. Anurognathids haven’t been covered in much detail at this blog, but that will likely change soon when Mike Habib and I publish a new study on their functional morphology in the near future. This painting alludes to something which we attempt to quantify in that study – prey size. Anurognathids are frequently depicted as hawking relatively large insects like dragonflies, but – based on prey proportions in modern avian insect hawkers, and the delicate build of anurognathid skulls – much smaller insects were probably pursued instead. Catching aerial insects is already difficult enough, so why chase relatively rare, enormous and feisty prey when abundant small midges can be scooped out of the sky with relatively little effort? Because anurognathids aren't big beasts - wingspans of less than 0.5 m are common - their likely prey was probably best measured in millimetres, as shown by the Target Midge in this picture. Other features to note in this painting include the tufted wing tips and completely fuzzy face, both of which are known from fossils and, for the time being at least, unique to anurognathids. The ‘cryptic’ colouration and nocturnality are nods to recent work on these pterosaurs suggesting these pterosaurs were shy, well-hidden creatures which were primarily active at dawn and dusk. More on these neat pterosaurs as time – and manuscript progress – permits.

To finish – because I can’t not post this – here’s a poster for the superhero movie the world deserves, but not the one it needs right now. Image by Jon Davies (@SovanJedi on Twitter – you may recall his equally excellent lampooning of in-your-face dinosaur art from last year).

That logo needs a T-shirt. Image manipulation by Jon Davies.

Monday, 5 January 2015

Babified Allosaurus and prehistoric sphenodontians

A curious juvenile Allosaurus is told to get off the lawn owned by a grumpy Opisthias. Prints are available. 
With Christmas 2014 fading into memory, I can start sharing pieces of artwork commissioned for presents by various clients without fear of spoiling any surprises. I have several of these to reveal, and the first of which is above, showing an alsatian-sized Allosaurus and a feisty Jurassic sphenodontian, Opisthias. The Allosaurus in this image is based on one of the smallest Allosaurus specimens known, the partial skeleton SDSM 30510. This specimen, described by John Foster and Daniel Chure in 2006. is notable for not only its small size but also its proportions: it seems that very young Allosaurus had relatively longer legs than their parents, which is interpreted as them being more sprightly and cursorial than larger Allosaurus individuals (Foster and Chure 2006). I tried to capture these proportions accurately in the image, not the least because it was commissioned as a Christmas present for John Foster, the chap who discovered and assessed the significance of the specimen (I hear from my commissioner, ReBecca Hunt-Foster (@paleochick), that it's got the seal of approval). It must be stressed, however, that much of the reconstruction is speculative because many details of tiny Allosaurus anatomy remain unknown. Thus, a lot of the anatomy here reflects 'babification' of larger Allosaurus specimens. 

Allosaurus is joined in this image by the small sphenodontian Opisthias rarus. As with many small Mesozoic herps, Opisthias is not well known and much of what you see here as goes appearance and anatomy is based on the modern tuatara. It would be nice to know what Mesozoic sphenodonts really looked like rather than just trotting out variants of the Sphenodon bauplan again and again. Until better fossils are known, I guess this remains the most sensible option, however, as tired as it is. At least have good skull material for Opisthias and, from this, we can see it wasn't a straight replicate of the Sphenodon condition: the snout is longer, the temporal region rather shorter, and the teeth are generally more bulbous without pronounced anterior fangs. I attempted to further differentiate my Opisthias from Sphenodon with a green and red colour scheme, although its behaviour - an open mouth 'push up' pose - is a classic sphenodon threat display, a nod to the aggressive nature of modern male tuataras.

As is becoming tradition around these parts, I tweeted some in-progress images of this painting.




Coming soon: Deinonychus! The pterosaur formally known as 'Phobetor'! Comic-style Carnotaurus!

Reference


  • Foster, J. R., & Chure, D. J. (2006). Hindlimb allometry in the Late Jurassic theropod dinosaur Allosaurus, with comments on its abundance and distribution. New Mexico Museum of Natural History and Science Bulletin, 36, 119-122.

Sunday, 21 December 2014

Taking in the festive air with an azhdarchid pterosaur

An azhdarchid pterosaur takes off in a festively-coloured woodland, because it's Christmas. Prints are available
I was recently thrilled to have the above image featured on the front cover of The Anatomical Record, its depiction of a freshly launched azhdarchid pterosaur tying in with the first paper of the issue. And yes, the colours are deliberately festive, because the Anatomical Record adopts a Christmas theme for its December issues, hence the deep reds and greens of my image. There's two stories I briefly want to tell about this: one about the paper it accompanies, and the other about the art itself.

The paper

My art accompanies the work of Nick Geist and his team on the respiratory mechanism of large pterodactyloid pterosaurs (Geist et al. 2014). Lung ventilation in pterosaurs is an interesting topic. The torso skeleton of many pterodactyloids is locked up pretty tightly thanks to their vertebrae fusing together, their scapulocoracoids being tightly braced between their sterna and backbones and a series of robust, mostly immobile ribs. How were their lungs or air sacs inflated within such a rigid skeleton? Because this configuration isn't a million miles from the torso skeletons of some birds, some authors (Claessens et al. 2009) have suggested that pterosaurs may have breathed in basically avian manner: muscles anchoring to small ribs set between the sternum and larger thoracic ribs move the sternum up and down, pumping air around the body in the process.

This has been accepted fairly widely for the last five years, but now Geist et al. (2014) have presented an alternative argument. They suggest that pterosaur sternal ribs are ill suited for anchoring such muscles because they are very slender - we might even call them fragile - and often entirely cartilaginous, the latter observation borne out by their poor representation in fossil record. Indeed, large portions of the pterosaur chest seem cartilaginous and rarely preserved - the bony sterna of many species (Dorygnathus and Scaphognathus spring to mind) are tiny, and cannot possibly have supported the flight musculature indicated by their powerful shoulders and forelimbs. There must have been large cartilage extensions to these in life. Moreover, in many respects pterosaur torso construction resembles those of crocodilians more than birds, such as the manner with which the thoracic ribs articulate with the vertebrae and the essentially vertical orientation of the ribs themselves. This configuration does not permit the rib rotation required to move the sternum in respiration, and actually adds further rigidity to the anterior pterosaur torso. A bird-like respiratory mechanic may be unlikely for pterosaurs then.

So how were pterosaurs breathing, then? Perhaps the only part of their bodies which wasn't locked up tight and permitted the expansion and contraction required for breathing was their bellies. Behind the sternum sits a suite mobile bones: the belly ribs (gastralia) and the prepubes, a pair of paddle-shaped bones articulated with the pelvis, along with a few 'floating' sternal ribs. Perhaps, like crocodiles, but unlike birds, pterosaurs used this region of their body to control the pressure in their lungs. Crocodiles use contraction of their abdominal muscles to move a large, body-spanning liver forward to compress their lungs, while relaxation of their abdominal wall then allows the liver to retract and the lungs to expand, bringing in their next breath. It seems this action accounts for about 65% of air moved in and out of their lungs, with the rest coming from costal - rib - movements. Given that it seems only pterosaur bellies were flexible enough to inflict substantial changes on body volume, it is not inconceivable to think they used a similar 'belly-pump' (or extracostal pump) as their principle means of controlling air flow into their lungs.

What does this mean for pterosaur lung structure overall? It's well known that pterosaur skeletons and bodies were pneumatised to the same extent, if not more, than avian dinosaurs, prompting suggestions that pterosaurs also had solid avian-like lungs and similar unidirectional flow-through pulmonary mechanics (Claessens et al. 2009). Do the observations of Geist et al. (2014) refute this? Well, not really, but they don't support them, either. As Geist et al. point out: we really don't know anything concrete about pterosaur lung structure, and it's actually pretty hard to tell anything about them from bones alone. A bird-like lung may have been present in pterosaurs and would certainly be consistent with extensive skeletal pneumaticity. However, we need to be careful about exclusively linking extensive pneumaticity with bird-like respiratory organs: flying fish, which of course have no lungs at all, also have pneumatised skeletons thanks to outgrowths of their swim bladders (Geist et al. 2014). Moreover, our uncertainty is not helped by a general lack of knowledge about reptile lungs. This year has seen several revelations about the lungs of extant reptiles being more complex, and sometimes more avian-like, than previously thought. We might need a better handle on reptile lung diversity, and the phylogenetic distribution of different lung structures within Sauropsida, before we start making inferences about the lungs of long extinct reptile lineages. In sum, while the avian-like pterosaur lung remains a viable hypothesis, it's not the only option on the table. We might be able to gain insights into how the body cavity of pterosaurs was manipulated to move air in and out, but their precise lung anatomy remains largely mysterious (Geist et al. 2014). There's a lot more we could say about this, but you'll have to track down the full paper for further details.

The cover image

Festivodactylus in situ.

There's a bit of a story behind the cover artwork for this paper too. It's hardly the stuff of novels but, given that 2014 has been another year in which palaeoart plagiarism and working practices have been a hot topic, it's nice to share a happier, positive story about a palaeoartwork for a change.

This cover has been a long time coming, with Nick asking me for potential cover art for the paper at the end of last year. I duly obliged by lending the flying Anhanguera from my book. Nothing much happened while the paper was crunched through the publication mill, until in November the cover art arrived. Looked like I was due for the December issue, which, as noted above, Anatomical Record always jazzes up with festive colours - green, red and white. This involved tweaking the colours of my original art to meet these, as well as some stretching and cropping to fit the AR cover format. Without going into details, I wasn't really happy with the results. Uh oh. Pessimist I am, I foresaw the worst. I stress that these expectations weren't because of previous experience of working with Nick or AR, but my experiences with other clients and agencies. Protesting about art use normally leads to Bad Things: unhappily forced compromises, loss of commissions, or having to fix 'problems' without pay. When writing back to Nick and AR with my concerns, I pretty much expected the whole cover project to fall apart. I pitched, without optimism, the idea of doing another image, for a fee, to replace the modified one. Despite linking to the 'State of the Palaeoart' article I helped pen this year to substantiate my request for payment, I was expecting the same old response: lack of money, thanks but no-thanks.

To my complete surprise, Nick, his colleagues and AR were on board with everything. The 'palaeoart situation' was new to them all, but I - we, the palaeoart community - had their sympathy. Within a day, AR had been able to put things on hold for a week while I drafted a new image to their specifications and size, Nick and his team rapidly found a generous payment for the work at short notice, and we all ended up with a product we were happy with.

I mention all this for two reasons. Firstly, Nick, his team and AR deserve accolade for being so refreshingly cool and respectful of palaeoartistry. Secondly, independent palaeoartistry can seem a most hopeless industry at times: we get ripped off by everyone from toy companies and movie makers to museums and publishers; our marketplace is mainly structured around exploitation of individuals, and sympathy or assistance from those in the position to change this can be hard to find. But, as this case shows, it's not all hopeless. Increasing awareness of the issues facing palaeoartistry does help rectify them, change can happen, and we have more supporters than we know. I'm optimistic that eventually we'll all have more stories like this one than the negative situations currently reported so frequently.

Best to you all for the festive period, see you all in 2015!

References


  • Claessens, L. P., O'Connor, P. M., & Unwin, D. M. (2009). Respiratory evolution facilitated the origin of pterosaur flight and aerial gigantism. PloS one, 4(2), e4497.
  • Geist, N. R., Hillenius, W. J., Frey, E., Jones, T. D., & Elgin, R. A. (2013). Breathing in a box: Constraints on lung ventilation in giant pterosaurs. The Anatomical Record, 297, 2233-2253.

Friday, 5 December 2014

Overcooking Aucasaurus garridoi

Aucasaurus made a note in its diary after this. Simply said: "Bugger". Prints are available.
This week I've been mostly rendering an abelisaurid, the theropod group best known for short-faced, short-armed taxa such as Carnotaurus, and famous for occupying many predatory niches in southern continents while tryannosaurids occupied the north. This 'common knowledge' is only mostly true however: abelisaurids did spread to at least Europe in the uppermost Cretaceous, and represent the largest predatory dinosaurs on the continent at that time. We need not overstate that significance however: uppermost Cretaceous Europe was a topsy-turvy world where all theropods were rather small, and top-dog predator duties were likely filled by terrestrially-stalking, quarter-tonne azhdarchid pterosaurs. It seems even evolution likes a good Htichcockian-twist every now and then.

In southern continents, abelisaurids remained medium-to-large sized predators. It was one of these, the Campanian, Patagonian species Aucasaurus garridoi that Felix Bridel asked me to paint as one of my £100 palaeoart commissions. Aucasaurus is one of the best known abelsisaurids, the holotype skeleton presenting an almost complete osteology of this c. 5 m long animal, and is considered a 'derived' member of the abelisaur clan. Its anatomy is almost as unusual as that of its close relative Carnotaurus. Like other abelisaurids, the general bauplan of Aucasaurus was that of a small head, tiny arms and relatively gracile torso strapped to a robust, probably powerfully muscled hindlimbs and tail. The peculiar anatomy of derived abelisaurid proximal tail vertebrae created huge spaces for hindlimb muscle-anchorage and likely betrays tremendous sprinting power (Persons and Currie 2011). Perhaps this explains the strange upper-body anatomy of abelisaurids: their gracile bodies and reduced extremities may represent pressures to keep weight down and speeds high. Long term readers may reconcile some components of this functional complex with another group of dinosaurs, the ornithischian clade Dryosauridae, which also married a powerful set of legs with a svelte upper body.

Felix wanted to incorporate the notion that Aucasaurus and similar species were probably fast runners into his commission, but not in a conventional way. While recent research has hinted that abelisaurids were likely fast, they were likely not as agile as other taxa. Bulging abelisaurid hindlimb muscles may have created a lot of power, but they also kept the tail base rather immobile (Persons and Currie 2011). In tight turns, the tail probably fairly ineffective for adjusting gravity centres or resisting turning inertia. Felix wanted his Aucasaurus image to reflect this, showing a predator which had overcooked its pursuit of a more nimble prey item and lost balance altogether. I was more than happy to oblige: watching animals for any length of time reveals they are just as clumsy as we are, but we seldom see palaeoart reflecting this. Perhaps the only exception is predators being thwacked by the weapons of their prey, which I guess sort of reflects a clumsiness, but it's not quite the same level of slapstick as an animal slipping over.

My brief working time with Felix was a lot of fun: it was clear from our first few emails that we had a similar idea in mind and the image came together quickly. I posted my progress of the image up on Twitter and, as you can see below, the basics of the image weren't altered from the start. Efforts were made to show the Aucasaurus mid-slip: deep enough into the fall for some immediate reaction to show, but early enough that the limbs and dust still have to settle. To my mind, the animal's right leg flew out from beneath it when attempting a tight left-turn, leaving it to gaze off-canvas at whatever prey item it was pursuing.


That final Tweet did indeed feature the finished version (also seen at top), which is now being printed and packaged for delivery (click here if you would like your own copy). As usual, there's a lot more to say, but I'll have to end there. Before I go, a few nods are needed as goes sources for the picture: Scott Hartman's Aucasaurus skeletal was an important reference, as was the Coria et al. (2002) description of the Aucasaurus holotype. The notion that abelisaurid arms were used as display structures (termed 'pom pom arms' by @Blackmudpuppy) isn't new: All Yesterdays (Conway et al. 2012) explored that first.

References


  • Conway, J., Kosemen, C. M., & Naish, D. (2012). All Yesterdays: Unique and Speculative Views of Dinosaurs and Other Prehistoric Animals. Irregular Books.
  • Coria, R. A., Chiappe, L. M., & Dingus, L. (2002). A new close relative of Carnotaurus sastrei Bonaparte 1985 (Theropoda: Abelisauridae) from the Late Cretaceous of Patagonia. Journal of Vertebrate Paleontology, 22(2), 460-465.
  • Persons IV, W. S., & Currie, P. J. (2011). Dinosaur speed demon: the caudal musculature of Carnotaurus sastrei and implications for the evolution of South American abelisaurids. PloS one, 6(10), e25763.

Friday, 28 November 2014

You won't believe how interesting the Mesozoic mammaliaform Morganucodon watsoni actually is!

Morganucodon watsoni forage for insects and spiders at night among Carboniferous limestones in early Mesozoic Wales. Empty, torn webs suggest they're having a good night, while forest fires burn in the background. Prints are available.
Vertebrate palaeontology textbooks always devote a good chunk of space to morganucodonts, a clade of Triassic-Jurassic Mammaliaformes representing some of the first wholly 'mammal-like' synapsids. Even folks largely uninterested in Mesozoic synapsids will be familiar with two morganucodonts - the Triassic, South African Megazostrodon and the widely-spread Triassic-Jurassic Laurasian genus Morganucodon - because they have become the quintessential 'Mesozoic mammal': small, shrew-like creatures which scurried around the feet of reptiles. Their lack of unusual proportions or adaptations for specialist lifestyles has probably played a part in Mesozoic mammaliaforms being considered a bit boring compared to their dinosaur contemporaries (sorry, mammal palaeontologists), a feat not helped by a deficit of new, particularly interesting artwork of them. Morganucodont representations in palaeoart are frequently quite 'diagrammatic' with 'generic' early Mesozoic backgrounds, animals in lateral or anterolateral aspect to show off their anatomy and daylight settings, despite frequent discussion about their possible/likely nocturnal habits.

Recently, I was asked to produce a reconstruction of Morganucodon watsoni for some friends (above). Being better versed in reptiles than mammals, I had to undertake a fair bit of research to bring myself up to speed on morganucodont anatomy and evolution. Turns out that reputation for being dull is entirely unwarranted: Morganucodon, its relatives, and the world they inhabited are really fascinating. Indeed, they should be bona fide fossil celebrities: Morganucodon and Megazostrodon were the first Mesozoic mammaliaforms known from anything like complete remains (albeit lots of fragments for the former, rather than a single complete specimen) instead of mere teeth and jaws. Their discovery in the mid-20th century can be seen as the start of a new era of understanding of Mesozoic mammaliaform life, and a forerunner of our now rapidly expanding knowledge of Mesozoic mammal diversity.

Initially, I wanted to write a long, detailed post about this painting and the animals it depicts, but that just won't be happening this side of 2015. But, dammit, Morganucodon is too cool to ignore completely or short-change with a 'picture of the day' post, so here's a quick-fire, from-the-hip summary of the research behind the work.

We'll start with the setting. Fossils of M. watsoni occur in British Triassic/lower Jurassic 'fissure fills' cropping out around Bristol and south Wales. These deposits represent ancient infills of caves carved into much older Carboniferous limestones, which are perhaps best known for yielding the sauropodomorph Thecodontosaurus. Fissure fill outcrops occur in multiple quarries across the southern UK and are frequently rich in fossil material, but the mammaliaforms are rare components of the fauna constrained to just a few localities. Dating the fissure fills is not easy because they contain few fossils useful for dating. Some quarries are reliably set at the Rhaetian, but they are probably not all of the same age: some may be as young as the earliest Jurassic. These include sites which contain M. watsoni fossils, which is why different texts give slightly different ages for this animal.

The upper Triassic/lower Jurassic of Europe would be an ideal holiday location for many. The desert landmass of Pangaea was in the process of breaking up, and Europe - including the southern UK - was in the process of being flooded by shallow seas. By the time M. watsoni appeared, Britain's only landmasses were small, low-lying, forested islands which, in terms of climate and general topography, would have resembled those of the Caribbean. Burned plant remains in the fissure fills indicate that the forested inlands of these islands burned on occasion, the remnants of forest fires being washed into coastal limestone caves by storms and floods. We can identify the fissure fill caves as coastal because they contain marine fossils along with terrestrial and freshwater species. It's on these limestones that I set this painting, a deliberate move to avoid another cycad-filled 'semi-arid' Triassic scene.

The island home of M. watsoni was ruled by reptiles - but not necessarily the ones you expect. Although dinosaurs were common, represented by both sauropodomorphs and theropods, the most abundant and diverse reptile group were sphenodonts. These guys deserve their own posts and paintings one day, their Mesozoic run being far more than just spreading tuatara clones across the world. Anyway, the decaying body of one of these - Planocephalosaurus - can be seen in the foreground of the painting above. As these indicate, the sphenodonts contemporary with M. watsoni weren't huge, but they still likely gave the resident mammaliaforms a hard time in competing for similar food resources. It's interesting to ponder how these animals carved up their respective ecologies to avoid direct competition with one another.

Scientists predict that, if Morganucodon were alive today, the sight of them would make grown women leap on their chairs, clutching the skirt tails in fear. 
What of Morganucodon itself? The skeleton of M. watsoni is small (about 10 cm nose to tail base) and extremely mammal-like, with differences limited to fine anatomical details. For instance, the composition of the Moranucodon jaw-joint isn't a simple as those of true mammals, the scapula is a little bit 'reptile-like', and (according to some sources, anyway), there may have been some degree of bowing to the fore- and hindlimbs when walking or standing. This doesn't necessarily indicate sprawling limbs, but they may not have been as neatly tucked under the body as those of other mammals. Because morganucodont skeletons are so similar to those of true mammals, it seems likely that many aspects of our basic soft-tissue anatomy were established by this point of synapsid evolution - ear pinnae, fur, loose skin and so on. Direct evidence for these are currently lacking in morganucodonts, but there is indirect evidence for fur from the relatively large Morganucodon brain. Although not as large as those of later mammals, Morganucodon endocasts were expanded beyond a typical 'reptilian' condition, and much of this reflects an enlarged neocortex. This part of the brain processes sensory information, and it may be that the covering mammaliaform bodies with pressure-sensitive hairs promoted this development. I find this observation quite interesting because other lineages with fuzzy bodies - bird-like dinosaurs and pterosaurs - have also developed expanded brains and enhanced abilities to process sensory information. These enlargements are often attributed to enhanced balance and coordination, but might they also be related to the developed of sensitive fuzzy hides, as is assumed for mammals?

Because art of Mesozoic mammals scurrying about at night is so rare, I wanted to capture this in my painting. The evidence for nocturnal activity in Mesozoic mammaliaforms is not as strong as you might think - it's largely based on the (questionable?) assumption that reptiles forced early mammals into nocturnal niches and the abundance of small nocturnal mammals in the modern day - but what the heck: it makes for a fun picture. It seems nocturnal mammals are often equipped with tremendous sets of whiskers, so I put similar features on my Morganucodon to help them find their way around, They may not be 'true' whiskers, in the sense of derived, mobile whiskers of modern mammals, but it doesn't seem unreasonable to imagine long, stiffened sensory hairs of some kind developing rapidly once fur was attained.

And... blast it, I'm out of time. So many other things to say, but they'll have to wait for another time. Coming soon: various theropods, festive pterosaurs, er... and probably other things too!

Friday, 14 November 2014

Of tiny tyrants and Triassic big-heads: Tyrannosaurus rex and Garjainia madiba

This week sees two new pictures of mine being 'released' in one way or another. Much as I'd like to go into lots of detail about each, that realistically isn't going to happen anytime soon. I'm going to attempt a sort of 'picture[s] of the day'-style writing. I'm sure I can do it... right?

Chidumebi Browne's resting Tyrannosaurus teens

Two young adult old male (left) and female Tyrannosaurus on a break from pillaging and destroying the Cretaceous, distracted by a group of ruffian moths. Concept and animal colouration by Chidumebi Browne. Prints are available.
First up is one of my '£100 palaeoart offers', painted for Chidumebi Browne. Featuring Tyrannosaurus, which needs no introduction as an dinosaur most famous for antisocial tendencies, Chidumebi wanted a more relaxed approach to tyrant dinosaur art. The concept called for Tyrannosaurus at the smaller end of their size scale, settling on individuals approximating the size of the 'Jane' specimen - about half the length of a fully-grown animal. There were also requests for contrasting blue and red colours on a male and female. I was happy to oblige, seeing as some degree of dimorphism is defensible for dinosaurs even at on half their full-grown size. Like mammals and non-avian reptiles, Mesozoic dinosaurs hit sexual maturity well before attaining fully ossified, completely grown skeletons and, for Tyrannosaurus, specimens in their early teens were probably reproductively active. In that sense, some features related to sexual behaviour might be expected in 'teenage' animals. Such individuals - better considered very young adults rather than large children - look rather different to their super-size contemporaries with their longer legs and more gracile build. Some of that is obscured here by the extensive feathering covering both animals (if you look very closely, you can just make out the arms of the sitting male), but their long legs at least show through.

The concept called for a a series of moths catching the attention of the male tyrant: initially one was ordered but, even at half-size, Tyrannosaurus is pretty big, so a few more were added to make them more conspicuous. My initial thought was to use butterflies rather than moths for the role of the lepidopterans, but I was surprised to learn that butterflies don't appear in the fossil record until well after the K/Pg event. Moths have a fair, if not especially extensive Mesozoic record, so they seemed a safer bet. They certainly add an air of tranquility to the scene not featured in a lot of theropod art: well done to Chidumebi for an excellent idea.

There'll be more output from the '£100 palaeoart offers' soon, although note that the offer is now full - over-full, in fact. There's some great ideas which I'm hoping to do justice to, so thanks to all who got their orders in - the offer sold out very quickly. If you didn't manage to get something to me on time, prints are still available - wittonprints@gmail.com is the address to contact for them.

Gower et al.'s Garjainia madiba: yes, the head is that big 

Gargainia madiba sp. nov., South Africa's newest erythrosuchid. From Gower et al. 2014.

Art number 2 is a life restoration of a new species of Early Triassic stem-archosaur, the erythrosuchid Garjainia madiba, described by David Gower and colleagues in this week's PLoS ONE. Unearthed in South Africa and named for Nelson Mandela ("Mr Mandela was known affectionately as 'Madiba'" - Gower et al. 2014), G. madiba has been making surprising ripples on Twitter and Facebook because of its rather enormous head. I say surprising because, for an erythroshucid, G. madiba is fairly typically proportioned - so far as anyone can tell, anyway. We don't have anything like a complete skeleton for G. madiba, although many aspects of its anatomy are represented in fragmentary specimens. It is currently distinguished from its relatives by fine anatomical details, perhaps the most notable being its large postorbital and jugal bosses of unknown function (best seen in the reconstructed anterior aspect, above). The discovery of more substantial G. madiba fossils may reveal more obvious distinction from other erythrosuchids, but, for the time being, the best we can do reconstruction-wise is show G. prima with a madiba upgrade package. Still, given how similar the two Garjainia species seem to be, this does not seem unreasonable.

Restoring Garjainia was a lot of fun because it forced a 'back to basics' approach to the artwork where David Gower, Richard Butler and I spent a lot of time discussing proportions, muscle distribution and posture. Many fossil animals - dinosaurs, pterosaurs, etc. - have been restored so often that the basic foundations of their anatomy are very well known, but this is not so for Garjainia and other erythrosuchids. A personal revelation to come from this process was evidence for enlarged areas of axial musculature on erythrosuchid skeletons, indicated by the rather tall neural spines of their necks and backs. This might give some insight into how their large heads were supported: a particularly well-developed, strong set of axial muscles. The posterior faces of their skulls are also wide and robust, providing space sufficient to anchor powerful neck muscles. But erythrosuchid anatomy was likely not held together only by brute strength: there's also some clever biological engineering at work. Like many archosauriforms with huge-looking heads, their skulls are more gracile and lightweight than they first appear, actually being fairly narrow for much of their length and riddled with fenestrae. We tried to show the former in our anterior aspect reconstruction: note how slender the snout of the animal is compared to the cheek region. The result is a head which is undeniably large, but probably much more manageable than it first seems.

For a lot more on Garjainia and other erythrosuchids, including the life restoration in situ, full descriptions of G. madiba anatomy and revisions to the diagnosis of the group, Gower et al. (2014) can be read here (hurrah for open access!). Thanks to David and Richard for bringing me on board, and congrats to them on the paper.

Coming soon: small, brown Mesozoic mammialiaforms! Yes, they are exciting. Really.

Reference

  • Gower, D.J., Hancox, P.J., Botha-Brink, J., Sennikov, A.G., & Butler, R.J. (2014) A New Species of Garjainia Ochev, 1958 (Diapsida: Archosauriformes: Erythrosuchidae) from the Early Triassic of South Africa. PLoS ONE 9(11): e111154. doi:10.1371/journal.pone.0111154

Friday, 7 November 2014

Prints, custom palaeoart, and antisocial Triceratops

Hey now - look at this: there's a way to buy high-quality prints of my artwork, and it's dead simple. Drop me an email at wittonprints@gmail.com with your requirements, pay off the invoice, and wait for your prints to arrive - hopefully within a week or so of order confirmation. Prices, sizes and all are discussed over here.

To celebrate this occasion, I'm also offering a limited number of ├╝ber-cheap palaeoart commissions for private clients:


Yep - your own palaeoartwork, a print and delivery for just £100, which is a stupidly cheap price for original artwork. Full details (including a few important conditions) are here. As you may expect, I can't sustain working at that price for long. For that reason, there's only five of these deals being offered, and at time of writing, three of these deals have been taken. If you want in, don't delay. Don't despair if you miss this deal but would still like your own commission: drop me a line and we might be able to work something out.

Finally, because things have been a bit quiet about here for the last month or so, here's something to fill the void: a monochrome bristly Triceratops horridus, the dromaeosaur Acheroraptor temertyorum, and an interaction inspired by the wise, yellow philosophy of The Simpsons.

"...and like people, some [animals] are just jerks."

Apologies for yet another short post. Coming soon (when I'm allowed to publish them): Mammaliaformes! Heaps of pterosaurs! Deinonychus! Diminutive tyrannosaurines! And perhaps other subjects too!