Soundbites is a weekly (less often when Danielle is doing fieldwork) feature of the coolest, newest bioacoustics, soundscape, and acoustic research, in bite-size form. Plus other cool stuff having to do with sound. Yes, I know it’s been awhile. I’ll try to make this one extra awesome to make up for it.
Dolphins have social food calls:it turns out that humans aren’t the only ones to gossip about our food (see anyone’s Instagram feed ever). These researchers found that wild bottlenose dolphins had particular social calls that were highly correlated with food calls, and didn’t occur otherwise. Dolphins might therefore be sharing information about the food patch itself.
Invasive cane toad calls change the calling patterns of native Australian frogs: as I’m deep in frog fieldwork, you just knew I’d have some frog news for you. Invasive species are bad as it is (and cane toads are particularly bad), but they might also be changing the way native species communicate. Here, one native species decreased their call rate with playback of cane toad calls. I hope these authors extend this work with observational studies, there’s a lot of potential here.
Birds shift the frequency of non-breeding calls above noise:we’ve heard about birds shifting their frequency before, but only with breeding calls. Here, black-capped chickadees (a local species) and American goldfinches both shifted their non-breeding calls (described as “chickadeedeedee” and “po-tay-to-chip”, which I love) above the frequency of urban noise.
Fun link of the week:apropos of absolutely nothing at all, did you guys know that sand dunes sing!??!?! Not only do they sing, they sound creepy! Someone needs to work on some weird ambient music with the stuff, stat!
Soundbites is a weekly (biweekly, occasionally) feature of the coolest, newest bioacoustics, soundscape, and acoustic research, in bite-size form. Plus other cool stuff having to do with sound.
Fish sound preference may inform migration patterns:here’s an interesting one. Water sounds are thought to be important in triggering upriver migration patterns, so these researchers played some tones and watched how fish reacted. They avoided the 100 Hz tone and were attracted to the 200 Hz tone. Then they fed this into a GIS model and think that they can replicate patterns now–they might even be able to manipulate migration behavior.
Fun link of the week:a scientific examination of whether or not a duck’s quack actually does echo (I love scientists because we do this sort of thing in our spare time).
…A question that sometimes occurs when I tell people that I study the sounds of the whales. Still, my very close non-scientists friends do think that I try to talk to dolphins. This might not be accurate since my research equipment and purpose of my study do not allow anything like this, but essentially I do try to spy on their “conversations”.
Meet Dory, a (fictional but funny) colleague of mine
One of the functions of sound in dolphins and whales is communication. Communication is a keyword in bioacoustics and is defined as being “the transmission of a signal from one organism to another such that the sender benefits from the response of the recipient”. There are different purposes that it serves living organisms and different ways to express it.
A primary purpose of communication is to attract and repel. Plants use chemical signals that get transmitted through the air or their roots, people use the smell of pheromones to attract each other, and skunks use the same signal to repel. Dogs and foxes use face and body gestures to express submission and aggression. Elephants use touch interlinking their trunks as a means of close communication. Especially for attracting mates, vision (peacock elaborated feathers) and sound (bird songs) are both very useful.
Do you get the message?
Though the most common well-known animal communication signal heard by humans is the bird song, there are all sorts of animals that rely on their hearing and vocal ability to succeed and survive. Whales, the modern giants, appear to be experts in the art of sound communication with different species each having their own sounds. They use these sounds to navigate, locate and capture prey, communicate about the environment and the availability of food or predators, and to attract mates or repel competitors.
Whale chat #alltheycareforisfoodandromance
http://www.michw.com/
Such acoustic signals may be (a) instinctive that is genetically programmed or (b) learned from others through social learning.
Social learning is the information moving through communication from one organism to another. This information then passing on is what we call culture. Without this transfer there would be no life, no evolution, no biology. Culture is why we have the Parthenon, the South Park, boy bands and the MIT. What you read, like this blog, that you may pass it on is culture.
Random example of culture: the Parthenon
Cultural transmission, the social learning from conspecifics is believed to occur in a number of groups of animals, including primates, cetaceans and birds, elephants and bats. Cultural traits can be passed through different paths.
Cultural transmission can be done vertically: from parents to offspring, obliquely: from the previous generation via non related individuals to younger individuals, or horizontally: between unrelated individuals from similar age classes or within generations.
3 families of sperm whales and how they get their culture transmitted
Of the several types of social learning which have been recognized, imitation is particularly significant for the propagation of culture. Humans can imitate new sounds and learn how to use them correctly in social situations. This is called vocal learning which is considered to be one of the foundations of language.
My favorite example of imitation in the animal kingdom is the lyrebird of S. Australia, which has an unbelievable capacity for mimicry. During the breeding season in South Australia, the male lyrebirds spend six hours a day calling, doing their best to attract the ladies. They have the most complex syrinx (vocal organ in birds), and they make a remarkable use of it!
I know I am repeating myself since I have posted a video of the lyrebird before but this time the famous mime has enriched its repertoire with more sounds that will make you wonder how and why… Check out the lyrebird’s latest hits here.
Next I would like you to meet Luna, another excellent mime; Luna is a male orphan killer whale. Luna has been all alone since the age of two, living off the coast of Vancouver Island, Canada. There, in 2001, Luna became popular for getting in close proximity to people, interacting with local boaters and perfectly mimicking boat noises. A tragic result of this interaction was the tragic death of Luna in 2006 due to a tugboat collision!
Culture, through social learning, has been studied and papers have been published mainly in only four species of cetaceans: (1) the humpback whale, (2) the sperm whale, (3) the killer whale, and (4) the bottlenose dolphin.
Humpback: the Diva
Humpbacks are the most popular singers of probably all the non-human mammals. They have even released CDs with their songs ! When we think of whale songs the humpback is what we have in mind. They represent the best understood horizontal culture of cetaceans.
The males produce series of vocalizations that form songs used in sexual selection (through mate attraction and/or male social sorting). Their songs are very complex and can be heard mainly in breeding grounds and whales can hear them up to 10 km (about 6 miles) away. Whales sing the same song for hours and hours. Populations within an ocean basin have similar songs with this similarity dependent on geographical distance between populations.
Humpbacks can change their song after hearing other songs. A terrific example takes place in the southern ocean where the songs are horizontally transmitted from eastern Australia in the west across the region to French Polynesia in the east. The songs have been documented radiating repeatedly across the region from west to east, usually over a period of two years. The result: soon the song that was recorded on the east region is now fully replaced by the west region hit. This seems to me to be really similar to our music culture transmission.
Earworm!
Killer whales: The Intellectuals
The Sea Pandas (as some marketing teams have proposed renaming killer whales to help promote their conservation) are highly social.
The cheeky ones
The populations off the west coast of Canada have been studied for decades and are divided in different ‘‘types’’: the residents, transients and offshores. These 3 different types have diverse feeding preferences and subsequent vocalizations. The residents feed on fish and are highly vocal, the transients feed on marine mammals and are much quieter to not reveal their presence to their prey that has good hearing abilities. The offshores are also highly vocal and feed on sharks and rays.
Extroverted vs. Introverted (Resident vs. Transient)
Killer whales that are separated by great geographical distances have completely different dialects. An analysis of Icelandic and Norwegian killer whale pods revealed that the Icelandic population made 24 different calls and the Norwegian whales made 23 different calls, but the two populations did not share any of the same calls.
Besides dialects, killer whales have been shown to learn vocalizations from other species. Yes, they speak foreign languages! At a water facility, where they socialized with bottlenose dolphins, they changed the types of sounds they made to resemble those of their neighbors.
If I was not so enthusiastic about the sperm whales, killer whales would definitely receive most of my scientific admiration. They have evolved outstanding sophisticated hunting techniques and their vocal behavior is impressive, being specific to certain groups and passed across generations. Killer whales are great examples of cultural organisms.
Keeping these animals in captivity sounds like even less of a good idea now, right?
Bottlenose dolphins: the Eponymous
Bottlenose dolphins are well known for their signature whistles. They have stereotypical signatures attributed to each individual that work as their name. This helps to maintain contact between mom and calf or between individuals in a group. Each bottlenose dolphin has its own unique whistle and it uses it to broadcast their location and identity to others.
3 different whistles from different individuals. Hard to call a dolphin by its name…
Most of the characteristic whistles are usually fixed for all the lifetime of the dolphin. However in some cases, when a male dolphin leaves mom and joins with other males to form an alliance (which might last for decade), their distinctive whistles converge and become very similar. So the longer they stay together the more similar their whistles become. Based on the same reasoning, I can’t understand why my English accent is still the same after three years living in USA!
Sperm whales: the Bignose
Sperm whales are among the loudest animals on Earth, and my favorite (not sure if I have already mentioned my preference). They owe this to their huge nose which functions as a massive click producer. They also have the biggest brain. They produce a variety of loud and distinctive types of clicks for different functions. One of these types of vocalizations is called coda. It is stereotypical patterns of clicks resembling Morse code, and frequently serves social purposes. Codas are usually heard when the group of animals rest or socialize at the surface of the ocean. Similar codas used by one group may help maintain group cohesion after its members are done feeding.
Chilling after dinner
It is thought that each sperm whale has its own individually distinctive coda pattern and it has been reported that groups within one geographic area tend to have more similar codas than groups from further away. The “five regular” call is one of the few codas that all sperm whale groups around the globe use in their regional dialects; while the “plus one” type seems to be specific to Mediterranean inhabitants. These vocal behaviors are transmitted vertically, and loosing members of the population may seriously impact the transmission of this cultural trait that carries important information content vital for the survival of the population.
The “regular 5” and the “plus one” codas
We don’t need to watch Interstellar to search for life in different solar systems and unknown worlds. Like Anne Stevenson said: “the sea is as near as we come to another world”. The ocean is vast largely undiscovered. We can consider the open sea an intriguing new wet universe. In interstellar, communication or miscommunication played an important role and turned out to be vital for rescuing the world. Father and daughter that could not directly speak to each other used binary code to transmit their messages through different dimensions. The cetaceans also transmit their messages through codes that we try to identify and understand. It is vital for their world to be able to use these sounds to communicate. You can correctly guess that we are using their home for our anthropocentric purposes and we are being very noisy neighbors, polluting their ocean and impacting their survival. This can be changed… If you are looking for New Years resolutions…
Like in the movie, it’s not Them that will help us save the world. No external factors are required, all the power is in us!
Happy, quiet and peaceful holidays to y’all!!
This post was inspired by the presentation that me and Selene gave on Saturday 12/13/2014 for the Oregon Chapter of the American Cetacean Society entitled: “Do you speak whale?”.
Soundbites is a weekly (biweekly, occasionally) feature of the coolest, newest bioacoustics, soundscape, and acoustic research, in bite-size form. Plus other cool stuff having to do with sound.
Bill morphology shifts along with fundamental frequency in urban birds: we talk a lot in ORCAA about the way animals change their vocalization in response to outside pressure, but there are physiological constraints on the changes that can be made (for example, there’s no way I can sing bass, although I can get to tenor if I warm up). Birds in urban, disturbed areas had longer, narrower bills, which might help them get food at feeders, but actually makes it harder for them to vocalize at the higher frequencies that are more advantageous in noisy areas.
40-million-year-old protowhale was sensitive to low frequency sound: I’m a little bit of a paleo-nerd, so this was pretty cool to see. They looked at CT scans of the inner ear structures of this fossil, Zygorhiza kochii, and compared it to current mysticetes, and found that they were similar, indicating Zygorhiza was probably also sensitive to low-frequency sound the way our current baleen whales are. This implies that the order developed with a sensitivity to low-frequency and toothed whales’ high-frequency sensitivity came later.
Baird’s beaked whales are affected by sonar: beaked whales are some of the most mysterious ocean-dwellers, and we know little about their life history, behavior, or response to noise. Using acoustic tags, these researchers found that a Baird’s beaked whale displayed unusual diving behavior after being exposed to sonar.
Fun link of the week: I’m taking next week off because it’s the day before Thanksgiving here, and I’ll be traveling and then spending four straight days eating my family’s amazing cooking. So this week I give you a video about turkey vocalizations! Bonus: if you have energy, a paper cup, some string, and a paperclip after gorging yourselves on turkey, you can make a simple turkey-ish call.
In the midst of the summer and early fall when I was traveling a bunch and doing field work, I remember thinking how nice the term would be to be in one place for a while and get some analysis/other work done. What I didn’t realize was how unexciting my life would be for blog posts….
I guess excitement depends on your interests, though, because for me there have been SOME exciting moments standing in front of my computer. I’ve spent the last month putting my master’s on hold, instead analyzing acoustic data collected from one of our gliders that was deployed back in March, and then deploying and analyzing another glider all within the month of October. Want to see what I found? Good. I was going to put in the images anyway.
Here’s a Stejneger’s beaked whale click. The top image is a long term spectrogram, or LTSA, that shows 15 minutes. All the little bits around 50 kHz are beaked whale clicks. The middle spectrogram just shows one click during a fraction of a second, and the bottom shows the wave form, or the amplitude of the click.
From the March deployment, the excitement came in the form of TONS of beaked whales. Like so many. Like all the time. Including the super weird looking Stejneger’s beaked whale (Mesoplodon stejnegeri). I can tell the species by what frequency the click is at, how much time there is between clicks (inter click interval, aka ICI fyi), and the duration of the click. They are all unique features for this species of beaked whale, which I know thanks to other people confirming that by combining visual and acoustic data like was done by theses lovely folks at Scripps.
Here’s two porpoise species detected together – harbor porpoise (the two higher frequency red specs) and Dall’s porpoise (the middle, slightly lower frequency). All together a bunch of those clicks make up that light blue section in the LTSA on the top.
The March deployment also brought excitement through porpoise recordings! Did I mention that glider was the first of its kind to record ultra high frequencies? We used a 394 kHz sampling rate, which means we could detect vocalizations up to 196 kHz, which is where porpoise and a few other odontocetes (toothed whales) vocalize. Most equipment doesn’t sample that high (memory gets filled too fast) so this was pretty neat-o. I’m a big fan of looking for these ultra high frequency encounters because they are so obvious in the upper part of the LTSA, far above the background noise.
And like I mentioned, I did go out in the field one day. We deployed one of our new gliders for a few days just outside of Newport in early October, and I went out on the recovery. I took this one super exciting picture of these gulls on the back of the ship. You’re welcome.
Piper helped Holger and Alex prep Will the glider before he got deployed in early October.These gulls agree with “no excitement November”. Until I threw pistachio shells over the side. Sadly this is the only picture I took of the whole glider recovery.
Soundbites is a weekly (biweekly, occasionally) feature of the coolest, newest bioacoustics, soundscape, and acoustic research, in bite-size form. Plus other cool stuff having to do with sound.
High-frequency vessel noise may have an effect on marine mammals in shallow water: much of the anthropogenic noise that we’re concerned with at ORCAA, whether it’s road or vessel noise, is low-frequency because of the attenuation of higher frequencies. However, in shallow water, the high frequencies may not attenuate as much and may therefore cause masking for higher-pitched odontocetes.
Direct-developing frogs are more reliant on climate cues to start calling: what a week, we get one whale link and one frog link! There are some species of entirely terrestrial frogs that don’t go through a tadpole stage; instead, they hatch as mini adults. However, the eggs still need to be kept moist while they’re developing. These researchers found that the onset of calling was more closely tied to high humidity and rainfall than it was to overall air temperature, which is a different cue than most species of tadpole-metamorphosing frogs.
Fun link of the week: I’ve been practicing for my presentation at ASA in a couple of weeks, so I’ve been asking myself this question regularly: “does my voice really sound like that?” Here Greg Foot examines why our voices sound different on recordings.
“Whistling while you work is only acceptable if you are one of the 7 dwarves. You are too tall to be a dwarf; or the Snow White”, I can imagine Holger, my advisor, saying.
Some people are whistle sensitive
In reality Holger is too wonderful to mind if I whistle while I work or not. But I actually don’t. Which a few unfortunate people that have witnessed it will unanimously agree that it is for the common good. Nevertheless, I get to work on whistles!
The animals that I work with are notorious whistlers! You might consider yourself skillful in whistling, an expert in whistle-flirting and dexterous in folding you tongue and sending loud whistles miles away to your friends on the other side of a soccer field, but that is just like whistling against the wind to dolphins. If you compare your selves to their whistling capabilities you will be embarrassingly defeated. (In every case, several analysts and Experts of Life support that comparing yourself to others can only make you unhappy.)
Dolphins and killer whales, which belong to the Delphinidae family, produce 3 types οf sounds:
1. Clicks used for echolocation that help them navigate, find food and capture it,
2. Burst pulses that are rapid rate clicks and serve similar purpose but with higher definition, and 3. Whistles
Types of delphinid sounds and how they look (frequency on the y axis and time on the x axis)
Dolphin whistles are generally of narrow bandwidth and frequency modulated sounds that commonly last for half to a few seconds, much longer than the individual clicks and they are of lower frequency. Their characteristic lower frequency allows them to propagate in longer distances and their function is believed to be primarily social.
Whistles are considered to be a product of the same mechanism that generates the clicks: air that goes through the nasal passages of the dolphin’s head. The odontocetes (toothed whales) don’t literally vocalize, since they don’t use vocal cords like we do. They use the air that enters their blowhole to make sound by canalizing it through passages and their melon (the fatty tissue that makes their forehead look rounded). This video: Echolocation and sound production mechanism can give you a good representation of it.The production of whistles seems to require larger volumes of air which makes them unsuitable for echolocation since air volume is reduced by hydrostatic pressure during diving and foraging. Instead, the dolphins are thought to use them for communicative purposes, to stay in touch with their gang in the vast oceans.
I am particularly interested in the whistles. Especially the dolphin whistles. As I described at my previous post, this past summer I collected a bunch of different dolphin species’ acoustic recordings from the Aegean Sea. These recordings will help me create a sound library for the dolphin populations that dwell the eastern Greek Seas, essentially a whistle-bank for the populations in that area.
In addition to the different dialects or accents that the dolphins populations have and I have previously mentioned, they also have names that the scientists call signature whistles. Specifically, the bottlenose dolphins are known to learn and recognize whistles that are unique for every individual in a group and these whistles are used to broadcast the identity and location of the animal that produced them. This characteristic is crucial for the contact between mother and offspring, for feeding and protection from predators. Most of the characteristic whistles are usually unchanged for all the lifetime of the dolphin. But occasionally, when the male dolphins leave their mom to experience the adult life in a group of other males their distinctive whistles actually converge and become very similar!
Besides the dolphins, more animal species seem to find names meaningful. A striking example is the one of the green-rumped parrotlet that lives in Venezuela.
Touch is communication too. Even if it happens with the beaks.
This cute little green parrot is attributed a whistle name by its parents and it gradually learns it by them. In this delightful video you can see how the researcher discovers the learning ability of the parakeets in contrast to the genetic encoding of communication mechanisms in this species.
Birds have actually been the very first research target of bioacousticians. Even though they can fly away and escape the
Some birds can be so weird (maybe is the flying…)
claws of their scientific fate, it is still easier to study them than the marine mammals that slip away in the open ocean. A remarkable example of unusual bird vocalizations and intriguing to research specie is that one of the superb lyre bird of
South Australia! In this specie the male, in order to attract the girls, besides the elaborated dance and feather display, can also imitate the calls of more than 20 other bird species. This bird is so good at mimicking others that it can confuse even the birds that it is copying.
But the lyrebird is not only imitating other birds; it has evolved his skills beyond living organisms. A real master of mimicry! It is able to incorporate in its repertoire any sound that hears in the forest. Like that of a camera shutter, or a car siren, or chainsaws! Or the sound of the fridge door opening and closing (would be the case if my house was its habitat)…
But seriously, I am not making this up! Check this jaw dropping video to see for yourselves. This bird is either desperate to reproduce or the females don’t really know what they want.
At this point I will paraphrase Snow White; whistling is a lot of work!
Some people seem to have a talent in whistling. They can whistle entire songs, or the more eccentrics can whistle the whole alphabet. They use their lips, teeth and tongue to do it, their fingers in all sorts of strange formations, their palms, and a wide range of imaginative accessories. Personally, it took me several weeks at the age of 23 to learn how to whistle. Soon I was glad for my achievement as it turned out to be a remarkably useful skill when I got a dog. Loud, piercing and sharp… a whistle is hard to ignore. Even if you are a dog.
You might be surprised to discover that whistles are not used uniquely by animals for their communication. Since the Antiquity people used whistles to communicate in very long distances. Whistles can travel much longer than speech and can overcome ambient noise much more effectively. You might have noticed that often people that work in bars use them to signal among them.
In the natural environment, in locations where the landscape consists of deep valleys and steep ravines, whistled languages were common within some human communities. Before the 1940s, when the phone was not widely used yet, people replaced words with whistles to send messages that would overcome distance issues. Whistles have the ability to travel up about to two miles (3.2km), which is much further and with less effort than shouting. Initially these languages were invented and largely used by shepherds, and for long time they were a common way in agricultural communities at isolated villages to transmit news, events or emergencies.
Examples of these communities and their whistled languages still exist! The cases of the Village Antia in the Greek island of Evia, the Kuskoy Village “Bird Village” in Turkey, and the “Silbo” language at La Gomera at the Canary Islands in Spain, are the exceptional cases of alive whistled languages.
In this uncommon language, consonants are distinguished by changes in pitch over different intervals of time and the whistle is a substitute of the original language which gets compressed. The whistled language is not a code, has rather defined characteristics.
Evidently marine scientists are charismatic people with variable interests and acute curiosity . It appears that Cousteau was also interested in analyzing the characteristics of La Gomera’s whistled language!
Nowadays these languages are slowly becoming extinct. However, it is encouraging that in La Gomera at least, the Canary Islands’ government links the whistled language to the identity of the people and recognizes its value as part of the traditional culture in this area and try to preserve it. As a result, La Gomera is one of the few places in the world where children learn to whistle in schools!
Aristotle in the History of Animals wanted to describe what separates animals from people. What is that makes us different: is it the reason, the language or the laughter? Several recent researchers and philosophers suggest that it is the culture. But what do we define as culture. Is it the ability to learn, to mimic, the language? It turns out that both people and dolphins use certain sounds, in this case whistles, in form of language in order to communicate. The human community considers the human whistled language as a cultural heritage worth protecting and maintaining. Similarly, without me trying to attribute human qualities to the animals, cetaceans have social learning skills and cultural capacities that are advanced and worth maintaining as well. It is our doubtless responsibility to protect them.
During my childhood, my mom would wake me up every morning with whistling melodies. I surely despised it. Mainly the wake-up- in-the-morning part. The whistling part was also very disturbing, especially because it was such an effective mean to get me off the bed! Now I am particularly attracted by whistled melodies and I am a fool for songs that include them. So I prepared my favorite Top 10 of songs with whistling, with extra 2 Greek tracks. #1 on the list is my current wake-up-song. I love it! Not the wake-up part, I still cannot get over that…
11. Το ποδηλατο (the bicycle)- Ελένη Βιτάλη
12. Συννεφούλα (the little cloud)- Διονύσης Σαββόπουλος
**Stay tuned in our “vocalizations” through our tweets @ORCAAlab and our facebook updates at Orcaa Lab**
Soundbites is a weekly (biweekly, occasionally) feature of the coolest, newest bioacoustics, soundscape, and acoustic research, in bite-size form. Plus other cool stuff having to do with sound.
Jackass penguins have quite the vocal repertoire: this is from a little while ago, but still really cool. The link is a great pop-press writeup of this paper recently published in PLOS ONE. Adult birds have vocalizations for four separate situations, and chicks have two different calls. Vocal animals are constantly surprising us with how much they can say…
Soundscapes can be used to monitor biodiversity: but with some caveats, figuring out how to get beyond anthropogenic noise among them. Still, once the hiccups get figured out, this has a lot of potential to rapidly assess biodiversity.
(A story that follows the adventures of Niki Diogou, the first person that hitchhiked at the Aegean Sea to record dolphin “voices” before somebody else does it)
Since it has been suggested that the idea of leaving the oceans (and then coming down from the trees) was not a wise thing to do, I decided to return to our distant ancestor’s water element for this summer. I spent 2 weeks of late
Let’s go back
July and early August at the remnant of the ancient Sea Tethys, where also happens to be my motherland. Tethys Sea, prior to its closure into the Mediterranean Sea, it was the one of the 2 world oceans during the Earth’s early life, when geography class would had been so much simpler (history too) with Pangaea being a unique super-continent. Greece was covered by the
The super-continent and the Oceans before they broke up
Tethys and nowadays there are fossils at the Aegean islands to prove this intimacy. The Tethys Sea was named by Eduard Suess (don’t get confused, this is a different Dr. Suess ) after the Greek goddess Tethys. She was the daughter of Uranus (Sky) and Gaia (Earth), both sister and wife of Oceanus (there are no taboos if you are a god).
After praying to all the Greek sea gods that I could remember for an opportunity to collect the data I needed for my 3rd thesis chapter, the opportunity arose. Well to be accurate, didn’t really arise itself. I did push it a bit to come up…
The history of every major marine research has passed through 3 recognizable stages, those of: Survival, Enquiry and Sophistication. Otherwise known as the How, Why and Where phases. For instance the first phase is characterized by the question “how can I get funding”. The second, by the question “why do I do this research”, and the third “where in the world is the seawater warmer and clearer”.
To answer the first question I wrote this post.
To answer the second question, I wrote my previous blog.
And for the third ultimate question about the meaning of life, universe and absolutely everything, eeeh I meant the sampling site, the ultimate answer: Greece!
Concerning the second question, I will give you a summary of my field work purpose. Though, Douglas Adams has already expressed the importance of my research:
“Man had always assumed that he was more intelligent than dolphins because he had achieved so much — the wheel, New York, wars and so on — whilst all the dolphins had ever done was muck about in the water having a good time. But conversely, the dolphins had always believed that they were far more intelligent than man — for precisely the same reasons. The last ever dolphin message was misinterpreted as a surprisingly sophisticated attempt to do a double-backwards-somersault through a hoop whilst whistling the ‘Star Spangled Banner’, but in fact the message was this: So long and thanks for all the fish”.
To avoid this sort of misunderstandings, bio-acousticians have been feverishly working on decoding the dolphins’ vocalizations.
First step towards this direction is telling the voices of different species apart.
Different species of cetaceans are known to produce different types of sounds, resulting from various factors such as morphology, genetics, ecology, sociality, and culture. For example, the calls that sperm whales, humpbacks and common dolphins produce are significantly different from each other in so many ways that are clearly distinguishable by an expert ear (and eye that inspects the spectrograms). This fact makes the lives of the bio-acousticians easier because it helps us to identify different species of whales and dolphins by just listening to them.
Things though are more complicated than this. It has been shown that within the same species, some cetaceans tend to produce different sounds when they live in different areas. So the sperm whales in the Pacific produce codas (a type of vocalization indicative of sociality and communication) that are different to the ones of the Mediterranean sperm whales. Similar is the case for pods of killer whales that use different habitats and target different prey. Likewise, different geographic populations of dolphins that belong in the same species have different call characteristics. It is like speaking dialects or simply having an accent. The differences seem to be greater when the geographical distance increases.
The geographic variations of cetacean sounds are usually divided microgeographically and macrogeographically. For instance the striped dolphins in the Mediterranean Sea produce different whistles than the ones in the Atlantic. Also the striped dolphins that live in the western Med sound differently than the ones that dwell in the eastern side. Applying the same logic, the ones that inhabit the Aegean Sea will have a different “accent” than the Ionian Sea habitants. Past studies have revealed the existence of variations in the whistle acoustic structure of a striped dolphin within the different regions of the Mediterranean Sea. However the Aegean Sea is still an acoustically pristine place. The dolphins we encounter there (common, striped, bottlenose, and risso) have not been acoustically recorded (during visual encounters) and classified. YET!
Maps always help
Being a communicative creature myself, I feel the need of these dolphins in the Aegean to be understood. 🙂
And the same time I will use this information to identify different dolphin species in my N. Aegean acoustic dataset. 😉
I return to the first survival question. If you have read my previous post you will probably remember my public invitation for funding to achieve the acoustic sampling in the area of my interest. In case you are not fortunate enough to study and work on the field with the charismatic megafauna, I should enlighten you into the specific requirements of cetacean research: HIGH BUDGET! Cetacean research is particularly expensive. Money for renting a boat, gas money for the boat, money for the boat crew (a captain at least is required) and money for the acoustic instrumentation.
Because the times are hard and funding appears dimly or not at all in the horizon, I had to recruit some old skills of mine to make this happen. Hitchhiking skills (contacts also help, so get your selves out to these conferences)!
I first thumbed a ride when I was doing my undergraduate at the island of Lesvos, in Greece. With my friends we would hitchhike to the university which was slightly further from downtown. Too far to walk when you are already late for the morning lecture, too close to wait for the bus that has a very irregular schedule, too expensive for taxi while being a student, and just the right distance to be given a lift! That is when my hitchhiker’s career commenced. Now that I have reached a Ph.D level and I only possess a bicycle, my hitchhiking skills have equally improved and can be utilized for science. In this case, the thumb got replaced by emails, phone calls and meetings.
Not too far from the area that I have my hydrophone deployed and I get part of my acoustic data; there is the island of Alonissos. T
Blue: where Niki’s Dolphin Quest took place
here, it is founded the first Marine Protected Area in Greece that happens also to be the biggest in Europe. The marine area around Alonissos Island, together with 6 more islands, 22 islets and rocky outcrops is one of the few remaining habitats of the Mediterranean monk seal; the only seal specie in Med. In the past, the monk seal was very common all along the Mediterranean coasts.
Nowadays, it is on e of the world’s most endangered marine mammals and
half of its current population lives in Greece. For this reason in 1992, the National Marine Park of Alonissos, Northern Sporades was established and is dedicated to the protection of this rare species. There are laws a
Too cute to go extinct
nd regulations that limit certain anthropogenic activities that could interfere with the animals’ welfare and the population’s survival. To impose these regulations and ensure the good management of the reserve, the guards of the Marine Park patrol daily the marine protected area. And this is where my thumb comes up. The lovely people that work for the Marine Park accepted me on their daily patrols, allowed me to get on their boat and look for dolphins while they were looking for any illegal activity.
At work with the National Marine Park of Northern Sporades’ team
So I bought a big hat, I got my dipping hydrophone, swimming suit as my uniform and my Dolphin Quest began!
First day on the boat was mind blowing! Traveling with 35 miles/hour, stop every now and then to exotic locations, blue caves, a long break to rest the engine and the guards, have some drinks and swim in turquoise water coves. Marvelous sites that few have had the chance to visit.
And you will rightfully ask: did you find the dolphins?
No. But it was a good way to break the ice!
The following days were much more effective. I explained that for the purposes of my research we would have to go slower. As a hitchhiker I hesitated to reinforce my own rules to my hosts but soon our zodiac was going with 15 miles/hour and had 2 extra visual observers on board scanning the horizon for dorsal fins and splashes.
Still though, no dolphins in sight.
You see, the ocean is big. You just won’t believe how vastly, hugely, mind- bogglingly big it is. I mean, you may think it’s a long way down the road to the chemist’s, but that’s just peanuts to ocean. Searching for dolphins there is not an easy job. It is fun but not easy. It can take unpredictable amount of time until you get to see them. And I had only a few days before my flight back to USA…
Fortunately dolphins are curious creatures and if the boat is not too noisy they will swing by for a bit to check it out and hopefully play with its wake. Just like this. Eeeeeh, I wish.
A couple of days went by without any dolphin luck. And the thump comes out again for extra rides. I needed more time in the sea.
and Protection of the Monk seal who has been monitoring the monk seal population and promoting the establishment of a Marine Park for almost the last 30 years also operates in the same area. The last 2 years Mom has been running the Northern Aegean Dolphin Project . A team of volunteers and their lovely project leader, also called Niki, perform daily visual transect surveys to study the population and ecology of the dolphins in the Marine Park region. I
The MOm team and I, happy after an exciting sighting
hitched a ride with them too. Success from our very first cruise! A monk
seal sighting first thing in the morning and a big group of striped dolphins that we were able to stalk for a while. Stalk and eavesdrop on their conversations! This raised my expectations.
Stalking a groups of striped dolphins
My days passed with me jumping from the one vessel to the other exploring extensively the N. Aegean Sea. But without enough dolphin sightings. And while I was trying to compromise with the idea of having only striped dolphins’ recordings and thinking of the shift I would give to my research, disappointingly looking for any dolphins, the common dolphins appeared and gave me hope again! Fortunately, trustworthy hope. Later on the same day a mixed group of common and bottlenose dolphins was having a long dinner close to our boat. After recording them for long time, I did not resist jumping in to the water. There were far enough to not be interrupted by my presence but close enough to hear them while I had my head underwater. I was shaking with excitement. Dream comes true. Check.
My field trip ended with recordings from 3 different dolphin species, 2 monk seal encounters, countless seabirds, and 3 illegal spear-gun divers. The sea CSI in action!
The only problem was that I had to go. Too soon I think. But would there ever be a right time to leave this heavenly place?
Take me back!
And now I am back in Newport, my skin has still some tan left and all the Greek memories are still fresh with strong salty flavor. My suggestion is the following:
Do you want to implement research but you don’t have funds to do it? DON’T PANIC. There are ways and alternatives. Consider the hitchhiking method. It is an inexpensive way to do your sampling and it essentially means collaborating, meeting people, working together, sharing and having a common direction. I assure you, it’s the journey not the destination that matters.
My gratitude to the National Marine Park of Northern Sporades and MOm, the Northern Aegean Dolphin Project, for their hospitality and help. Definitely worth a visit and I am already craving my return!
I am going to start with a stereotype. The term stereotype is derived from the Greek words στερεός (stereos), meaning “firm, solid” and τύπος (typos), meaning “impression,” hence “solid impression”. The stereotype of Greeks relating the definition of every word to Greek origin. I know, stereotype in the stereotype, right? The Matryoshka Principle (MP) in effect!
Some people like to generalize a lot. Most of us criticize this behavior but overall it is hard to avoid it. Stereotypes result from peoples’ effort to understand the world by categorizing. As long as the stereotypes are not accompanied by prejudicial or discriminatory reactions I can, sarcastically, use them and self-stereotype.
Stereotype that does NOT apply
I enjoy looking into the history, the origin of things, the etymology of words. The word itself derives from the Greek word ἐτυμολογία, etymologia, from ἔτυμον, etymon, meaning “true sense” and the suffix -logia, denoting “the study of”. MP again!
I regularly (quite always) find myself asking people, especially here in the US, where they come from. Where they originally come from, you know, not where they were born but their ancestors origin. In the case that I cannot directly ask people questions, I ask myself.
Where my studies’ subjects come from, where and when cetecean and bioacoustic rese
Roman copy in marble of a Greek bronze bust of Aristotle by Lysippus, c. 330 BCE.
arch was initiated. You would (not) be surprised to discover that Cetology (from κῆτος, kētos, “whale”; and -λογία, -logia), has Greek origin, and I am not just referring to the word. It was 2364 years ago when the ancient Greek philosopher Aristotle published the History of Animals. He was only 34 when he wrote these 10 books! I don’t want to make any comparisons here, it would be inaccurate because I am also younger (!!!!), but just for reference: I struggle with just one publication.
Aristotle was the first to study and record dolphins (from Greek δελφίς (delphís), “dolphin”, related to the Greek δελφύς (delphus), “womb” and referred to as “a ‘fish’ with a womb”) and dolphin behavior. He made observations, he took notes and then he scientifically published them. He even reported his methods! Sounds like what everybody does, right? Well yes, but not 2.5 thousand years ago! It is also startling that he came up with 2 common research methods used nowadays in cetology: photo-identification and tagging. He did not have a camera or any tag equipment, but he collaborated with the fishermen and they would create artificial notches on the dorsal fins of the dolphins that were entangled alive in their fishing nets and then they were able to identify different individuals, monitor their movements and get information on their age and span of their lives.
In his writings, he correctly claimed that dolphins were mammals, he observed that they bore their live young and suckled them, breathed air and communicated by underwater sounds:
“The dolphin has a blow and lungs… it sleeps with the snout above the water and when it sleeps, snores. None produces any eggs but they give birth directly to an embryo like in the case of human and the viviparous quadrupeds. The gestation period lasts for 10 months and gives birth in the summer. The dolphins produce milk and they suckle the young which they accompany for long periods. The caring for their young is remarkable. The young grow up fast and becomes adult at the age of 10 years old. It lives for many years, even above 25 or 30… The voice of the dolphin in air is like that of the human in that they can pronounce vowels and combinations of vowels, but have difficulties with the consonants.” (Aristotle, HISTORIA ANIMALIUM, 350 BC)
It is interesting to think how much more information we have (or have not) acquired the last couple thousands of years. Especially as far as acoustics are concerned as it was not before the 1950s when new observations were made. In 1949, William E. Schevill and B. Lawrence used their hydrophones (from Greek ὕδωρ = water and φωνή = sound) into the Saguenay River of Quebec to make the first underwater recordings of the sound of cetaceans, belugas in this case, in the wild.
The use of hydrophones started at wartime too, used during WWII by
Passive Aquatic Listener (PAL): my hydrophone to eavesdrop the sperm whales and the dolphins at the Gulf of Alaska and the Greek Seas.
the submarines to detect underwater targets. Since it became declassified and available, it has been widely used today to study the underwater soundscapes and reveal a non-Silent World. While Jacques-Yves Cousteau’s title was a misnomer, Professor Huxley, in 1869, stated in his essay on the “Physical Basis of Life”:
“The wonderful noonday silence of a tropical forest, is, after all, due only to the dullness of our hearing; and could our ears catch the murmur of these tiny maelstroms, as they whirl in the innumerable myriads of living cells which constitute each tree, we should be stunned, as with the roar of a great city.”
making a point on the information we can get from soundscapes and the essentiality of the right equipment. Thus hydrophones become a favorite tool for cetologists and bioacousticians to record, understand and accurately study the charismatic marine-megafauna.
Being able to hear the whales and dolphins “voices”, opened a discussion whether these intelligent animals can actually talk, use their sounds to communicate with each other in a language context. I’m not sure which is the answer but I don’t see why we should give such an anthropocentric meaning to their vocalizations just to consider them intelligent and worthy of our protection and conservation efforts…
But the languages have further significance even within the human society. Anthropologists, linguists and psychologists have done research around the world and looked into many different languages to understand the importance of the use of certain languages and words in our minds performance. Results of these studies show that the words and language that we use represent and shape what and how we think. Thus who we are! Very cool research has shown that human languages shape the way we think about space, time, colors, and objects. Just like what cetaceans do using sound to navigate and locate food over long distances!
In fact, an interesting example of how words change the way we view the world is this one of Shakespeare who is known to have created a whole bunch of new words and phrases that have unarguably affected the way we sense our surroundings. “It’s all Greek to me” has been introduced by him, but I know that after reading this post this phrase has no use for you! In fact Greek is not really that hard, of medium difficulty. After 44 posts you will be proficient…
I will close by quoting Marcel Proust who said that the real voyage of discovery doesn’t consist in seeking new landscapes but having new eyes. And to paraphrase that, as far as my field of studies is concerned, the voyage of discovery consists in seeking soundscapes instead of landscapes, in listening to the deep sea, deep listening and understanding what we hear of the sounds in the oceans.
Every fourth week of the month I will be sharing with you, thoughts, ideas, everyday lessons and concerns, more related to bioacoustics than the Greek language 😉
