Dolphin Encounter – Touching and Mindblowing at the Same Time

By Anupum Pant

Like crows and humans, dolphins have an impressive brain-to-body ratio. Based on an assumption, intelligence of a creature is in proportion to the size of its brain, scientific research suggests that dolphins are the most smartest creatures on the earth, after human beings. H2G2 suggests the same!

  • Besides that, there are a couple of other evidences that say dolphins are incredibly intelligent creatures. For instance, the part of a brain where all the emotional and higher thinking takes place, is considerably larger among dolphins – in MRI scans. Also, dolphins show several human-like skills –
  • They can identify themselves in a mirror-reflection, displaying highly developed, abstract thinking and self-awareness – Like Elephants and Great apes. Although self-awareness is a highly debated topic, dolphins are definitely better than so many other animals out there.
  • To some extent, dolphins can understand numbers.
  • They are often found to be engaged in complex play – Like, they can make and play with water bubble rings (Video – It is mesmerizing to watch them play with the rings) They are also seen riding the waves. Just like humans surf on the waves.

  • It isn’t just that. Dolphins also live in social groups and have different names (Distinct whistles) they use to call out each other.

[More of Dolphin-intelligence feats here]

But, why am I talking Dolphins today?

Well, they are of course extremely interesting creatures. But there was a video I stumbled upon on the front page of Reddit today, which really touched me. Moreover, it made me appreciate the creature’s intelligence. This is what happens in the video:

A diver, Jack is seen swimming around with a couple of Manta rays in the Garden Eel cove, Hawaii. Out of some where, a Bottlenose Dolphin appears. It appears to be in trouble and then the diver notices a fishing line entangled on one of its fins. He signals the dolphin to come closer. It comes, and most amazingly it stays nearby and cooperates with the diver to let him cut the hook and the fishing line.

Dolphin comes near a human, turns upside down, as if saying “Hey human, I have a problem. Can you help?”

Just two things. Kudos to the human for helping it out. The problem is solved.  And cheers to the dolphin which leaves us mindblown, wondering about how intelligent animals can be! At times, even smarter than some people I’ve met. 

Michio Kaku’s High-School Science Fair Project was Astounding

By Anupum Pant

 michiokakuDr. Michio Kaku without a doubt is one of the finest Physicist of the present times. Besides that he is also a very popular person. If you watch TV, you must have definitely seen this man some where. He has made several appearances on TV channels like  BBC, the Discovery Channel, the History Channel, and the Science Channel. Also, he has written books and hosts a radio show.
He has made science popular. But if you live in a cave, this person in the picture is the man I’m talking about.

What made him the man he is today, was his great love for science since childhood. By the time he was in high-school, he had started doing incredible things. His high-school science fair project story, pretty much sums up the remarkable things he had started doing back then.

The science fair project

During his high school, when he was working on anti-matter photography, he had an idea to create his own anti-matter beam. He then went to his mom and asked her this:

Mom, can I have permission to build a 2.3 million volt atom smasher betatronic accelerator in my garage?

The shocked and proud mom obviously agreed to the proposal. This is what he had to procure to convert his idea into a reality:

  • 400 pounds of transformer steel
  • 22 miles! of copper wire

With the help of his parents, he wound the 22 mile long copper wire around a football field that was able to generate a magnetic field 20,000 times greater than the Earth’s magnetic field. It could produce collisions powerful enough to create antimatter. After a few troubles with the power, there, he had his own  2.3 eV atom smasher (cyclic particle accelerator).

This was an atom smasher built in his backyard garage – a mini version of the $ 10 Billion Large Hadron Collider.

Changed his life

This science fair put him in the right track. A nuclear scientist, Edward Teller, noticed it in the National Science Fair and spread the word to the scientific community. And soon, he got a full ride to the Harvard University.

via FromQuarkstoQuasars

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Consuming Fat Can Have Exceptional Health Benefits – Whale Fat

By Anupum Pant

Blubber Crash-course

Blubber is thick layer of fat that is present under the skin of many sea dwelling animals which helps them withstand the cold sea temperatures. It is found in animals like dolphins, whales, seals etc. Since fur fails to insulate once the animal is inside water, blubber is what helps them stay warm in there. Depending on the size of the animal, the thickness of this fat layer can vary from 2 to 12 inches. Look at a minute-long Sick Science experiment (Video) that demonstrates this particular function of a layer of fat (shortening in this case).

The other important use of blubber for these animals is that it can act as a buffer stock of energy. During the times when sea animals aren’t able to find food, they burn up the fat for energy. It helps them last for a long time without food. Also, blubber helps them float better in water.

Eskimos eat this

Inuit, a group of people living in parts of Arctic, Canada, Greenland and USA, commonly known as Eskimos, love to include blubber in their food because it is a great source of  omega-3 fatty acids and vitamin D. They consume raw, dried and boiled blubber with meat regularly, either with soya sauce or sea oil.

The positive health benefits of blubber, as Wikipedia puts it, can be observed in Greenland, where people consume it regularly. As a result, they are less likely to die due to Heart diseases. It says, not a single person died in that region in the 1970s due to cardiovascular diseases. Someone needs to study the same for the present decade.

It cites the following a source that no longer exists. However, another source clarifies it (source):

In the 1970s there was not a single death due to cardiovascular disease in the hunting district of Uummannaq with about 3,000 inhabitants. The average 70-year-old Inuit with a traditional diet of whale and seal has arteries as elastic as those of a 20-year-old Danish resident.

That is a pretty incredible health benefit, given hardening of arteries due to build-up of fat has become such big killer in developed countries.

Is Blubber really that good today?

Today, whales and other sea animals that are a primary source of blubber for Eskimos, come across huge amounts of toxic chemicals in the sea – mostly through food. They consume these industrial wastes, and with time carcinogens build up in their bodies. These carcinogens ultimately enter the traditional food items of Eskimos through blubber.

So, heart disease might not be a widespread phenomena in Greenland, but in a few years, cancer could be. But, that is just the poor human logical brain talking.

According to current studies, blubber based diet has is indeed been credited to the Inuit health and longevity.

Also read –

  1. Sharks Are Not So Bad After All
  2. Ambergris – Whale Vomit Can Make You Rich

Wasp Uses Venom to Turn Cockroaches into Zombies

By Anupum Pant

Background

The Emerald Cockroach Wasp A.K.A Jewel wasp – a metallic blue/green colored, 2 cm long wasp – is something that will blow your mind by the way it reproduces. More specifically, the Emerald Cockroach Wasp uses venom to hack into cockroach brains, turns them into zombies and lays eggs inside them. With time, this live yet immobile cockroach body is hollowed out by the larvae of the wasp and the young ones come out eventually.

How does it reproduce? (details)

At a time when the female Emerald Cockroach Wasp is ready to lay eggs, it competes with the other females to find a host to lay their eggs. When a wasp finds a good host – only this one kind of cockroach – the weird reproductive activity begins.

  1. The wasp attacks the cockroach and injects the first dose of venom into its central nervous system that is aimed at making the front legs of the cockroach paralyzed. Killing the cockroach with its venom is simple for the wasp, but keeping it alive is what matters here. So, the right amount of venom at the perfect place is injected.
  2. Now, when the cockroach can’t move its front legs, the wasp attacks again at a perfectly still moment to inject the second dose of venom. It carefully sticks the stingers into the brain of the victim in a way that the perfect amount of venom reaches the exact place in the brain of the cockroach which controls escape reflex. In short, it performs a micro neurosurgery and turns the cockroach into a zombie – Now it gets completely under control.
  3. Next, the wasp chews off half the antennae from the cockroach’s head and drinks its blood to gain energy.
  4. Then it grabs the cockroach by its antennae and hauls it into a burrow, lays the eggs on the abdomen of the cockroach, goes out and obstructs the entryway of the burrow using small pebbles to ensure that the host doesn’t escape. The calm zombie-cockroach is left in there to take care of the larvae for several days.
  5. The larvae hatches, drills a hole into the body of the cockroach, eats it from the inside, hollows is and comes out after a few weeks as a grown up wasp. The cockroach is dead.

Did you know? There is funny sticker selling on the internet – Jewel wasp vs. Zombie cockroach sticker. (Just FYI. I have no affiliation with it)

[Video]

Einstein Couldn’t Figure How the Drinking Bird Worked

By Anupum Pant

Background

DrinkingBirdThe Drinking Bird is a toy which almost every one of us has heard of. If you haven’t, may be this picture of it rings a bell. Otherwise, it is a funny looking bird-head made of felt, mounted atop a glass or plastic straw, with a little bulb at its lowest point. The whole contraption is suspended at two points, which allows it to swing smoothly like a pendulum – drinking water at regular intervals, from a glass, for ever.

The amusing thing about this little toy is that, once it starts, it keeps swinging and “drinking” for ever. Upon giving it a cursory look, it seems to be a perfect perpetual machine – a contraption that can run indefinitely without an external source of energy. In reality, it isn’t a perpetual motion machine. There is a complex physical and chemical activity going on inside the toy, which keeps the simple heat engine running forever without a battery – Something so complex to deduct, that even one of the greatest Physicist ever, Albert Einstein himself couldn’t figure out the correct mechanism that keeps it running.

Don’t worry, it isn’t as difficult to understand the mechanism.

How does it work?

Assuming you have properly understood the parts of the toy, you will notice that the little bulb at the bottom of it has a colored liquid in it. This colored liquid is a chemical called Methylene chloride – A chemical that dissolves caffeine and can be used to decaffeinate coffee, teas and colas. The special property of this chemical which makes the toy work is its extremely low boiling point. It has a high vapor pressure at room temperature.

At room temperature the vapor pressure in the tube and head is high. The fluid remains in the bulb and the bird is upright due to the weight of the fluid.

The first thing you do is, you make its head dip in water. That way, the head made of felt absorbs water. The water cools due to evaporation (like our sweat cools our body), drops the temperature of the head and the bird comes up.

While swinging in the upright position, as the head cools further, the vapor pressure at the head decreases, while the pressure at the bulb becomes relatively higher. This causes the chemical to rise up the tube and it changes the center of gravity (CG). Due to the change in CG the bird tips its head back into the water.

Absorbs water and the process starts once again. It keeps on going till the bird can no longer reach the low water level. You, then have to fill up the reservoir.

Source of energy?

There is a lot going on in the toy so it isn’t really easy to point a single source of energy. However, it is pretty clear that the bird isn’t a perpetual motion machine. Anyway, watch the insightful video now. The simple toy is indeed a beautiful thing to marvel about. [Video]

The Domino Effect Physics Can be Pretty Incredible

By Anupum Pant

 falling dominoesDomino effect is a fairly well-known mechanical effect in which a single falling domino (A tile of the tile-based game called Dominoes) causes a chain reaction. The resulting chain reaction depends on the size of arrangement – number of arranged dominoes.

Usually  hundred to hundred thousand equal sized dominoes are carefully arranged to form a sequence. Then, the first domino is flicked to start a huge chain reaction. There have been several world records with kinds of falling-domino-patterns based on this effect. But there is one thing about the domino effect that isn’t popularly known.

The 2X rule

When these falling domino records are made, they are usually done with equal sized dominoes. Suppose, continuously increasing sized dominoes are used in sequence, the size of falling dominoes can go really huge, pretty fast.

The limit: When the size of second domino is from 1.5 to 2 times the size ( says a physics study) of the first domino, it can fall with ease. But that is the limit. If the second domino is any larger than 2 times the size of the previous domino, it won’t fall down – stopping the chain reaction in between. So, 1.5 times the size of the previous domino is a pretty safe increment to use, if you really want your chain reaction to complete.

So, Morris in the video below, uses the first domino which is 5mm high and 1mm thick (I’m wondering how he manages to balance it on the 1mm side). The domino placed next to it is, 1.5 times thicker, longer and wider. So, if it is made of the same material, the second one would weigh more than 3.3 times the weight of the first one. Now do the math.

He uses 13 dominoes with increasing sizes. The last one is about a meter tall and weighs about 50 kg. Remember, the first one probably weighed no more than a few grams.

He flicks the 5 mm domino and within a second or two, due to the chain reaction, the largest one that weighs 50 kg, falls down with a huge bang. Had he used a few more dominoes and would have made the count to 29, the last one would have been as tall as the Empire State building. Imagine a domino of that size falling with such a measly initial energy expended to make the 5 mm sized domino fall.

The amplification of energy is about 2 Billion times! Thanks to the stored Gravitational energy.

Physics is marvelous. Isn’t it? [Video]

Bee Gees – Stayin Alive – Saving Lives Since 1977

By Anupum Pant

Not all of us are taught CPR at schools, but there is a simple way you can ensure that you do it right. The BeeGees disco hit track Stayin Alive which almost none of us has been able to un-hear for the last 30 years, has actually helped people to stay alive.

Why?
According to a research study at University of Illinois, British Heart foundation and American Heart Association, 100 – 110 is the optimum number of compression required to jump start a heart in the case of a cardiac arrest. Since the track contains about 103 to 104 beats per minute throughout, it is an “utterly perfect track” for performing or training to perform a CPR. In fact, thousands of medical students all over the world have been trained to perform CPR using the same track.

Procedure: In case a person around you collapses suddenly due to a cardiac arrest, the first thing you must do, is call the emergency services. Next, start pushing hard on the chest of the collapsed person using locked fingers (with knuckles up) to the beat of Bee Gees Stayin Alive.

[British Video 1] [American Video 2]

In addition to Stayin Alive, even if their names don’t sound like they’d save lives, other popular songs with a similar beat rate are –

  • AC/DC – Highway to Hell
  • Queen – Another One Bites the Dust
  • Madonna – La Isla Bonita
  • Lily Allen – LDN
  • Abba – Dancing Queen

Definitely a good thing to remember.

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The Simple Difference Between Venom and Poison

By Anupum Pant

Venom and Poison are both toxic substances. Still, some animals are called venomous and others are poisonous. The only difference between being called poisonous or venomous is in the way these animals deliver the harmful substance.

Venom: When animals like snakes use their sharp fangs to bite into the flesh and let the toxic substance move into the body of their prey,  through the punctured skin, they are called venomous animals. To deliver venom an animal has to use tools like fangs or stingers.

Poison: Poison is something that can get inhaled, ingested or seeped into the skin directly. For example, if you accidentally touch a brightly colored poison dart frog, you will transfer the toxins it secretes from its skin, to your own skin. And then the poison will seep into your blood stream.

The same substance can be Venom + Poison: Some substances can be both venom and poison depending on how an animal delivers it. eg: Tetrodotoxin – an extremely toxic substance – is found in both puffer fish and in a blue ringed octopus. It is poisonous in a puffer fish and venomous in a blue ringed octopus.

The same animal can be both venomous and poisonous: One example for this is the pelagic sea snake – a snake related to cobra. It has a poisonous flesh and its bite can also deliver a venom.

Non-poisonous Venom: There are some venoms which can be ingested without experiencing any ill effects because it was not designed to survive the acids present in the stomach. These types of venoms won’t get a chance to get absorbed in the blood stream. Before they try that, they might get digested. This is the reason a snake doesn’t die when it swallows its own venom. That doesn’t mean you can try drinking snake venom.

So you can happily go around telling everybody that most snakes aren’t poisonous, because most snakes use fangs to deliver venom, not poison. [Video]

 

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This Animal Makes its Own Food Like Plants do

By Anupum Pant

We have seen a Game of Thrones themed slug in the past. But today, we look at something that will completely blow your mind off. After giving this little article a read, you’ll be confused and wouldn’t know what to call this slug – a plant, or an animal.

Background

A just born Elysia chlorotica – a kind of sea slug – feeds on algae for the first few days of its life. When it eats algae, what it really does is, stores the chloroplast in its gut. By this way, it able to manufacture its own food later on. Just after those few days from birth, it can completely give up eating, and can survive on just solar energy, by using the stolen chloroplast – just like a plant does.

How is it a true hybrid?

Of course there are animals that eat plants, store chloroplast and use the solar energy in some way. But there is something in E. Chlorotica that sets it apart from animals like that.

E. Chlorotica is a true hybrid animal. Scientists have found that when it eats the algae, by some unknown process, it able to steal the genes from algae and can incorporate it in its own DNA. This gives it an ability to maintain the chloroplast cells by supplying them with the right proteins, and perform real photosynthesis in its own body. Without the gene theft, it wouldn’t have been possible for E. Chlorotica to live off solar energy for the whole life-time (around 1 year).

Photosynthesis in Humans?

The animal has baffled scientists. Before this, they hadn’t known that it was possible for DNA to jump from one kind of a specie to a completely different specie and impart a life-altering function.

No doubt, this opens up a whole lot of possibilities, but scientists say, photosynthesis still doesn’t seem to be possible among humans because unlike E. Chlorotica, our guts are designed to digest and completely destroy chloroplast.

[Source]

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No One Knows Where This Water Goes

By Anupum Pant

Background

In the Judge Magney State Park, Minnesota, as the Brule river makes it way towards Lake Superior, something very unusual happens at the Devil’s Kettle Falls – The river splits into two streams, one of which moves away like a normal stream and joins the Lake Superior. But the other stream falls down several meters into a big dark hole. No one till date, has been able to find where the water falling into this hole ends up.

Although no one has been able to prove it, the current theory which holds to some extent, says that the water flows through underground passageways and makes its way to the Lake Superior.

What all has been tried?

  • Several gallons of dye to track the water stream has been poured into the hole. The dye once poured in has been never seen again.  Besides that, so many kinds of objects have been thrown in there. Nothing ever comes out. Moreover, with every tourist, geologist or scientist throwing something in there, it has still not got clogged yet. So, it is the best place to get free ping-pong balls and other objects.
  • Some say that a car fell into the hole once and was never seen again. But those are probably just stories because the place isn’t big enough to accommodate a car.
  • Throwing in GPS tracking devices also don’t work because the stream takes them underground where they can’t be tracked by the satellites.
  • People can’t be dropped in because it is 240 meters deep and no one knows how far it keeps going. There is a lot of uncertainty to risk a human life.
  • Water-proof cameras can’t be tied to ropes and sent down because the impacts break them. Moreover, the video stream would be impossible to receive if it goes too far and several rock layers come in between.

More Mystery

But there is more. Unlike other parts of the world, where underground rivers are formed cutting through soft-rock deposits (e.g: limestone) underground, this part of Minnesota has no soft-rocks underground. So, even large underground caves can’t be used to explain the Devil’s Kettle.

Scientists have even dismissed a theory that says probably lava tubes have been formed inside. Geologists say that the kind of rock that is there inside, can’t form lava tubes.

What do you think is down there? Do you have any ideas to help figure it out?

 

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Lucky Worms Survived The Space Shuttle Columbia Disaster

By Anupum Pant

February 1, 2003 was a sad day for science. Space shuttle Columbia, during re-entry, due to a broken piece of insulation, got completely disintegrated. With the shuttle, died all the 7 astronauts who were aboard. [Remembering Columbia]

Scientists had lost hope on all of the 80 experiments that were on board. Only several days later while sifting through the wreckage they found something interesting – at least not all was lost. A live group of lucky worms (roundworms) was successfully salvaged from the wreckage. Yes, odd, but true.

Why were there worms in the shuttle?

The space shuttle Columbia was a research flight and contained 80 experiments on board. The group of live worms, sealed in a metal container which was ensconced in a safe locker, was a part of one of those 80 experiments.

Although the particular gene experiment that had to be conducted with fresh-worms-from-space was lost because they had entered Earth several days back, the worms still proved useful for other science experiments.

From these worms scientists learned a great deal about what micro-gravity could do to animals – Like weakening of muscles and manifestation of diabetic symptoms. When in space, these are the similar things that happen to humans as well.

How did they not get killed?

Firstly, they were in a strong metal container that was nicely protected by a second layer – a reinforced locker meant to really protect things.

Since the shuttle was coming in at a speed more than 2 times the speed of sound, the locker must have hit the ground pretty hard, right? No, till the time it reached the surface, the drag slowed it down. So, the worms basically experienced just a harder-than-normal landing.

What are they doing now?

Well, as round worms don’t really live longer than 2 years usually, they must have died long back. But their descendants have been stored safely in a genetic center – lucky worms indeed. Some of these descendants were lucky enough to be sent to space during 2011 in the shuttle Endeavour.

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Yes, Light Can Push Physical Objects

By Anupum Pant

Tim is a 71-year-old eccentric who has been collecting interesting toys for 50 years now. Today he has a collection of around 250,000 absurd toys in suitcases, labeled and stacked in a room from the floor to the ceiling. He shows them off in a Youtube channel regularly. I almost never miss any of his toys. Usually most the toys he displays amaze you, but do not blow off your mind. The last one did.

Before this, I had not known that light can push or move a physical object. So, I decided to investigate a bit.

The Extraordinary Toy

In his last video, he showed off a beautiful glass bulb mounted on a wooden stand, that he says has been made by some German company. The bulb has a very good vacuüm (not complete vacuüm, just enough to not create unnecessary drag for the vanes) and encloses a fan-like structure that starts rotating when a bright light is switched on near it. Some people call it the light mill – like the wind mill moves with the wind, this one moves when photons hit it. If give enough time, the mill can accelerate to really good speeds (at thousands of rounds per minute). Watch the video below. [Video]

Theories on how a radiometer really works

The device, a special kind of radiometer, was invented around 140 years back in the year 1873, by Victorian experimenter Sir William Crookes to measure the radiant energy of heat or light. It has four vanes mounted at the edge of four stiff wires to make a fan, each of which has a black side and a silvered side. All of this is enclosed in a bulb which is evacuated enough to not cause drag due to air. In complete vacuüm the vanes move in an opposite direction, but that experiment is really difficult to recreate!

  1. When light is turned on, the fan moves in a way that makes it look as if light is pushing away the black colored side. The theory of photons pushing the black side was accepted initially. But soon a problem was seen with the theory. If light is absorbed at the blackened side and reflected at the silvered side, the fan should be moving in the opposite direction.
  2. Then came in the other explanation which explained that the heated black side due to absorbed radiation rarefied the air near the black side and hence caused the gas to rush in and push that side. The greater the heat, the more this back side would get pushed and it would spin faster. Later even this theory was proved to be wrong. But, Britannica, till date decides to go with this explanation – to some extent this theory goes in the right direction, you will see why…
  3. One more theory claimed that the heat evaporated the impurities on the black side, whose force made it spin.

How the radiometer really works?

The correct explanation was given by a  prominent Anglo-Irish innovator, Osbourne Reynolds. He explained it by mentioning a porous plate, where the air inside the holes would flow from the colder sides to the warmer side (obviously) and make the vanes spin in the opposite direction. He called it “Thermal Transpiration” – makes sense and is easy to understand. But the vanes here are not porous. So…

He said that “Thermal Transpiration” in the vanes takes place at the edge of the vanes and not the faces. Think of edges as small pores, he said.

Due to a temperature gradient formed, the air starts moving along the surface from colder to the warmer side through the edges. The net pressure difference around the vane is created which pushes it in a direction that is away from warmer air and towards the colder air – makes sense for the apparatus.

This is the reason, if it is cooled, it moves in the opposite direction.

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A Mathematical Guide to Optimize Pizza Buying

By Anupum Pant

The logical engineer in me has always paid a lot of attention to how well my money is being put to use, or if something I bought was well worth it. So, before buying anything, I usually love to add in a basic mathematical calculation that would ensure the best logical use of my money. I used to do the same when I was studying engineering and had come up with a handful of tricks, which enabled me to eat the best food, in best quantities at the lowest prices.

Optimized Pizza Buying

Till date, I had relied on calculations for individual joints to buy the pizza that gave me the best value for money (irrespective of what my stomach could fit). In other words, I had never used statistical methods, as I always went to only 2 or 3 pizza places and never felt a need to do it statistically.

So yesterday, while skimming through blogs on NPR, I came across a post by Quoctrun Bui, where he had calculated the best valued pizza size using statistical methods. 

The final findings of his study based on 74,476 prices from 3,678 pizza places were condensed into a graph which depicted data as follows (here is the link to the article for an interactive version of the graph).

pizza guide

Conclusion

The above graph plots 74,476 data points to find the pizza size that gives you the best value for money. The y-axis plots price-per-square-inch – the lesser price-per-square-inch you pay, the better deal you score.

This basically means that buying the largest pizza gets the most value out of your money. As the size increases the value for money increases or the price you pay per-square-inch of pizza decreases. – Statistically speaking.

Adding value

I felt a need to add value to the study by finding how well ‘buying a large pizza’ to get the best value works in India.  So, I selected a popular joint Dominos (where I go all the time) for the test. I dug out their menu (probably an old one) to see if buying the large pizza always works in India. Here is a record of price you pay per square inch at Dominos for various sizes and categories of pizzas. (Click the image to see a better version)

pizza buying guide dominos
I did not pay much attention. Please point if there is a mistake.

Conclusion (Dominos India)

  • No, always buying the large pizza clearly is not the best option at Dominos in India.
  • A small pizza is the best option (economically) if you are buying from the categories: Simply veg, Veg I or Simply Non-veg.
  • A large pizza is the best option (economically) if you are buying from the categories: Veg II, Non-Veg I or Non-Veg II
  • Never go for the small Non-veg II pizza. It is the worst choice you can make.
  • Never ever get a medium pizza from any category!

I’d love to see someone doing the same thing for other popular pizza joints. Do get back to me if you have done it. I’ll add it to the article as an update.

 

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The Blue Blood of a Horseshoe crab is Precious

By Anupum Pant

Not-so-good Bunnies

Several years back large colonies of cute little rabbits were being maintained by pharmaceutical companies. These rabbits were used to find contamination in solutions that would be used to treat human beings. If the rabbits fell sick due to fever after being injected, the solutions were labeled as contaminated and were not injected into humans. If the rabbit had no fever after 2 days, the solution was deemed clean and could be used on humans.

However, pharma companies hated this process – not because they felt bad about harming cute bunnies, but the process was expensive and took about 2 days to give results.

A new discovery

A few years later, a scientist named Fred Bang was studying the circulatory system of a horseshoe crab – half a billion year old specie. He accidentally discovered some amazing properties of the horseshoe crab’s blood when one of his crabs died because its whole blood turned into a semi-solid mass.

He found that when the crab’s blue colored blood came in contact with a certain kind of bacteria, it got clotted into a semi-solid mass and completely trapped the bacteria.

And ultimately with the help of a scientist, Jack Levin, he developed a  process that could be used to detect bacteria contaminated solutions (contaminated with endotoxin). This process proved to be a boon to us humans.

The replaced test

Today the old bunny test has been completely replaced. Pharmaceutical companies love the new test because it takes about just 45 minutes to complete and costs much lesser.

Every year thousands of live Horseshoe crabs are made to bleed blue to take advantage of their blood’s unique properties. About 30% of these crabs die. The miracle blue liquid can detect contamination in solutions that are extremely tiny (even if the contamination is as tiny as some parts-per-trillion). 

The several liters blood extracted from these live crabs is used to save human lives by protecting them from contaminated solutions.

Every single person who has ever had an injection, has been protected because the blood of a horseshoe crab ensured that you got clean injections. Had there been no horseshoe crabs, we’d have been killing bunnies. Salute to the crab.

 

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A Chat With Jaan Altosaar From Useful Science

By Anupum Pant

Today is a special day on Awesci because I’m publishing the first ever interview that has been done especially for the website – A talk with one of the creators of Useful Science, Jaan Altosaar. I hope I keep bringing more of these interesting talks in the future.

Useful Science – Background

Useful Science is a super-hit science website run by a team of grad students from some of the world’s top universities like MIT, McGill, UCSB, Oxford, and Johns Hopkins. The website does exactly what its name says – Publishes practically useful science research summaries (every of them is cited) that can be understood by anyone in 5 seconds or less – a marvelous concept, I must say.

Make sure you finish reading our talk because in the end Jaan shares a great piece of information, without which and article on AweSci wouldn’t be labeled as complete.

A: When did you start Useful Science? Could you share with us what goes behind the scenes at Useful Science?

J: We launched on January 15th, 2014. We use Trello to coordinate our team and review process, and many of us use RSS feed readers to stay on top of the latest research (e.g. we subscribe to research journals, EurekAlerts, and blog feeds). The backend (designed and run by Cameron Spencer at lab43.com) is built on Drupal. We use Google Analytics for tracking stats, Hootsuite for managing our social media profiles, and Mailchimp for our email list (subscribe here!).

A: How did all of you guys meet?

J: Most of us are connected through McGill (our alma mater) and more specifically, we lived together in Douglas Hall in first year! I reached out to the rest of the contributors after meeting them at graduate school open houses.

A: Where else on the web do the team members write?

J: A few of us have personal websites; they’re listed on Useful Science’s about page.

A: What advice will you give to the thousands of Indians who apply to graduate school every year?

J: I found the process time-consuming but worth it, and tried to organize my thoughts into a resource in the form of a blog post (focused on graduate school).

A: Why did you feel the need to start Useful Science?

J: We felt there was a gap in science communication. The question was: what would a website look like if every sentence on it was cited?

A: Judging from your backgrounds, you people just love science too much and do it for the joy of it, but do you ever wish to make money out of useful science?

 J: We’d wish to make only enough to make the website sustainable. We are non-profit and any funds we receive through donations go directly to upkeep of the website (e.g. server costs and new features).

A: What revenue sources do you have in mind?

J: We’re hoping to integrate with Shirts.io so that anyone can order any of the one sentence summaries on a t-shirt.

A: I’ve read about you on Lifehacker, where else on the web, have you been featured?

J: We’ve been lucky to have been featured in BoingBoing, the McGill Science Undergraduate Research Journal’s blog, BetaKit, McGill’s Office for Science and Society blog, ITworld, the McGill Reporter, and Computerworld.

A: Before you go, could you share with us an interesting piece of science trivia for the day from any of your favorite areas?

J: One of my favorite areas of research focuses on the importance of mindset. Specifically, believing that intelligence is malleable and not fixed (i.e. it can be improved with practice) has been shown to improve grades. It’s great motivation for overcoming failure and pursuing deliberate practice.

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