Thursday, August 30, 2018









Operation “Diya Kawa”; The physics beneath it
The annual joint war exercise by the three forces is the “cormorant strike”. This operation is based on the aquatic bird cormorant, commonly known as “Diya kawa”
The Diya Kawa uses many of the principles of physics from up thrust to conservation of energy. In this article I thought of uncovering the physics beneath the “Diya Kawa” which is the basis of this military operation
This bird, a predator catching fish in the ocean is mostly seen gliding over the water surface. It does not flap its wings yet remains floating. How does it do this? The answer is simple. The law of floatation used by us in fluid dynamics is used here. The up thrust exerted on the bird by the air supports its weight. Thus the bird floats much like a cork floating on water
On close observation it is noted that this intelligent bird rarely misses its prey unlike other aquatic birds. Once the prey is identified, it calculates the real depth to the fish from the water surface using laws of refraction.
Then it gains sufficient height to gain sufficient potential energy for its strike. As it comes down, the body is shaped into a streamlined position to reduce air resistance. It flies with great speed converting most of its potential energy to kinetic energy at the water surface

As it enters the water not a drop of water splashes, confirming that it enters the water at the most accurate angle to gain a maximum depth of about 150 ft. then it dives in and captures the prey

Before entering the water it traps air inside its wings and curls into a ball. The maximum up thrust exerted due to this helps it to return to the water surface easily

Isn’t it amazing how even a bird can teach us many physics principles? Mother Nature holds many surprises. Be prepared to unfold them.

By Rukmanthi Fernando

Monday, July 30, 2018

Could you please text me the competency of our group's notes of lesson

Saturday, June 30, 2018

microscopic & MACROSCOPIC


Is studying about the atom (the smallest) necessary to understand the Universe (the biggest)?
Yes. Because in the beginning, the Universe itself was atomic.

Particle physics theories were too utopian, not possible by the experimental physicists to verify through experimental evidence. Like a detective left without the cooperation of police, particle physicists were deserted. Hence they came up with the idea to check out their theories by trying to help Cosmologists (physicists involved in the field of cosmology). Now cosmology is the study of “how the (poor) Universe came into being”-cosmologists are historians of universe (and archaeologists of black holes). One of the world famous cosmologists of our times is Stephen Hawking. And these cosmologists were struck with trying to figure out what happened during the very very  first few moments of the birth of the universe. They had developed a theory called “Big Bang” (sounds stylish right) ; which explained that in the beginning the Universe was just atomic in size-a highly dense and tiny dot. So in the first few moments the Universe was like an atom, and this is where the particle physicists saw their golden opportunity, they thought; ‘if the Universe was just like an atom in the beginning, then us, the particle physicists, the official people who study about atoms and sub atomic particles, should be able to explain those first moments”.So particle physicists formed a partnership with cosmologists.

Now we are capable of explaining , how the universe grew, from after 10-35sec of it’s birth to; look at your watch. From 10-12sec onward is backed up by experimental evidence. But, how did it all begin?

Enough for today.

written by-Group 3, MSc in Physics Education 2018, University of Colombo
image courtesy-dreamstime.com