Uniform and Accelerated Motion in X-axis

                 Motion is all around us. There is no time in a day where we don't see motion. Motion, in science, is defined as change in position per unit time. For example, when you wake up in the morning, move from your bed (we arbitrarily assign it as your initial position) to the comfort room (final position), then you changed your position (or your location) and for obvious reason, it took you some time to move from your bed to the comfort room. What is not motion then? Whenever your at rest, that is, when your are not changing your location, then you are not in motion. There two ways we can describe motion, constant and accelerated.

Constant Motion

      When you move in a straight line with the same speed, then your are in constant motion.

Accelerated Motion

      There are three ways to achieve accelerated motion:

1. you change your speed (slowing down or speeding up);

2. you change your direction (when you do a sudden U-turn or when you are in Uniform Circular Motion);

3. you change both your speed and direction (basically, most things we see daily)

To better understand the two description of motion, watch the video below and try to answer the embedded questions.

Defining Temperature

What is temperature?

Temperature can be define in many ways, some of which are the following:

1. The degree of hotness or coldness of a body or environment.
2. A measure of the warmth or coldness of an object or substance with reference to some standard value.
3. A measure of the average kinetic energy of the particles in a sample of matter, expressed in terms of units or degrees designated on a standard scale.
4. A measure of the ability of a substance, or more generally of any physical system, to transfer heat energy to another physical system.

     Definition #1 is a very subjective definition. When do we say that an object is cold or hot? How hot is a hot object or how cold is cold object? It subjective in a sense that different people may judge the temperature of the same object differently. To take this subjectivity in context, have you ever met a person from a hotter region in the country, take for instance, Pangasinan? Notice how they comment how cold it is in Baguio City around March when most people from Baguio City feel like the city is on fire? No blames either of them for having different opinion. Their sense and perception are simply very subjective.

  

Definition #2 is very similar to definition #1, but we can extend this definition to the use of measuring instruments such as thermometer. The unit of temperature when using a thermometer is degree centigrade, one can infer from the word centigrade that this particular instrument has 100 graduation. The reference point in this instrument the freezing point of water assigned as 0 degree centigrade and the boiling point of water set at 100 degree Centigrade. 

         Aside from the degree centigrade, there are other ways to report temperature such as degree Fahrenheit and Kelvin, the absolute temperature scale. Study the image above and tell us what you think about the relationship among the temperature scales.

  

       Definition#3 defines temperature at the microscopic level. This definition suggests that we can infer based from the temperature of an objective how fast the molecules that compose it are. The term average is justified by the fact that it virtually is impossible to measure the kinetic energy of individual molecules so we resort to measuring the average kinetic energy discounting the fact that some molecules may be more energetic than the rest of system. 

     Observe the box above. The movement of the molecules (represented by the dot) creates what we call as temperature. Specifically, the collision of molecules with each other and with the sides of the box results to release of energy that we sense as temperature. What do you think will happen to temperature as the molecules get faster?

     Definition #4 is an extension of definition #3. Have you ever tried touching a hot pot? How did you feel? Exactly! That is because of the so-called heat transfer. Well, for technical reasons, instead of saying heat transfer, we'll call it thermal energy transfer (heat is a mechanism of energy transfer and not a form of energy in itself). What actually happens when you touch a hot pot? Basically, some of its energy will transfer to you hand. When that happens, the molecules in your hand will have more kinetic energy (move faster, collide more often) and the friction the molecules create is what you perceive as the burning sensation. How about the cold sensation you feel when you touch an ice? Well, it's because of your hand is losing some of its energy to the ice cube. Watch the video below and tell us what you think about the mechanisms of heat transfer.

Welcome to the World of Physics

            Physics is often described as the study of matter and energy. It is concerned with how matter and energy relate to each other, and how they affect each other over time and through space. Physicists ask the fundamental questions: How did the universe begin? How and of what is it made? How does it change? What rules govern its behavior? (https://www.nevis.columbia.edu/what-is-physics.html).
          This blog is dedicated to communicating physics to the general public. You are free to share interesting information related to physics by sharing the link of your source.

Branches of Physics
1. Classical Mechanics- focuses on the study of description of motion of macroscopic object at speed much lower than the speed of light. Also studies how forces affect the motion of objects.


2. Electrodynamics and Statistical Mechanics - studies the effect of changes in temperature, pressure and volume on physical macroscopic systems and how energy is transferred through heat.


3. Electromagnetism - studies the interaction between electricity and magnetism.


4. Optics - studies the behavior of light.


5. Relativity - studies particles moving at very high velocities, and of the space-time.

6. Quantum Mechanics - is the branch of physics treating atomic and subatomic systems and their interaction with radiation. It is based on the observation that all forms of energy are released in discrete units or bundles called "quanta".