In which state of matter would a substance have thermal energy

States of Matter

How does thermal energy affect the state of a substance?

Matter consists of atoms and molecules and all substances consist of matter. Changing the state of a substance requires energy. Adding or removing thermal energy from a substance causes a change of state. Energy affects the attraction between the atoms or molecules and their rate of movement. A substance's temperature determines whether it occurs as a solid, liquid, or gas state. A substance changes from a solid to a liquid at its melting point, from a liquid to a gas at its boiling point, and from a liquid to a solid at its freezing point. A different amount of energy is needed to change the state of different substances. For example, it takes much more energy to melt a solid metal into liquid than to melt an ice cube into water.In this Virtual Lab you will examine how energy affects the state, the atomic or molecular activity, and the temperature of a substance.

Objectives:

Explore how thermal energy affects different states of matter.
Describe how the state of matter is affected by a change in temperature.
Interpret and analyze temperature versus time graphs.
Observe how the movement of atoms or molecules is affected by changes in thermal energy.

Procedure:1. Click the video button. Then click Play on the video controller. Watch the video about melting and boiling points of substances.2. Select the Water, Mercury or Iron button. The selected substance appears in its solid form inside the energy box. The energy box is able to add thermal energy to the substance or remove it from the substance at a constant rate. Inside the energy box, a sensor senses the temperature of the substance.3. In your Journal, make a prediction about what you think will happen as heat is added to the substance.4. Click the Heat button on the energy box. Observe what happens to the state of the substance, the atomic or molecular activity of the substance, and the temperature of the substance.5. Click the Graph button to see a printout of a temperature versus time graph that shows what happened when heat was added to the substance. Record your observations in your Journal.6. Click the Heat button on the energy box. Observe what happens to the state of the substance, the atomic or molecular activity of the substance, and the temperature of the substance.7. Click the Graph button to see a printout of a temperature versus time graph that shows what happened when heat was added to the substance. Record your observations in your Journal.8. Click the heat button on the energy box. Observe what happens to the state of the substance, the atomic or molecular activity of the substance, and the temperature of the substance.9. Click the Graph button to see a printout of a temperature versus time graph that shows what happened when heat was added to the substance. Answer the fourth and fifth journal questions.10. Click the Cool button on the energy box. Observe what happens to the state of the substance, the atomic or molecular activity of the substance, and the temperature of the substance.11. Click the Graph button to see a printout of a temperature versus time graph that shows what happened when heat was removed from the substance. Answer the sixth and seventh journal questions.12. Determine the approximate melting, boiling and freezing points of the substance by reading the graph. Record this data in the Table.

13. Repeat this activity with a different substance.

Thermal energy is energy that comes from a substance whose molecules and atoms are vibrating faster due to a rise in temperature.

The molecules and atoms that make up matter are moving all the time. When a substance heats up, the rise in temperature makes these particles move faster and bump into each other.

Thermal energy is the energy that comes from the heated up substance. The hotter the substance, the more its particles move, and the higher its thermal energy.

Here are some everyday examples of thermal energy that you'll be familiar with:

The warmth from the sun

A cup of hot chocolate*

Baking in an oven

The heat from a heater

*Let's think about that cup of hot chocolate...

The hot chocolate has thermal energy from its vibrating particles. When you pour some cold milk into your hot chocolate, some of this energy is transferred from the chocolate to the particles in the milk.

So what happens? Your hot chocolate cools down because it lost some of its thermal energy to the milk.
The tea has thermal energy from its vibrating particles. When you pour some cold milk into your hot tea, some of this energy is transferred from the tea to the particles in the milk.

As cold particles heat, they contain more energy and so vibrate and separate.

Some matter changes from solid to liquid to gas as its particles heat, vibrate and separate.

Boiling a kettle is an example of both thermal and kinetic energy.

Thermal energy comes from a substance whose molecules and atoms are vibrating faster due to a rise in temperature.

Heat energy is another name for thermal energy.

Kinetic energy is the energy of a moving object. As thermal energy comes from moving particles, it is a form of kinetic energy.

Ever burnt your hand from picking up something hot?
That's because the thermal energy has been transferred from the hot object to your skin. Ouch!

Boiling water on a stove is an example of thermal energy.

Thermal energy is produced when the atoms and molecules in a substance vibrate faster due to a rise in temperature.

Thermal Energy, also known as random or internal Kinetic Energy, due to the random motion of molecules in a system. Kinetic Energy is seen in three forms: vibrational, rotational, and translational. Vibrational is the energy caused by an object or molecule moving in a vibrating motion, rotational is the energy caused by rotating motion, and translational is the energy caused by the movement of one molecule to to another location.

Thermal energy is directly proportional to the temperature within a given system (recall that a system is the subject of interest while the surroundings are located outside of the systems and the two interact via energy and matter exchange.) As a result of this relationship between thermal energy and the temperature of the system, the following applies:The more molecules present, the greater the movement of molecules within a given system, the greater the temperature and the greater the thermal energy

+ molecules = +movement = + temperature = + thermal energy

As previously demonstrated, the thermal energy of a system is dependent on the temperature of a system which is dependent on the motion of the molecules of the system. As a result, the more molecules that are present, the greater the amount of movement within a given system which raises the temperature and thermal energy. Because of this, at a temperature of 0?C, the thermal energy within a given system is also zero. This means that a relatively small sample at a somewhat high temperature such as a cup of tea at its boiling temperature could have less thermal energy than a larger sample such as a pool that's at a lower temperature. If the cup of boiling tea is placed next to the freezing pool, the cup of tea will freeze first because it has less thermal energy than the pool.

To keep definitions straight, remember the following

Temperature: Temperature is the average kinetic energy within a given object and is measured by three scales of measurement (Fahrenheit, Celsius, Kelvin)
Thermal Energy: Thermal energy is defined as the total of all kinetic energies within a given system.
Heat: It is important to remember that heat is caused by flow of thermal energy due to differences in temperature (heat flows from object at higher temperature to object at lower temperature), transferred through conduction/convection/radiation. Additionally thermal energy always flows from warmer areas to cooler areas.

Matter exists in three states: solid, liquid, or gas. When a given piece of matter undergoes a state change, thermal energy is either added or removed but the temperature remains constant. When a solid is melted, for example, thermal energy is what causes the bonds within the solid to break apart.

Heat can be given off in three different processes: conduction, convection, or radiation. Conduction occurs when thermal energy is transferred through the interaction of solid particles. This process often occurs when cooking: the boiling of water in a metal pan causes the metal pan to warm as well. Convection usually takes place in gases or liquids (whereas conduction most often takes place in solids) in which the transfer of thermal energy is based on differences in heat. Using the example of the boiling pot of of water, convection occurs as the bubbles rise to the surface and, in doing so, transfer heat from the bottom to the top. Radiation is the transfer of thermal energy through space and is responsible for the sunlight that fuels the earth.

Thermal energy is a concept applicable in everyday life. For example, engines, such as those in cars or trains, do work by converting thermal energy into mechanical energy. Also, refrigerators remove thermal energy from a cool region into a warm region.

On a larger scale, recent scientific research has been aiming to convert solar energy to thermal energy in order to create head and electricity. For example,scientific research centers such as NASA explore the uses and applications of thermal energy in order to provide for more efficient energy production. In 1990, for example, NASA extensively researched and explored the potentials of a hybrid power system which made use of Thermal Energy Storage (TES) devices. This power system would convert solar energy into thermal energy which would then be used to produce electrical power and heat. However, converting solar energy to thermal energy has been found to be much easier and much more feasible when systems are not in a state of thermodynamic equilibrium. Rather, scientists have proposed, a moving object or a running fluid can allow the energy to be converted into thermal energy.

Thermal Energy and the 2nd Law of Thermodynamics The 2nd Law of Thermodynamics? states that whenever work is performed, the amount of entropy in the atmosphere is increased. Thus the flow of thermal energy is constantly increasing entropy.

References

Kerslake, Thomas W. & Ibrahim, Mounir B. "Analysis of Thermal Energy Storage Material with Change-of Phase Volumetric Effects." NASA Technical Memorandum 102457 (February 1990). 30 May 2008. <
http://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov>
Petrucci, et al. General Chemistry: Principles & Modern Applications: AIE (Hardcover). Upper Saddle River: Pearson/Prentice Hall, 2007.