Shehbaj singh said:A typical example is a iron chair gets cold in winters and wooden chain not.
Okay I am taking about rate of flow of heat. And it's in time limit like we put chairs from indoor to outside for five minutes. That's what I talking about why metal gets cold faster with only contact with air.alw34 said:not so.
Can you refine your question or provide the source you found this?
PS: If you put a whole bunch of different things at room temperature in a cold refrigerator, do you think any will be colder than any other after sufficient time has passed? Some may get colder faster or slower due to conduction, convection [or radiation] but all will end up at the ambient temperature of the refrigerator, right?
I know about general conduction but I am talking of process of transfer of heat from metal to air. How it happens at molecular level or it's just not conduction and is radiation.alw34 said:Hi,
Conduction electrons...loosely bound electrons...same reason as some materials are insulators [wood] others are conductors [iron] of electricity...
those with loosely bound electrons can diffuse more quickly carrying either heat energy of electrical energy or both from atom to atom...
A few views:
Electrical conductivity of non-metals is determined by the susceptibility of electrons to excitation from the valence band to conduction band...https://en.wikipedia.org/wiki/Valence_and_conduction_bands
https://en.wikipedia.org/wiki/Heat_transfer#Conduction
[has a link to more details]
http://farside.ph.utexas.edu/teaching/sm1/lectures/node86.html
The heat transfer from <something> to air is effected through convection and radiation. However, the internal transfer of heat through a metal chair is largely due to conduction, which is much faster. Therefore, a metal chair is going to be cold all the way through faster than a wooden chair (since wood is a very bad heat conductor).Shehbaj singh said:I know about general conduction but I am talking of process of transfer of heat from metal to air. How it happens at molecular level or it's just not conduction and is radiation.
Everything in universe radiates heat except those with temperature of 0kelvin.alw34 said:When you are thinking about heat exchange due to radiation, you are thinking about significant temperature differences. In other words, any substance has to be pretty hot to lose much heat energy via radiation...an incandescent light bulb for example is pretty hot, 2,000 or more Kelvin I think. Since it's encased in a vacuum, virtually all the heat loss is radiation...and something like 97 or 98% of the power is dissipated that way. The largely infrared radiation heats the bulb of course, so it loses heat via conduction as air passes.
See the chart here and the explanation beneath:
https://en.wikipedia.org/wiki/Thermal_radiation
Shehbaj singh said:Everything in universe radiates heat except those with temperature of 0kelvin.
Conduction of heat is the transfer of thermal energy between two objects or substances that are in direct contact with each other, typically from a hotter object to a colder one.
In metals, heat is transferred through conduction as the molecules of the metal vibrate and pass on their energy to neighboring molecules. This energy is then transferred to the air molecules through collisions, causing them to vibrate and increase in temperature.
The rate of heat transfer from metal to air is affected by several factors such as the temperature difference between the two substances, the surface area of the metal, the type of metal, and the thickness of the metal. The presence of any insulating materials can also affect the rate of heat transfer.
Metals conduct heat better than other materials because they have free electrons that are able to move and transfer thermal energy. These free electrons also explain why metals are good conductors of electricity.
While it is not possible to completely stop the conduction of heat from metal to air, it can be reduced by using insulating materials such as foam or fiberglass. These materials can trap air pockets, which act as barriers to slow down the transfer of heat.