A hot object exposed to low temperature in a vacuum doesn't lose heat?

Question

I heard somewhere that if the human body were exposed to outer space where the temperature is extremely low, the human won't actually feel cold because in a vacuum, the heat energy doesn't have another physical object to travel too.

So my question is, i thought heat is just a form of radiation, and that radiation can travel through a vacuum. So then, why doesn't a body lose heat in a vacuum the same way our sun emits a whole bunch of UV radiation? In which case, the body should be losing energy and feeling cold.

Answer 1

There are many ways to carry heat. The first is conduction, which is about the "vibration" of atoms on one material passing to another by simple physical contact. (Example: you touch something hot and get hurt). The second is convection: hot molecules simply move from one place to another (Example, water starts to boil in the bottom of a pan, but moves on the top because is lighter). The third is radiation and is precisely what you say: a warm body emits electromagnetic radiation. At "normal" temperatures (an oven, a human body), it's Infrared radiation, but it can be of higher frequency at higher temperatures, according to Planck's blackbody radiation law.

Notice, though, that the power emitted by radiation only is proportional to the fourth power of temperature. So the effect is very relevant in sun, but negligible for a human body. It should be around 500 W/m$^2$, which OK, is not small, but probably the most heat is transferred by conduction when the human is in air.

This is how garments work: they create a small layer of warm air around your skin, avoiding contact with constantly renewed cold air.

Answer 2

The body will lose heat when it's in vacuum in the same way the sum emits thermal radiation. In fact all matter with temperature above absolute zero emits radiation and human body is no exception.The power emitted by radiation per unit surface is given by the Stefan-Boltzmann law

$$ j*= \epsilon \sigma T^4$$ where, $j*$ that the total energy radiated per unit surface area per unit time, $\sigma$ is the Stefan-Boltzman constant, $\epsilon$ is the emissivity of the body and $T$ is the absolute temperatue.

Also, "heat" is not radiation. Heat or thermal energy is the energy which matter posseses because of the random motion of its molecules. And temperature of a macroscopic body is the measure of the average kinetic energy of its molecules.