Temperature Control Fabric

In summary: The article discusses a fabric that can let more heat out in hot weather or flip over to keep more heat in the cold. The fabric has 4 layers: 2 outside layers of polyethylene and 2 thin layers of carbon black and copper. The outside layer when cold is clear and 24 µm thick, while the outside layer when hot is clear and 12 µm thick. The copper and carbon layers are in contact, but distinct layers. The copper layer's action is discussed as a reflector.
  • #1
BillTre
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This article in Science mag news is about a fabric that can,
  • let more heat (via IR) out in hot weather, or
  • flipped over, keep more heat in the cold
Here is the Science article (not free).

The fabric also let's gasses and humidity pass through because it has nano-pores.
It has 4 layers: 2 outside layers of polyethylene and 2 thin layers of carbon black and copper.

• outside when cold
PE layer 1: IR clear, 24 µm thick
carbon black: absorbs and emits IR
copper: weakly absorbs and emits IR, reflecting?
PE layer 2: IR clear, 12 µm thick
• out side when hot

The copper and carbon layers are in contact, but distinct layers.

What I don't understand:
If the copper is reflecting the IR re-emitted by the carbon layer (as news article says), why is not the IR being absorbed by the carbon blocked to the same extent?
Does the closeness of the carbon layer to the copper matter?
Are there wavelength differences in what's absorbed and emitted by the carbon, that could interact with copper differently?
 
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  • #2
BillTre said:
If the copper is reflecting the IR re-emitted by the carbon layer (as news article says), why is not the IR being absorbed by the carbon blocked to the same extent?
Is the copper in contact, or does a gap exist?
 
  • #3
Bystander said:
Is the copper in contact, or does a gap exist?
There is not a gap.
The copper is sputter coated onto a layer of carbon that was dried down onto one of the PE layers.
 
  • #4
What does direct contact imply for/about heat transfer/transport? Radiation? Or conduction?
 
  • #5
Bystander said:
What does direct contact imply for/about heat transfer/transport? Radiation? Or conduction?

Contact between the copper and carbon layers implies heat conduction (vibrating molecules causing neighboring molecules to vibrate more) could occur, however, the article focuses almost exclusively on IR (InfraRed) radiation, how it penetrates the materials and is absorbed and emitted.
The copper layer's action is discussed as a reflector.

I can see a few ways contact between the carbon and black layers could have an effect:
  • The optical interface between the carbon and copper layers gets different optical properties from the juxtaposition of the two layers due to their different optical properties (such as optical density). The layers together may act as a one-way mirror.
  • There is something like fluorescent transfer going on at the interface between the carbon and the copper. The carbon absorbs an IR photon and then readmits it (like a fluorescent molecule). Presumably the emitted photo would be lower energy and thus longer wavelength. The carbon emitter of the IR photon might instead undergo an energy transfer to the copper. This would not involve most of the material in the carbon layer (9 µm thick) from interacting in this way because most of the atoms would be too far away.
  • The geometry of the closeness of the carbon emitter of IR photons to the copper layer night result in more photons interacting with the copper at angles more likely to result in a reflection instead of refraction (have not fully thought this one through).
 
  • #6
... and, the temperature dependence at "ambient" conditions? T4 = what?
 
  • #7
Has anyone else done the maths on the thermal conductivity for this material?
I came up with 11,000 watts per Kelvin.

After that, my head started exploding.

Bystander said:
... and, the temperature dependence at "ambient" conditions? T^4 = what?

This is what I came up with:

Code:
radiant            net W/m^2   conditions   
too cold            119.0       50 °F amb
just right           51.0       72 °F amb
too hot              47.0      100 °F amb
external body temp              90 °F
 

1. What is temperature control fabric?

Temperature control fabric is a type of material that is designed to regulate the temperature of the body by trapping or releasing heat. This is achieved through the use of specialized fibers or coatings that can absorb, wick away, or reflect heat depending on the needs of the wearer.

2. How does temperature control fabric work?

Temperature control fabric works by using specific properties of the fibers or coatings to either absorb, wick away, or reflect heat. For example, moisture-wicking fabrics use hydrophobic fibers to pull sweat away from the skin and evaporate it, which helps to cool the body. On the other hand, insulating fabrics use hollow fibers or coatings to trap heat and keep the body warm.

3. What are the benefits of temperature control fabric?

The main benefit of temperature control fabric is its ability to regulate the body's temperature and keep the wearer comfortable. This can be especially useful in extreme weather conditions, during physical activity, or for individuals with specific temperature sensitivities. Additionally, temperature control fabric can also help to reduce moisture and odor buildup, making it a popular choice for athletic and outdoor clothing.

4. What types of clothing use temperature control fabric?

Temperature control fabric can be found in a variety of clothing items, including base layers, sportswear, outerwear, and even everyday clothing such as socks and underwear. It is also commonly used in bedding and mattresses to help regulate body temperature during sleep.

5. Are there any potential drawbacks to using temperature control fabric?

While temperature control fabric has many benefits, there are a few potential drawbacks to consider. Some types of temperature control fabric may be more expensive than traditional materials, and certain coatings or chemicals used in the fabric may cause skin irritation for some individuals. Additionally, the effectiveness of temperature control fabric may vary depending on the specific climate and activity level of the wearer.

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