Yes a 1000w electric heater creates the same amount of heat as a 1000w hps or 1000w LED, so long as the light does not escape from the room, That heat from the light is being absorbed by everything the light bounces off of.I am talking about heat output per watt consumed here not efficiency loss of a transformer or light.
Technically this is true. The difference is a heater produces mostly infrared electromagenetic energy which is easily abosorbed by water molecules, which transfers that energy faster – hence why we fell "hotter" under infrared than we do under visible light (which is mainly reflected).
They both produce the same amount of energy yes. They don’t create the same amount of light so inversesly they don’t create the same amount of heat. Heat isn’t light, light isn’t heat. Heat can create light, light can create heat. They are both 2 different forms of energy though. A heater that’s 80% efficient will turn electrical energy into heat at an efficiency rate of 80% with the other 20% being waste (Depending on the heater type) mostly as light.
"Heat" is not a form of energy – it is a measure of potential energy transfer, or the difference in kinetic energy between two molecules.
Heat is 100% a form of energy with the SI unit being the joule.
Thanks a lot for these posts!
A device designed to create heat can’t have its waste be heat. This is only for electrical efficiency.
e=mc^2 is the theoretical proof that all mass is energy in the rest state. It’s actually complicated even at its most basic understanding and principles because it only works in a zero friction system (which doesn’t exist)
Energy and rest state just doesn't make sense though. Rest wouldn't seem to make sense as a form of energy, at all, without mass as well.
You're talking about "thermal energy". "Heat" is the transfer of that energy. Thermal energy can be transferred via touch (conductive), moving air (convective) and radiation.
So does this all come back around to why 1 watt = 1 watt?
LOL! OK, so it has been a LONG time since I studies this stuff, but this is how I remember it.
Idk mars hydro where/are making some pretty good heaters. Even catch fire sometimes
1 watt is a measure of energy, but energy can be in different forms as I've tried to explain above. An engine produces an accelerative force measured in watts (usually kilowatts), just as a thermal heater is measured in watts, just as a light fixture is measured in watts.So does this all come back around to why 1 watt = 1 watt?
But not in an efficiency sense, if light was the energy you wanted to take advantage of. Similar to why you wouldn't put diodes in a 1000w heater?
Really appreciate the time you've taken out of your day to explain. Super helpful...
) – is that you can turn energy into other forms of energy, but the form of energy we are mostly interested in is the energy that can be captured and converted into plant biomass via photosynthesis.
LOL! I do think we're on the same page!
Watt is energy over time but yeah everything else is pretty much right.1 watt is a measure of energy, but energy can be in different forms as I've tried to explain above. An engine produces an accelerative force measured in watts (usually kilowatts), just as a thermal heater is measured in watts, just as a light fixture is measured in watts.
You can think of it this way: how do you want to pass that energy from one thing (mass) to another? There are many ways! Just a few of them are:
You could simply touch the two items together and they would pass their thermal energy on to each other (conductive transfer).
You could flow air, water or another liquid between the two items so that thermal energy is transfered from Item 1 to the liquid/air molecules, and from the liquid/air molecules to Item 2 (convective transfer).
You could turn that energy into visible light, which would transfer to the other object via photons without the two items touching each other (radiated transfer).
You could turn that energy into infrared light or microwaves, which would also transfer to the other object via photons – the difference being, the transfer would be faster due to the interaction of an infrared or microwave photon with a water molecule (also radiated transfer).
You could transfer the kinetic energy of Item 1 by hitting it against Item 2 (kinetic transfer).
Basically, what everyone here is saying – because @reza92 is also saying it, it's just we disagree on the terminolgy (
What you have to remember is that NO energy is wasted. Energy converted into biomass is still potential energy – it can be burned in an exothermic reaction to produce thermal energy (mostly in the form of radiated energy). Or it can be composted, which also creates thermal energy. These processes are (in a way) the reverse of photosynthesis, as they release thermal energy and carbon dioxide instead of absorbing them.
But I think really we have reached the limits of my understandings and I wouldn't want to say much more on the subject as it can be quite exhaustive and I'm sure there are some real scientists here who can explain much more than I can.
But what if you thought of time as the distance light has to travel? Such as light speed and distance from the sun?
Man! Thanks.1 watt is a measure of energy, but energy can be in different forms as I've tried to explain above. An engine produces an accelerative force measured in watts (usually kilowatts), just as a thermal heater is measured in watts, just as a light fixture is measured in watts.
You can think of it this way: how do you want to pass that energy from one thing (mass) to another? There are many ways! Just a few of them are:
You could simply touch the two items together and they would pass their thermal energy on to each other (conductive transfer).
You could flow air, water or another liquid between the two items so that thermal energy is transfered from Item 1 to the liquid/air molecules, and from the liquid/air molecules to Item 2 (convective transfer).
You could turn that energy into visible light, which would transfer to the other object via photons without the two items touching each other (radiated transfer).
You could turn that energy into infrared light or microwaves, which would also transfer to the other object via photons – the difference being, the transfer would be faster due to the interaction of an infrared or microwave photon with a water molecule (also radiated transfer).
You could transfer the kinetic energy of Item 1 by hitting it against Item 2 (kinetic transfer).
Basically, what everyone here is saying – because @reza92 is also saying it, it's just we disagree on the terminolgy (
What you have to remember is that NO energy is wasted. Energy converted into biomass is still potential energy – it can be burned in an exothermic reaction to produce thermal energy (mostly in the form of radiated energy). Or it can be composted, which also creates thermal energy. These processes are (in a way) the reverse of photosynthesis, as they release thermal energy and carbon dioxide instead of absorbing them.
But I think really we have reached the limits of my understandings and I wouldn't want to say much more on the subject as it can be quite exhaustive and I'm sure there are some real scientists here who can explain much more than I can.
Yeah I quit uni to get away from calculus man. But google would have an approximate value of the energy of the sun in (probably) giga joules. This doesn’t account for dissipation over distance, the effect the atmosphere has or the types of energy the sun expels (mostly radiation (mostly IR which is why we feel it’s warmth) and light. As has been mentioned physics is hella complicated and if your interested in learning more a cannabis forum probably isn’t the right place.