Thus, if you want to talk about Total Energy in a volume of air
= average energy x unit volume, you can use = Temperature x 5/2 RT x volume.
Not exact matches
Total baseline points
= (points for
average energy content) + (points for
average saturated fatty acids) + (points for
average total sugars) + (points for
average sodium)
-- Wenger 2015 is stubborn, disinterested, old fashioned, clueless, no
energy, no game plan, nothing to prove, COMFORTABLE
= good /
average players but the worst Arsenal performances av seen in a very long time
Total
Energy Expenditure
= Target bodyweight in kilograms x -LRB-(8 - 10 or 9 - 11 +
average total weekly training hours) * 2.2)
During this time, the
average energy consumption was 136 ± 38kcal ⋅ BWkg0.75 or two times the calculated resting
energy requirement (RER
= 70kcal ⋅ BWkg0.75).
solar variability
= energy / time temperature change
= temperature / time
average temperature
= temperature No, as wrong as can be.
Average exchange of
energy between the surface, the atmosphere, and space, as percentages of incident solar radiation (1 unit
= 3.4 watts per square metre).
Nuclear
= $ 4,800 per
average kW delivered Wind with pumped hydro
energy storage
= $ 132,000 per
average kW delivered.
Maximum entropy is all molecules (on
average, not at the microscopic level) have equal total
energy TE
= PE + KE.
Energy Produced GWa is basically the
average power over the year (so 8760 GWh, which is a constant 1GW all year
= 1 GWa):
To be
energy or more properly, heat transferred, the one - way upwelling radiation from the surface absorbed by the air should be reduced by subtraction of the down - welling radiation of the air absorbed by the surface Note that by subtraction of the (about 20 W / m ² in global
average) flow surface to cosmos of both terms of GH, GH expression becomes GH
= (radiation from the surface absorbed by the air) minus (outgoing longwave radiation from the air) which has absolutely no physical sense!
The maximisation is not done under the constraint Em
= Sum (Pi.Ei) which gives the
average energy BUT under the constraint GEm
= (Sum (Pi ^ q).
The
average global
energy consumption of transportation fuels is currently several terawatts (1 terawatt
= 1012 Joule) per second.
The fundamental hypothesis is that at some time in the past and over some unspecified time -
averaging period that on a whole - planet basis radiative
energy transport attained a state of equilibrium; out - going
energy = in - coming
energy.
Due to this loss of
energy, the temperature of the remain water has dropped (1 / heat capacity
= 0.24 degK / (kJ / kg)-RRB- OR the lost
energy must be imported by: conduction (collisions transferring kinetic
energy), convection (a new group of molecules with a new
average energy), or absorbing radiation.
temperature is a function of
energy but certainly not
= energy Temperature is a measure of the
average internal kinetic
energy of matter and also a [non-linear] measure of the radiant
energy emitted by a body.
The
average global
energy consumption of transportation fuels is currently several terawatts (1 terawatt
= 1012 Joule per second).
Energy:
Energy before atmospheric entry: 1.99 x 1021 Joules
= 4.74 x 10 ^ 5 MegaTons TNT The
average interval between impacts of this size somewhere on Earth during the last 4 billion years is 2.6 x 10 ^ 6 years
The time - integral of sunspot numbers, properly reduced by earth IR radiation by using conservation of
energy, accurately (R2
= 0.88) correlates with
average global temperatures since 1895 as shown in the pdf made public 3/10/11 at http://climaterealists.com/index.php?tid
=145&linkbox
=true