Air Temperature given Air-Sea Temperature Difference Solution

STEP 0: Pre-Calculation Summary
Formula Used
Air Temperature = Air-Sea Temperature Difference+Water Temperature
Ta = ΔT+Ts
This formula uses 3 Variables
Variables Used
Air Temperature - (Measured in Kelvin) - Air Temperature is a measure of how hot or cold the air is.
Air-Sea Temperature Difference - (Measured in Kelvin) - Air-Sea Temperature Difference of the region under consideration, evaporation is greater with lower humidity in the air, increasing the temperature difference.
Water Temperature - (Measured in Kelvin) - Water Temperature is a physical property expressing how hot or cold water is.
STEP 1: Convert Input(s) to Base Unit
Air-Sea Temperature Difference: 55 Kelvin --> 55 Kelvin No Conversion Required
Water Temperature: 248 Kelvin --> 248 Kelvin No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Ta = ΔT+Ts --> 55+248
Evaluating ... ...
Ta = 303
STEP 3: Convert Result to Output's Unit
303 Kelvin --> No Conversion Required
FINAL ANSWER
303 Kelvin <-- Air Temperature
(Calculation completed in 00.004 seconds)

Credits

Created by Mithila Muthamma PA
Coorg Institute of Technology (CIT), Coorg
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24 Estimating Marine and Coastal Winds Calculators

Wind Speed at Height above Surface in form of near Surface Wind Profile
Go Wind Speed = (Friction Velocity/Von Kármán Constant)*(ln(Height z above Surface/Roughness Height of Surface)-Universal Similarity Function*(Height z above Surface/Parameter with Dimensions of Length))
Coefficient of Drag for Winds Influenced by Stability Effects given Von Karman Constant
Go Coefficient of Drag = (Von Kármán Constant/(ln(Height z above Surface/Roughness Height of Surface)-Universal Similarity Function*(Height z above Surface/Parameter with Dimensions of Length)))^2
Gradient of Atmospheric Pressure Orthogonal to Isobars given Gradient Wind Speed
Go Gradient of Atmospheric Pressure = (Gradient Wind Speed-(Gradient Wind Speed^2/(Coriolis Frequency*Radius of Curvature of Isobars)))/(1/(Density of Air*Coriolis Frequency))
Friction Velocity given Wind Speed at Height above Surface
Go Friction Velocity = Von Kármán Constant*(Wind Speed/(ln(Height z above Surface/Roughness Height of Surface)))
Wind Speed at Height z above Surface
Go Wind Speed = (Friction Velocity/Von Kármán Constant)*ln(Height z above Surface/Roughness Height of Surface)
Wind Stress in Parametric Form
Go Wind Stress = Coefficient of Drag*(Density of Air/Water Density)*Wind Speed^2
Friction Velocity given Wind Stress
Go Friction Velocity = sqrt(Wind Stress/(Density of Air/Water Density))
Gradient of Atmospheric Pressure Orthogonal to Isobars
Go Gradient of Atmospheric Pressure = Geostrophic Wind Speed/(1/(Density of Air*Coriolis Frequency))
Geostrophic Wind Speed
Go Geostrophic Wind Speed = (1/(Density of Air*Coriolis Frequency))*Gradient of Atmospheric Pressure
Friction Velocity given Height of Boundary Layer in Non-Equatorial Regions
Go Friction Velocity = (Height of Boundary Layer*Coriolis Frequency)/Dimensionless Constant
Height of Boundary layer in Non-Equatorial Regions
Go Height of Boundary Layer = Dimensionless Constant*(Friction Velocity/Coriolis Frequency)
Wind Speed given Coefficient of Drag at 10-m Reference Level
Go Wind Speed = sqrt(Wind Stress/Coefficient of Drag to 10m Reference Level)
Wind Stress given Friction Velocity
Go Wind Stress = (Density of Air/Water Density)*Friction Velocity^2
Wind Speed at Height z above Surface given Standard Reference Wind Speed
Go Wind Speed = Wind Speed at Height of 10 m/(10/Height z above Surface)^(1/7)
Wind Speed at Standard 10-m Reference Level
Go Wind Speed at Height of 10 m = Wind Speed*(10/Height z above Surface)^(1/7)
Height z above Surface given Standard Reference Wind Speed
Go Height z above Surface = 10/(Wind Speed at Height of 10 m/Wind Speed)^7
Rate of Momentum Transfer at Standard Reference Height for Winds
Go Wind Stress = Coefficient of Drag to 10m Reference Level*Wind Speed^2
Coefficient of Drag at 10m Reference Level given Wind Stress
Go Coefficient of Drag to 10m Reference Level = Wind Stress/Wind Speed^2
Air-Sea Temperature Difference
Go Air-Sea Temperature Difference = (Air Temperature-Water Temperature)
Water Temperature given Air-Sea Temperature Difference
Go Water Temperature = Air Temperature-Air-Sea Temperature Difference
Air Temperature given Air-Sea Temperature Difference
Go Air Temperature = Air-Sea Temperature Difference+Water Temperature
Coefficient of Drag for Winds Influenced by Stability Effects
Go Coefficient of Drag = (Friction Velocity/Wind Speed)^2
Friction Velocity of Wind in Neutral Stratification as Function of Geostrophic Wind Speed
Go Friction Velocity = 0.0275*Geostrophic Wind Speed
Geostrophic Wind Speed given Friction Velocity in Neutral Stratification
Go Geostrophic Wind Speed = Friction Velocity/0.0275

Air Temperature given Air-Sea Temperature Difference Formula

Air Temperature = Air-Sea Temperature Difference+Water Temperature
Ta = ΔT+Ts

What is Geostrophic Wind?

The Geostrophic wind is a theoretical wind speed that results from a balance between the Coriolis force and the pressure-gradient force, concepts explored in greater detail in later readings.

What is 10m Wind?

Surface wind is the wind blowing near the Earth's surface. The wind 10m chart displays the modelled average wind vector 10 m above the ground for every grid point of the model (ca. every 80 km). Generally, the actually observed wind velocity at 10 m above ground is a little bit lower than the modelled one.

How to Calculate Air Temperature given Air-Sea Temperature Difference?

Air Temperature given Air-Sea Temperature Difference calculator uses Air Temperature = Air-Sea Temperature Difference+Water Temperature to calculate the Air Temperature, The Air Temperature given Air-Sea Temperature Difference formula is defined as a measure of how hot or cold the air is. It is the most commonly measured weather parameter. Air Temperature is denoted by Ta symbol.

How to calculate Air Temperature given Air-Sea Temperature Difference using this online calculator? To use this online calculator for Air Temperature given Air-Sea Temperature Difference, enter Air-Sea Temperature Difference (ΔT) & Water Temperature (Ts) and hit the calculate button. Here is how the Air Temperature given Air-Sea Temperature Difference calculation can be explained with given input values -> 303 = 55+248.

FAQ

What is Air Temperature given Air-Sea Temperature Difference?
The Air Temperature given Air-Sea Temperature Difference formula is defined as a measure of how hot or cold the air is. It is the most commonly measured weather parameter and is represented as Ta = ΔT+Ts or Air Temperature = Air-Sea Temperature Difference+Water Temperature. Air-Sea Temperature Difference of the region under consideration, evaporation is greater with lower humidity in the air, increasing the temperature difference & Water Temperature is a physical property expressing how hot or cold water is.
How to calculate Air Temperature given Air-Sea Temperature Difference?
The Air Temperature given Air-Sea Temperature Difference formula is defined as a measure of how hot or cold the air is. It is the most commonly measured weather parameter is calculated using Air Temperature = Air-Sea Temperature Difference+Water Temperature. To calculate Air Temperature given Air-Sea Temperature Difference, you need Air-Sea Temperature Difference (ΔT) & Water Temperature (Ts). With our tool, you need to enter the respective value for Air-Sea Temperature Difference & Water Temperature and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
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