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SIO 210 Physical properties of seawater (3 lectures)
First lecture:
1. Accuracy and precision; other definitions
2. Depth and Pressure
3. Temperature
4. Heat
5. Potential temperature
Talley SIO 210 (2015)
Second and third lectures:
1. Salinity
2. Density
3. Freezing point, sea ice
4. Potential and neutral density, Brunt-Vaisala freq.
5. Sound speed
6. Tracers: Oxygen, nutrients, transient tracers
SIO 210 Properties of Seawater
Reading for this and the next 2 lectures:
DPO Chapter 3.1 to 3.6
DPO Chapter 4.2 to 4.6
Extra: DPO Java Ocean Atlas examples for Chapter 3
Stewart chapter 6, and just look at Gill Appendix 3
Study questions: see website
Talley SIO 210 (2015)
1. Definitions for measurementsAccuracy: reproducibility relative to a chosen standard
Precision: repeatability of an observation by a given instrument or observing system
A very precise measurement could be wildly inaccurate.
Talley SIO 210 (2015)
Mean: average value
Median: center of distribution (equal number of values above and below)
Mode: most common value
Ocean range: 0-6000 meters (mean 3734 m, median 4093 m, mode 4400 m since file had depths by 100 m intervals)
2. Depth and pressure
Talley SIO 210 (2015) FIGURE 2.2
Pressure (mostly) results from overlying mass of water (and air); total mass depends on the water density and height
Ocean range: 0-6000 dbar (get to this unit below) (note that 1 dbar is equivalent to about 1 m)
Pressure is a force per unit area
Newton’s law: F = ma where F and a are 3-D vector force and acceleration, and m is mass.
Units of force: mass x length / (time)2
cgs: 1 dyne = 1 gm cm / sec 2
mks: 1 Newton = 1 kg m / sec 2
2. Depth and Pressure
Talley SIO 210 (2015)
2. Depth and PressureUnits of pressure: dyne/cm2 and N/m2
1 Pascal = 1 N/m2
1 bar = 106 dynes/cm2 = 105 N/m2
approximately the atmospheric pressure at sea level
1 atmosphere = 1000 millibar = 1 bar
1 decibar = 0.1 bar
Decibar or “dbar” is the most common pressure unit used in oceanography because it is so close to 1 m, given the density of seawater: approximately the pressure for 1 meter of seawater. (Don’t use the abbreviation “db” because dB is used for decibels – sound intensity.)
Talley SIO 210 (2015)
2. Relation of pressure to depth (1)“Hydrostatic balance”
From Newton’s law, use the force balance in the vertical direction
vertical acceleration = (vertical forces)/mass
vertical acceleration = vertical pressure gradient force + gravity
Pressure gradient (difference) force (“pgf”) is upward due to higher pressure below and lower pressure above
pgf = - (pressure/depth) = -(p/z)
(since z increases upward and p increases downward)
Gravitational force per unit volume is downward = - g
where is the density of seawater, ~1025 kg/m3
Talley SIO 210 (2015)
2. Relation of pressure to depth (2)We now assume vertical acceleration is approximately zero, so the vertical pressure gradient (pressure difference force) almost exactly balances the downward gravitational force. This is called “hydrostatic balance”.
0 = vertical pgf + gravitational force
0 = - (p/z) - g
We can then solve for the change in pressure for a given change in depth.
For:
z = 1 meter, density ~1025 kg/m3, and g = 9.8 m/s2, we get
p = - g z = (1025 kg/m3)(9.8 m/s2)(1 m) =
10045 kg/(m s2) = 0.10045 bar = 1.0045 dbar
Talley SIO 210 (2015)
2. Pressure vs. depth for actual ocean profile
Z
DPO Figure 3.2Talley SIO 210 (2015)
2. Pressure measurements
Reading the reversing thermometers
Old: pair of mercury reversing thermometers
Modern (post 1960s) - quartz transducers that produce digital output
DPO Chapter S16Talley SIO 210 (2015)
2. Pressure measurement accuracy and precision
Accuracy Precision
~5 dbar ?
3 dbar 0.5 dbar
(0.1% of range) (0.01% of range)
Talley SIO 210 (2015)
Old-fashioned reversing thermometers
Quartz pressure sensor on modern (1970s to present) instrument
3. Temperature, heat and potential temperature• Temperature is measure of energy at molecular level• Temperature units: Kelvin and Celsius
• TK Kelvin is absolute temperature, with 0 K at the point of zero entropy (no motion of molecules)
• TC Celsius 0°C at melting point at standard atmosphere (and no salt, etc)
• TK = TC + 273.16°
• Ocean temperature range: freezing point to about 30° or 31°C
• (Freezing point is < 0°C because of salt content)Talley SIO 210 (2015)
3. Surface temperature (°C)
DPO Figure 4.1: Winter data from Levitus and Boyer (1994)Talley SIO 210 (2015)
Note total range and general distribution of temperature
Pacific potential temperature section (“potential” defined on later slides)
Talley SIO 210 (2015) DPO Fig. 4.12aNote total range and general distribution of temperature
3. Temperature
• Temperature is defined in statistical mechanics in terms of heat energy
• T = temperature, Q is heat, S is entropy
• Heat content is zero at absolute zero temperature (Kelvin scale)
• dQ = TdS
Talley SIO 210 (2015)
Heat is not 0 at 0°C!!!!
4. HeatEnergy: 1 Joule = 1 kg m2 / sec2
Heat is energy, so units are Joules = J
Q = total amount of heatdQ/dT = Cp where Cp is heat capacity
q= heat per unit volume = Q/V, units are J/m3
dq/dT = cp where cp is specific heat = Cp/mass
For seawater, typical values (with a wide range) are:cp ~3850 J/kg °C and ~ 1025 kg/m3
Talley SIO 210 (2015)
4. Heat flux
Heat change per unit time1 Watt = 1 W = 1 J/sec
Flux of heat from air into ocean or vice versa:Heat/(unit time x unit area)
Units are Joules/(sec m2) = (J/sec)/m2 = W/m2
Talley SIO 210 (2015)
4. What sets temperature? Surface heat flux (W/m2) into ocean
Yellow: heating. Blue: coolingMap shows the annual mean (total for all seasons)
Talley SIO 210 (2015) DPO Figure S5.8 (in supplement to Chapter 5)
5. Potential temperatureWater (including seawater) is (slightly) compressibleIf we compress a volume of water adiabatically (no exchange of heat or salt), then its temperature increases. (“adiabatic compression”)We are interested in tracking water parcels from the sea surface down into the ocean. We are not interested in the adiabatic compression effect on temperature. We prefer to track something that is conserved following the parcel.“Potential temperature” Is defined as the temperature a parcel of water has if moved adiabatically (without heat exchanges or mixing) to the sea surface.
Potential temperature is always lower than measured temperature except at the sea surface (where they are the same by definition)
Talley SIO 210 (2015)
5. Potential temperature expressions
€
(S,T, p) = T + Γ(S,T, p')dp'p
pref∫
The change in temperature with pressure that is due solely to pressure is called the “adiabatic lapse rate”:
Γ(S,T,p) = T/ p (> 0)
In the atmosphere, the adiabatic lapse rate is equivalent to 6.5°C per 1000 m altitude.In the ocean, the adiabatic lapse rate is about 0.1°C per 1000 m depth (1000 dbar pressure).
Potential temperature is defined as
Again: potential temperature is always lower than measured temperature except at the sea surface (where they are the same by definition) (pref = 0 dbar, p is > 0 dbar)Talley SIO 210 (2015)
5. Pressure effect on temperature:Mariana Trench (the most extreme example because of its
depth)
DPO Figure 4.9
X
Note the measured temperature has a minimum around 4000 dbar and increases below that.
Potential temperature is almost exactly uniform below 5000 m: the water column is “adiabatic”.(This is because all of the water in this trench spilled into it over a sill that was at about 5000 m depth.)
Talley SIO 210 (2015)
5. Temperature and potential temperature
difference in S. Atlantic (25°S)
X
Note that this water column has a temperature and potential temperature minimum at about 1000 m (must be balanced by a salinity feature).
Talley SIO 210 (2015)
5. Temperature and potential temperature
difference in S. Atlantic (25°S)
X
Note that this water column has a temperature and potential temperature minimum at about 1000 m (must be balanced by a salinity feature).
Talley SIO 210 (2015)
T
5. Atlantic temperature and potential temperature sections for contrast
Temperature Potential temperature
Talley SIO 210 (2015)
Summary: definitions
Talley SIO 210 (2015)
AccuracyPrecisionMean MedianMode
PressureNewton’s LawHydrostatic balance
DyneNewtonDecibar
TemperatureKelvinCelsius
Heat and heat fluxJouleWatt
Potential temperatureAdiabatic lapse rate