1. Flushing Time or Turnover Time
1) Time required to replace the Volume of the basin V by the Volume Influx Vin R
Vout
Vin x z
Vout = Vin + R
Vout Sout = Vin Sin
Water Budget:
Salt Budget:
Knudsen’s Relations
t = V / Vin
t is obtained in seconds [ m3 / m3/s]

2. Flushing Time or Turnover Time
2) Time required to replace the fresh water volume in the estuary by the river discharge R x z
Volume of fresh water in the system (m3)
River discharge (m3/s)

3. The freshwater fraction f is given by:
3) Same as 2) but using the concept of freshwater fraction to determine Vf
Define oceanic salinity as σ and salinity at any part of the estuary as S
The freshwater fraction f is given by:
If f = 0, all salty water; if f = 1, all fresh water
average freshwater fraction
Could use salinity between head and mouth to get

4. 4) Flushing by Tides (Tidal Prism Method)
Tides bring oceanic water into the estuary during flood.
The volume of this oceanic water Vp is equal to the difference between
high hw and low hl water multiplied times the surface area A of the estuary;
Vp = (hw – hl ) A z VR Vp x hw hl
Volume of
fresh water
tidal prism
S = 0
S = σ
Assume:
- no variations of depth along the estuary  short estuary
- over a full tidal cycle, Vp is entirely mixed with VR
- entire volume of mixed water is removed from estuary during ebb
- on the next flood the process is repeated with seawater of S = σ entering the estuary
Water going in has oceanic salinity; water going out has mixed S = Š

5. Flushing by Tides (Cont.)VR Vp x hw hl
Volume of
fresh water
tidal prism
S = 0
S = σ z
The average Š of the mixed water at high tide can be obtained from salt balance:
If Vp >> VR , then Š  σ
If VR >> Vp , then Š  0
The mean fresh water fraction is:
which includes River and Tidal effects

6. Flushing by Tides (Cont.)
Taking our definition 3):
T is the tidal period, i.e., the characteristic period of tidal exchange
Flushing time by the tidal prism
It would take a lot of T scales to flush the system if V >> Vp + VR
Drawbacks:
-complete mixing from head to mouth of waters entering estuary;
this shortens tT relative to real tT
-no atmospheric forcing
-water coming in is of oceanic salinity, which is usually not the case
tT should be < t [t as derived from (1), (2) or (3)]

7. and the Flushing rate due to tidal prism FT
Flushing Rates
Flushing rate F - rate at which the total volume of the estuary is exchanged
and the Flushing rate due to tidal prism FT
FT should be > F
Reference on Flushing Time:
Sheldon, J.E. and M. Alber (2002), A comparison of residence time calculations using simple compartment models of the Altamaha River Estuary, Georgia. Estuaries, 25:

8. from particle tracking in numerical models
5) Residence time: time required for water or material elements found initially at certain locations of a basin to exit the basin.
Anabela Pacheco de Oliveira
from particle tracking in numerical models
Tejo Estuary, Portugal
Residence Times (hours)
(following particles with
a numerical model)

9. TAMPA BAY, FLORIDA

10. exit embayment boundary “transit time” entrance
From Lucas (2010)
entrance
exit
“age”
“residence time”
“transit time”
embayment
boundary
time “t”
Fig Schematic of an aquatic water body with two openings, one through which water parcels, scalar constituents, and/or particles enter and one through which they exit. The total time it takes a particle to pass through the embayment is the “transit time”, which is the sum of water or particle “age” (the time since entering) and “residence time” (the time a parcel will remain in the embayment). Average transit time may be considered equivalent to “turnover time” or “flushing time” (Bolin and Rodhe 1973; Sheldon and Alber 2006). “Age” and “residence time” are measured relative to an arbitrary time “t” and particle location within the water body (Monsen et al. 2002).

11. Willapa Bay, WA
Banas and Hickey (2005)

13. Flushing Rates in Sections (or segments)
Modify tidal prism method by dividing the estuary into segments over which
mixing takes place, rather than assume that there is complete mixing over the length of the estuary during each tidal cycle.
The length of each segment is determined by the tidal excursion:
Let, Pi = intertidal volume for segment i (or tidal prism + VR)
Vi = low water volume Vi Pi
At the landward end:
Vi = V0 -- low tide volume
Pi = P0 = VR -- over a tidal cycle; provided by the river discharge

14. Flushing Rates in Sections (or segments)
For the succeeding segments, assume that the high tide volume of the landward section is the low tide volume of the seaward section.
This implies that the tidal excursion decreases landward or that the channel gets narrower. Vn
Vn -1
Pn -1
Therefore,

15. Flushing Rates in Sections (or segments)
If the water within each segment is completely mixed at high tide, the proportion of water removed on ebb tide will be given by the ratio between intertidal volume and the high tide volume of the segment, or exchange ratio
of segment ‘n’ rn:
Modified Tidal Prism
High Tide Volume Vn
Vn -1
Pn -1
If Vn = 0 (as in a tidal flat) rn = 1
Using:
Volume of basin / (tidal prism + fresh water volume)
or High Tide Volume / Modified Tidal Prism

16. Flushing Rates in Sections (or segments)
Accumulated freshwater in each volume segment:
Finally,
Reference on Residence Time:
Sheldon, J.E. and M. Alber (2002), A comparison of residence time calculations using simple compartment models of the Altamaha River Estuary, Georgia. Estuaries, 25:
Refer to to Tomczac’s page for more information on Flushing Times .

17. Flushing time in Mururoa Atoll Lagoon
a coral island in Polynesia previously used for nuclear tests, determined from a numerical model
© 2000 M. Tomczak
bathymetry
The model takes into account tides and wind-driven water movement and includes flow over the coral reef as well as through the access channel. The figure on the left shows the circulation in the form of streamlines along which the water circulates. The zero streamline separates anti-clockwise circulation near the channel from clockwise circulation in the lagoon. Notice that most of the lagoon circulation is closed, so exchange with the ocean can only occur through turbulent diffusion across streamlines. The figure on the right shows the water residence time or flushing time in days. Most of the lagoon is flushed within less than 100 days, but there is a less well flushed region in the east where the flushing time exceeds 140 days.

18. 4) Consider these relationships a step further in terms of the
Equivalent Downstream Transport represented by Qd
f = 1
f = 0.5 f
Qd is a fictitious quantity;
it could be measured under unusual circumstances.
It is an expression in terms of the advective and diffusive effects R R
S = 0 z R x
Qd = R
Qd = 2R
Qd = R / f
Flushing time α Qd / R = 1 / f
It measures the combined effects of advection and diffusion in removing a pollutant in an estuary, compared to advection only
The greater Qd (small f ), the longer the flushing time