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Friday, October 11, 2024

Thermosteric Sealevel Change Revisited - 2

Fig. 1 "It depends"

Revisiting the thermal dynamics of fresh water generally begins with remembering that the maximum density temperature is critical.

The graphic in the first post helps us grasp the reality involved with whether fresh water will expand or contract when we add or remove heat from a mass of it, because that depends on its temperature at the instance we add or remove that 'heat'.

For example, if the temperature of the mass is below 4 deg C (e.g. 3 deg C) when we add heat the mass will lose volume until the temperature reaches 4 deg C but will increase in volume if we continue to add heat beyond that maximum density temperature point.

Sea water is the same in principle in the sense that whether it will expand or shrink in volume if we add or remove heat depends in substantial part on its temperature at the instant we add or remove that heat.

But since seawater also has salinity as an additional factor to be considered, the graphic at Fig. 1 indicates that requirement by using 'X' as the maximum density variable (instead of a fixed temperature).

The TEOS-10 library can be used to our advantage when we want to determine the 'X' factor of seawater (see "IV. Important TEOS-10 Functions" here, noticing the all-important gsw_alpha function).

Fig. 2

TEOS-10 can be used to determine whether a mass of seawater will expand or contract in volume if heat is added to or removed from that mass of seawater.

To develop visual aids for delving deeper into the dynamics of this subject, I designed an experiment as follows: 1) determine which WOD zones have PSMSL tide gauge stations in them; 2) load the WOD temperature, salinity, depth, latitude, longitude, length, width, depth, and volume of those WOD zones; 3) load the PSMSL tide gauge records of sea levels dating from 1950 through 2023; 4) calculate the average tide gauge sea level for each year; 5) calculate the thermal expansion and contraction of the sea water at up to 33 depth levels based on the WOD data.

The exercise is to compare a zone's thermal dynamics with it's tide gauge recorded sea levels.

Fig.3

But more than that, the zones involved are restricted to Atlantic Ocean zones and tide gauge stations, Pacific Ocean zones and tide gauge stations, and Indian Ocean zones and tide gauge stations (see Fig. 2, Fig. 3, and Fig. 4 graphs).

What these graphs show is that there is no correlation between steric and thermosteric dynamics.

If we were talking about humans we could say they each have a mind of their own.

But since we are talking about abiotic rather that biotic entities, we can say that different dynamics determine the shape of the graphs.

Fig. 4

The tide gauge station sea level records are not based on temperature, salinity, depth, latitude, or longitude, they are based only on the surface location over a span of years.

On the other hand, the thermal expansion and contraction is based on temperature, temperature change, salinity, depth, latitude, longitude, and the mass of the depth slice of the ocean upon which the TEOS-10 calculations are applied.

The formula and some of the TEOS-10 considerations were pointed out in the previous post of this series (Thermosteric Sealevel Change Revisited), however, let me point out and emphasize that today's post is not about the same subject matter or the same WOD zones.

The WOD zone data involved in today's posts are only zones with coastlines within them, because tide gauge stations are located only on shorelines, thus the zones are located in very different geographical areas.

Thus the in situ measurements are less in number than in the previous post which also included zones without coastlines in them (e.g. zones far offshore).

The graph lines that show Tidegauge SLC are very different from the graph lines below them which show Thermal SLC (thermal expansion and contraction) even though they are in the same zone or zones.

Not to worry, because that difference is to be expected if we consider how different the two dynamics (steric, thermosteric) are.

Today's appendix (Appendix HTML) contains the list of zones per ocean used in Fig. 2, Fig. 3, and Fig. 4, and also the HTML data further emphasizes the differences between the two SLC types in terms of the magnitude of steric SLC compared to thermal SLC.

Thermal expansion is a minor part of sea level rise and fall, but that is not well understood , so, "worse than previously thought" is how glacial melt is described all too often because every once in awhile it becomes clear that more Cryosphere ice is melting than previously thought (Widespread seawater intrusions beneath the grounded ice of Thwaites Glacier, West Antarctica, dated May 20, 2024; "Glaciers suffer largest mass loss in 50 years" - State of Global Water Resources 2023, dated 07 October 2024).

The previous post in this series is here.



Appendix HTML

This is an appendix to: Thermosteric Sealevel Change Revisited - 2


WOD Zones

ocean: Atlantic, zones used in graph:
1000,1500,1501,3001,3201,3301,5003,5004,5005,5103,
5204,5207,5305,5306,5307,5406,5407,7201,7207,7208,
7209,7300,7301,7302,7303,7306,7307,7308,7309,7400,
7405,7406,7407,7500,7505,7506,7509

ocean: Pacific, zones used in graph:
1011,1012,1013,1015,1016,1017,1110,1111,1112,1114,
1116,1211,1212,1214,1311,1312,1313,1314,1413,1414,
1515,1517,1600,1601,1616,1617,3011,3013,3014,3015,
3016,3017,3112,3113,3114,3115,3116,3117,3216,3317,
3416,3417,5007,5008,5009,5014,5015,5017,5107,5114,
5117,5208,5210,5213,5214,5215,5217,5417,7000,7005,
7007,7008,7015,7101,7102,7106,7107,7108,7109,7110,
7115,7116,7210,7211,7215,7216,7217,7311,7312,7412,
7512,7513,7515,7516,7517

ocean: Indian, zones used in graph:
1007,1009,1010,1103,1104,1105,1107,1108,1109,1206,
1207,1208,1209,1210,3003,3004,3005,3007,3010,3104,
3106,3109,3203,3205,3211,3214,3215,3302,3311,3312,3
313,3314,3315,3407,3414


Atlantic
Special Calculation of Zones
With Tidegauge Stations
year slc tsSlc
1950 0.00 0.00
1951 -3.18 0.00
1952 21.75 0.00
1953 5.78 0.00
1954 -5.41 0.00
1955 12.87 0.00
1956 -4.78 0.00
1957 6.33 0.00
1958 16.28 0.00
1959 -8.86 0.08
1960 12.07 0.02
1961 35.15 0.14
1962 -0.42 0.14
1963 -24.83 0.14
1964 -29.00 0.18
1965 -7.49 0.28
1966 11.28 0.26
1967 34.49 0.21
1968 6.64 0.27
1969 19.30 0.20
1970 21.44 0.21
1971 15.14 0.19
1972 29.41 0.17
1973 42.88 0.09
1974 34.25 -0.03
1975 27.95 0.12
1976 10.29 -0.00
1977 20.11 0.00
1978 20.63 0.22
1979 18.77 0.21
1980 11.31 0.28
1981 40.78 0.09
1982 25.19 0.20
1983 73.92 0.26
1984 38.34 0.24
1985 39.19 0.20
1986 40.97 0.01
1987 37.45 0.26
1988 38.30 0.26
1989 41.10 0.25
1990 53.61 0.27
1991 32.59 0.27
1992 39.90 0.27
1993 44.57 0.27
1994 42.18 0.27
1995 56.16 0.27
1996 34.20 0.27
1997 69.49 0.27
1998 76.59 3.44
1999 54.80 3.19
2000 54.09 3.03
2001 44.60 3.08
2002 63.06 3.15
2003 58.77 3.16
2004 62.40 2.68
2005 63.83 3.29
2006 69.41 3.23
2007 69.93 3.29
2008 78.85 3.30
2009 81.79 3.27
2010 81.90 3.34
2011 85.07 3.41
2012 79.50 3.58
2013 77.29 3.37
2014 94.70 3.35
2015 89.35 3.33
2016 104.69 3.26
2017 121.42 3.28
2018 103.85 3.32
2019 143.35 3.35
2020 149.55 3.33
2021 120.68 3.35
2022 134.86 3.23
2023 185.47 3.34


Indian
Special Calculation of Zones
With Tidegauge Stations
year slc tsSlc
1950 0.00 0.00
1951 -15.63 0.00
1952 -7.17 0.00
1953 -16.68 0.00
1954 -2.22 0.00
1955 27.66 0.00
1956 11.68 0.00
1957 -18.25 -0.03
1958 8.27 0.51
1959 11.83 0.16
1960 1.94 -0.15
1961 -7.49 -0.03
1962 13.80 -0.17
1963 -4.16 -0.14
1964 18.25 -0.03
1965 -27.20 -0.21
1966 -20.72 -0.21
1967 -6.71 0.19
1968 10.25 -0.25
1969 -23.48 0.14
1970 23.78 0.05
1971 40.88 -0.36
1972 -31.31 -0.07
1973 35.95 -0.14
1974 32.43 -0.43
1975 31.83 -0.32
1976 18.02 -0.36
1977 38.61 -0.38
1978 35.85 -0.50
1979 12.24 -0.43
1980 34.66 -0.16
1981 50.26 -0.05
1982 -16.58 -0.38
1983 12.99 -0.19
1984 54.15 -0.16
1985 17.96 -0.38
1986 1.48 -0.35
1987 5.74 -0.18
1988 53.46 -0.39
1989 45.03 -0.39
1990 36.80 -0.39
1991 24.70 -0.39
1992 21.11 -0.39
1993 6.17 -0.84
1994 12.34 -0.49
1995 36.95 -0.63
1996 52.90 -0.26
1997 5.31 -0.26
1998 31.95 -0.26
1999 79.14 -0.26
2000 76.50 -0.26
2001 71.97 -0.26
2002 28.40 -0.26
2003 39.97 -0.28
2004 36.33 -0.14
2005 47.86 -0.22
2006 35.08 -0.23
2007 59.86 -0.27
2008 82.72 -0.14
2009 70.76 -0.12
2010 90.60 -0.03
2011 105.91 -0.17
2012 100.00 -0.03
2013 114.72 -0.08
2014 86.73 -0.11
2015 67.98 -0.02
2016 104.37 0.11
2017 106.81 -0.12
2018 93.31 -0.12
2019 83.35 -0.08
2020 109.72 -0.09
2021 140.50 0.03
2022 135.87 -0.13
2023 157.39 0.18


Pacific
Special Calculation of Zones
With Tidegauge Stations
year slc tsSlc
1950 0.00 0.00
1951 -5.68 0.00
1952 -1.56 0.00
1953 7.90 0.00
1954 1.43 0.00
1955 -12.87 0.00
1956 -13.85 0.00
1957 13.58 0.00
1958 4.42 0.00
1959 -0.11 0.00
1960 -7.48 0.12
1961 1.63 0.25
1962 -12.50 0.14
1963 -17.64 0.14
1964 -9.93 0.14
1965 -5.71 0.14
1966 -8.28 0.14
1967 -1.24 0.55
1968 -17.90 1.61
1969 5.11 -1.11
1970 -8.98 -1.06
1971 -8.53 -0.85
1972 12.17 0.39
1973 2.76 -1.89
1974 10.24 -1.67
1975 8.03 -1.76
1976 7.76 -1.88
1977 -2.20 -1.95
1978 -0.74 -1.68
1979 -2.41 -1.90
1980 -4.87 -1.40
1981 11.79 -1.61
1982 -0.75 -1.56
1983 23.31 -1.79
1984 -7.45 -1.68
1985 -23.37 -1.69
1986 -1.80 -1.59
1987 -1.34 -1.56
1988 -6.70 -1.66
1989 13.23 -1.71
1990 6.36 -1.46
1991 5.66 -1.90
1992 19.22 -1.90
1993 -6.34 -1.90
1994 10.23 -1.82
1995 9.36 -1.71
1996 5.60 -1.71
1997 19.18 -1.71
1998 19.00 -1.71
1999 32.62 -1.71
2000 23.08 -1.71
2001 20.70 -1.71
2002 18.62 -1.71
2003 30.24 -1.71
2004 34.02 -1.71
2005 26.75 -1.71
2006 32.66 -1.71
2007 33.73 -1.71
2008 29.31 -0.97
2009 35.62 -1.38
2010 50.38 -0.62
2011 48.51 -0.62
2012 63.54 -0.62
2013 45.99 -0.56
2014 55.30 -0.56
2015 56.20 -0.56
2016 73.18 -0.80
2017 69.88 -0.55
2018 58.61 -0.92
2019 66.72 -0.07
2020 82.03 -0.07
2021 91.42 -0.07
2022 89.25 -0.07
2023 88.85 -0.07