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(Note: Some of the text may be changed, which differ from the site shown.)[edit]

How do we estimate the global volume of ice?[edit]

Sea level equivalents[edit]

The IPCC and other outlets frequently indicate how much sea levels will rise under given climate change scenarios (mm sea level rise). Other times, you might see that such and such volume of ice (km³) is equivalent to so many millimetres of sea level rise (sea level equivalent (SLE); the amount of sea level rise on full melting of the ice). But how are these calculations made?

Table 1: Sea level equivalent (SLE) from various land ice sources. From Morligheim et al. ([[2017; 2019) and Farinotti et al. 2019. [[
Ice on land	Sea level equivalent (m)
Antarctic Ice Sheet	57.9
Greenland Ice Sheet	7.42
Glaciers and ice caps	0.32

Calculating the volume of ice[edit]

Antarctica[edit]

The first complexity is in calculating the volume of ice in the world. This is complex, as we often do not have a complete picture of the bed of the ice sheet or glacier. For Antarctica, BEDMAP2 and Bedmachine provides the most complete and up-to-date estimate of ice volume, and it is derived by combining thousands of radar and seismic measurements of ice thickness.

Greenland[edit]

BedMachine V3 provides a recent estimate of ice volume for the Greenland Ice Sheet.

In Greenland, the bed topography is a primary control on ice flow, grounding line migration and calving, and subglacial drainage. Deep fjords allow penetration of warm Atlantic Water that undercuts Greenland’s tidewater glaciers that terminate in the ocean. This means that sectors of the Greeland Ice Sheet, like the Antarctic Ice Sheet, are also vulnerable to oceanic forcing.

The BedMachine V3 is a 150 m horizontal resolution bed topography and bathymetric map, which shows that the sea level potential of the Greenland Ice Sheet is 7.42±0.05 m.

Global glaciers[edit]

For glaciers, ice thickness datasets are sparse. While we have a good estimate of global glacier ice surface area from satellite measurements, direct observations of glacier ice thickness are available for only around 3000 glaciers. These include radar measurements (both airbourne and from the ice surface) and seismic measurements. Unfortunately, these methods are time consuming and costly, and glaciers are often remote and difficult to access.

Yet glacier volume and ice thickness data are essential parameters required for understanding sea level rise, water resource management and assessment of future glacier changes. Glaciers and small ice caps are also contributing rapidly to present-day sea level rise. Ice thickness data and bed topography are essential data required for numerical modelling of glaciers.

Other methods employed to calculate glacier volume include volume-area scaling, and calculations of ice thickness based on ice surface slope that assume a given basal shear stress, and numerical models based on principles of ice physics and mass conservation. These methods, when correctly applied, do well against direct observations of ice thickness.

Farinotti et al. (2019) provided an updated estimate for ice thickness for all glaciers on Earth. They used an ensemble of five models to provide a consensus esimate for 215,000 glaciers outside of the Greenland and Antarctic ice sheets. They find a total volume of (1.58±0.41)×10⁵ km³.

Taking into account and discounting the ice below present-day sea level, this is equivalent to 0.32±0.08 m of sea-level equivalent. Roughly 15% of glacier ice is below sea level.

Calculating the mass of ice[edit]

Gigatonnes[edit]

The mass of ice is usually given in metric gigatonnes (Gt). 1 Gt = 10⁹ tonnes (where 1 tonne = 1000 kg); a gigatonne is 1 billion tonnes.

A tonne of water occupies one cubic metre (a cube 1 m × 1 m × 1 m). A gigatonne (Gt) occupies one cubic kilometre of water (1 km × 1 km × 1 km).

Densities of ice and water[edit]

Calculating the sea level equivalent for a given volume of ice requires some simple maths and a knowledge of the densities and properties of ice and sea water. Ice volumes are usually given in km³.

Table 2: Densities of ice and water (at 1 atmospheric pressure and 4.3°C)
Density of glacier ice	916.7 kg/m³	or 0.9167 Gt/km³
Density of pure water	1000 kg/m³	or 1 Gt/km³
Density of sea water	1027 kg/m³	or 1.027 Gt/km³

We can calculate the mass of something if we know the volume and the density:

$\rho {\text{ (Density)}}={\frac {m{\text{ (Mass)}}}{V{\text{ (Volume)}}}}$

$m{\text{ (Mass)}}=V{\text{ (Volume)}}\times \rho {\text{ (Density)}}$

$V{\text{ (Volume)}}={\frac {m{\text{ (Mass)}}}{\rho {\text{ (Density)}}}}$

See this website for more information on these equations.

Because ice and water are different densities, 1 km³ results in different masses. However, remember that 1 Gt of ice = 1 Gt of water! They take up different volumes but have the same mass. So, 1 Gt (whether ice or water) is equal to:

1.091 km³ ice
1 km³ pure water
0.9737 km³ sea water

Converting a volume (km³) to a mass of ice (Gt)[edit]

We can convert a given volume of ice (in km³) to a mass of ice (in Gt) by using the following equation:

Mass of ice (Gt) = Volume of ice (km³) x Density of ice (Gt/km³)

If we have a calculated ice volume of 500 km³, then:

Mass of ice = 500 km³ × 458.3 Gt⁄km³

The mass of ice here is ~458.3 Gt. If it all melted, you would have ~458.3 Gt of water.

Calculating sea level equivalent[edit]

Removing ice below sea level and floating ice[edit]

Calculating the sea level equivalent from a mass of ice involves firstly, removing all ice below sea level. This ice is already displacing water, and will not raise sea levels upon melting. This is explained in excellent detail here.

Floating ice (ice shelves, sea ice, floating ice tongues) are already floating and displacing water, and so these ice masses do not raise sea levels upon melting.

However, increased ice discharge, which delivers more icebergs to the ocean, will raise sea levels as ice that was not floating is delivered into the ocean.

The ice that is excluded from sea-level equivalent calculations is shown in the figure below. Firstly, the ice volume, ice thickness and bed topogrpahy must be known. Then, ice below sea level is excluded (it already displaces water).

ice that is below hydrostatic equilibrium is excluded as it will not contribute to sea level rise (only ice that is above freeboard will contribute to sea level rise).

Finally, in a firn air correction is applied; the snow and firn near the upper surface includes a lot of air. If you remove all the air, the surface of the ice sheet would be slightly lower.

Converting ice volume to sea level rise[edit]

To convert a mass of ice into the total amount global sea levels would rise if the ice all melted (i.e., the sea level equivalent), we need to know how much area the oceans cover. This is usually given as ~3.618×10⁸ km² (361.8 Mm²). A 1 mm increase in global sea level requires ~10⁻³ m³ (1 L, 10⁻¹² km³) of water for each square metre of the ocean surface, or ~10⁻¹² Gt (1 kg) of water.

We can calculate the volume of water required to raise global sea levels by 1 mm:

Volume = area x height

Area = 3.618×10⁸ km² (361.8 Mm²)

Height = 10⁻⁶ km (1 mm)

Volume (km³) = (3.618×10⁸ km²) × 10⁻⁶ km = 3.618×10² km³ = 361.8 km² water.

We can convert km3 of water to Gt of water as we did above; 1 km³ water ≈ 1 Gt water. In the same way, 1 Gt of ice ≈ 1 km³ water. So, 361.8 Gt of ice will raise global sea levels by ~1 mm. 361.8 Gt of ice is approximately to ~394.67 km³ ice.

Calculating sea-level equivalent[edit]

If we took our 458.30 Gt of ice (as calculated above), then we could calculate the global sea level equivalent by:

SLE (mm) = mass of ice (Gt) × (1⁄361.8)

SLE = 458.3 × (1⁄361.8)

SLE = 1.27 mm

However, we should note that some of the world’s glaciers have parts that are below sea level. This ice will not affect sea level if it melted. The volume of glacier ice below the surface of the ocean should therefore be subtracted from the total volume of glaciers and ice caps when calculating sea level equivalents.

Also remember that ice that is floating (like ice shelves, sea ice and icebergs) does not contribute to sea level rise upon melting. Only land ice above sea level will contribute to sea level rise.