In the last decades several indicators have been proposed to guide decision makers and help manage natural capital. Among such indicators is the Ecological Footprint, a resource accounting tool with a biophysical and thermodynamic basis. In our recent paper (Niccolucci et al., 2009), a three dimensional Ecological Footprint (3DEF) model was proposed to better explain the difference between human demand for natural capital stocks and resource flows. Such 3DEF model has two relevant dimensions: the surface area (or Footprint size – EFsize) and the height (or Footprint depth – EFdepth). EFsize accounts for the human appropriation of the annual income from natural capital while EFdepth accounts for the depletion of stocks of natural capital and/or the accumulation of stocks of wastes. Building on the 2009 Edition of the National Footprint Accounts (NFA), global trends (from 1961 to 2006) for both EFsize and EFdepth were analyzed. EFsize doubled from 1961 to 1986; after 1986 it reached an asymptotic value equal to the Earth's biocapacity (BC) and remained constant. Conversely, EFdepth remained constant at the “natural depth” value until 1986, the year in which global EF first exceeded Earth's BC. A growing trend was observed after that. Trends in each Footprint land type were also analyzed to better appraise the land type under the higher human induced stress. The usefulness of adopting such 3DEF model in the National Footprint Accounts was also discussed. In comparing any nation's demand for ecological assets with its own biocapacity in a given year, four hypothetical cases were identified which could serve as the basis for a new Footprint geography based on both size and depth concepts. This 3DEF model could help distinguish between the use of natural capital flows and the depletion of natural capital stocks while maintaining the structure and advantages of the classical Ecological Footprint formulation.
[1]
E. Tiezzi.
The End of Time
,
2002
.
[2]
Mathis Wackernagel,et al.
Establishing national natural capital accounts based on detailed Ecological Footprint and biological capacity assessments
,
2004
.
[3]
Gene Bazan.
Our Ecological Footprint: Reducing Human Impact on the Earth
,
1997
.
[4]
William E. Rees.
Ecological Footprints and Biocapacity: Essential Elements in Sustainability Assessment
,
2006
.
[5]
Simone Bastianoni,et al.
How deep is the footprint? A 3D representation
,
2009
.
[6]
Jo Dewulf,et al.
Renewables-based technology : sustainability assessment
,
2006
.
[7]
J. Hicks.
Value and Capital: An Inquiry into Some Fundamental Principles of Economic Theory.
,
1939
.
[8]
William E. Rees,et al.
Ecological footprints and appropriated carrying capacity: what urban economics leaves out
,
1992
.
[9]
M. Wackernagel,et al.
Perceptual and structural barriers to investing in natural capital: Economics from an ecological footprint perspective
,
1997
.
[10]
M. Wackernagel,et al.
Shrink and share: humanity's present and future Ecological Footprint
,
2008,
Philosophical Transactions of the Royal Society B: Biological Sciences.
[11]
M. Wackernagel,et al.
Our ecological footprint
,
1996
.
[12]
H. Daly.
Toward some operational principles of sustainable development
,
1990
.
[13]
Enzo Tiezzi,et al.
An exploration of the mathematics behind the ecological footprint
,
2008
.