Gravitationally bound geoengineering dust shade at the inner Lagrange point

R. Bewick; J.P. Sanchez Cuartielles; C.R. McInnes

doi:10.1016/j.asr.2012.07.008

Gravitationally bound geoengineering dust shade at the inner Lagrange point

R. Bewick, J.P. Sanchez Cuartielles, C.R. McInnes

Mechanical And Aerospace Engineering

Research output: Contribution to journal › Article › peer-review

5 Citations (Scopus)

366 Downloads (Pure)

Abstract

This paper presents a novel method of space-based geoengineering which uses the mass of a captured near Earth asteroid to gravitationally anchor a cloud of unprocessed dust in the vicinity of the L1 position to reduce the level of solar insolation at Earth. It has subsequently been shown that a cloud contained within the zero-velocity curve of the largest near Earth asteroid, Ganymede, can lead to an insolation reduction of 6.58% on Earth, which is significantly larger than the 1.7% required to offset a 2C increase in mean global temperature. The masses of the next largest near Earth asteroids are found to be too small to achieve the required level of insolation reduction, however, they are significant enough to be used as part of a portfolio of geoengineering schemes.

Original language	English
Pages (from-to)	1405-1410
Number of pages	10
Journal	Advances in Space Research
Volume	50
Issue number	10
Early online date	14 Jul 2012
DOIs	https://doi.org/10.1016/j.asr.2012.07.008
Publication status	Published - 15 Nov 2012

Keywords

geoengineering
Lagrange point
four-body problem
zero-velocity curve

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10.1016/j.asr.2012.07.008

Bewick R et al Pure Gravitationally bound geoengineering dust shade at the inner Lagrange point Nov 2012Accepted author manuscript, 1.58 MB

Cite this

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title = "Gravitationally bound geoengineering dust shade at the inner Lagrange point",

abstract = "This paper presents a novel method of space-based geoengineering which uses the mass of a captured near Earth asteroid to gravitationally anchor a cloud of unprocessed dust in the vicinity of the L1 position to reduce the level of solar insolation at Earth. It has subsequently been shown that a cloud contained within the zero-velocity curve of the largest near Earth asteroid, Ganymede, can lead to an insolation reduction of 6.58% on Earth, which is significantly larger than the 1.7% required to offset a 2C increase in mean global temperature. The masses of the next largest near Earth asteroids are found to be too small to achieve the required level of insolation reduction, however, they are significant enough to be used as part of a portfolio of geoengineering schemes.",

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author = "R. Bewick and {Sanchez Cuartielles}, J.P. and C.R. McInnes",

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T1 - Gravitationally bound geoengineering dust shade at the inner Lagrange point

AU - Bewick, R.

AU - Sanchez Cuartielles, J.P.

AU - McInnes, C.R.

PY - 2012/11/15

Y1 - 2012/11/15

N2 - This paper presents a novel method of space-based geoengineering which uses the mass of a captured near Earth asteroid to gravitationally anchor a cloud of unprocessed dust in the vicinity of the L1 position to reduce the level of solar insolation at Earth. It has subsequently been shown that a cloud contained within the zero-velocity curve of the largest near Earth asteroid, Ganymede, can lead to an insolation reduction of 6.58% on Earth, which is significantly larger than the 1.7% required to offset a 2C increase in mean global temperature. The masses of the next largest near Earth asteroids are found to be too small to achieve the required level of insolation reduction, however, they are significant enough to be used as part of a portfolio of geoengineering schemes.

AB - This paper presents a novel method of space-based geoengineering which uses the mass of a captured near Earth asteroid to gravitationally anchor a cloud of unprocessed dust in the vicinity of the L1 position to reduce the level of solar insolation at Earth. It has subsequently been shown that a cloud contained within the zero-velocity curve of the largest near Earth asteroid, Ganymede, can lead to an insolation reduction of 6.58% on Earth, which is significantly larger than the 1.7% required to offset a 2C increase in mean global temperature. The masses of the next largest near Earth asteroids are found to be too small to achieve the required level of insolation reduction, however, they are significant enough to be used as part of a portfolio of geoengineering schemes.

KW - geoengineering

KW - Lagrange point

KW - four-body problem

KW - zero-velocity curve

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UR - http://www.sciencedirect.com/science/article/pii/S0273117712004504

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DO - 10.1016/j.asr.2012.07.008

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VL - 50

SP - 1405

EP - 1410

JO - Advances in Space Research

JF - Advances in Space Research

SN - 0273-1177

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Gravitationally bound geoengineering dust shade at the inner Lagrange point

Abstract

Keywords

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VISIONSPACE - VISIONARY SPACE SYSTEMS: ORBITAL DYNAMICS AT EXTREMES OF SPACECRAFT LENGTH SCALE (ERC ADVANCED GRANT)

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Gravitationally bound geoengineering dust shade at the inner Lagrange point

Abstract

Keywords

Access to Document

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VISIONSPACE - VISIONARY SPACE SYSTEMS: ORBITAL DYNAMICS AT EXTREMES OF SPACECRAFT LENGTH SCALE (ERC ADVANCED GRANT)

Cite this