Your search keyword '"Radachowsky J"' showing total 7 results

1. Detecting vulnerability of humid tropical forests to multiple stressors

Author

Saatchi, S, Longo, M, Xu, L, Yang, Y, Abe, H, André, M, Aukema, JE, Carvalhais, N, Cadillo-Quiroz, H, Cerbu, GA, Chernela, JM, Covey, K, Sánchez-Clavijo, LM, Cubillos, IV, Davies, SJ, De Sy, V, De Vleeschouwer, F, Duque, A, Sybille Durieux, AM, De Avila Fernandes, K, Fernandez, LE, Gammino, V, Garrity, DP, Gibbs, DA, Gibbon, L, Gowae, GY, Hansen, M, Lee Harris, N, Healey, SP, Hilton, RG, Johnson, CM, Kankeu, RS, Laporte-Goetz, NT, Lee, H, Lovejoy, T, Lowman, M, Lumbuenamo, R, Malhi, Y, Albert Martinez, JMM, Nobre, C, Pellegrini, A, Radachowsky, J, Román, F, Russell, D, Sheil, D, Smith, TB, Spencer, RGM, Stolle, F, Tata, HL, Torres, DDC, Tshimanga, RM, Vargas, R, Venter, M, West, J, Widayati, A, Wilson, SN, Brumby, S, and Elmore, AC

Abstract

Humid tropical forests play a dominant role in the functioning of Earth but are under increasing threat from changes in land use and climate. How forest vulnerability varies across space and time and what level of stress forests can tolerate before facing a tipping point are poorly understood. Here, we develop a tropical forest vulnerability index (TFVI) to detect and evaluate the vulnerability of global tropical forests to threats across space and time. We show that climate change together with land-use change have slowed the recovery rate of forest carbon cycling. Temporal autocorrelation, as an indicator of this slow recovery, increases substantially for above-ground biomass, gross primary production, and evapotranspiration when climate stress reaches a critical level. Forests in the Americas exhibit extensive vulnerability to these stressors, while in Africa, forests show relative resilience to climate, and in Asia reveal more vulnerability to land use and fragmentation. TFVI can systematically track the response of tropical forests to multiple stressors and provide early-warning signals for regions undergoing critical transitions.

Published

2021

2. Author Correction: Anthropogenic modification of forests means only 40% of remaining forests have high ecosystem integrity

Author

Grantham, H. S., Duncan, A., Evans, T. D., Jones, K. R., Beyer, H. L., Schuster, R., Walston, J., Ray, J. C., Robinson, J. G., Callow, M., Clements, T., Costa, H. M., DeGemmis, A., Elsen, P. R., Ervin, J., Franco, P., Goldman, E., Goetz, S., Hansen, A., Hofsvang, E., Jantz, P., Jupiter, S., Kang, A., Langhammer, P., Laurance, W. F., Lieberman, S., Linkie, M., Malhi, Y., Maxwell, S., Mendez, M., Mittermeier, R., Murray, N. J., Possingham, H., Radachowsky, J., Saatchi, S., Samper, C., Silverman, J., Shapiro, A., Strassburg, B., Stevens, T., Stokes, E., Taylor, R., Tear, T., Tizard, R., Venter, O., Visconti, P., Wang, S., and Watson, J. E. M.

Published

2021

3. Anthropogenic modification of forests means only 40% of remaining forests have high ecosystem integrity

Author

Grantham, H. S., Duncan, A., Evans, T. D., Jones, K. R., Beyer, H. L., Schuster, R., Walston, J., Ray, J. C., Robinson, J. G., Callow, M., Clements, T., Costa, H. M., DeGemmis, A., Elsen, P. R., Ervin, J., Franco, P., Goldman, E., Goetz, S., Hansen, A., Hofsvang, E., Jantz, P., Jupiter, S., Kang, A., Langhammer, P., Laurance, W. F., Lieberman, S., Linkie, M., Malhi, Y., Maxwell, S., Mendez, M., Mittermeier, R., Murray, N. J., Possingham, H., Radachowsky, J., Saatchi, S., Samper, C., Silverman, J., Shapiro, A., Strassburg, B., Stevens, T., Stokes, E., Taylor, R., Tear, T., Tizard, R., Venter, O., Visconti, P., Wang, S., and Watson, J. E. M.

Published

2020

4. Anthropogenic modification of forests means only 40% of remaining forests have high ecosystem integrity

Author

Grantham, H. S., Duncan, A., Evans, T. D., Jones, K. R., Beyer, H. L., Schuster, R., Walston, J., Ray, J. C., Robinson, J. G., Callow, M., Clements, T., Costa, H. M., DeGemmis, A., Elsen, P. R., Ervin, J., Franco, P., Goldman, E., Goetz, S., Hansen, A., Hofsvang, E., Jantz, P., Jupiter, S., Kang, A., Langhammer, P., Laurance, W. F., Lieberman, S., Linkie, M., Malhi, Y., Maxwell, S., Mendez, M., Mittermeier, R., Murray, N. J., Possingham, H., Radachowsky, J., Saatchi, S., Samper, C., Silverman, J., Shapiro, A., Strassburg, B., Stevens, T., Stokes, E., Taylor, R., Tear, T., Tizard, R., Venter, O., Visconti, P., Wang, S., Watson, J. E. M., Grantham, H. S., Duncan, A., Evans, T. D., Jones, K. R., Beyer, H. L., Schuster, R., Walston, J., Ray, J. C., Robinson, J. G., Callow, M., Clements, T., Costa, H. M., DeGemmis, A., Elsen, P. R., Ervin, J., Franco, P., Goldman, E., Goetz, S., Hansen, A., Hofsvang, E., Jantz, P., Jupiter, S., Kang, A., Langhammer, P., Laurance, W. F., Lieberman, S., Linkie, M., Malhi, Y., Maxwell, S., Mendez, M., Mittermeier, R., Murray, N. J., Possingham, H., Radachowsky, J., Saatchi, S., Samper, C., Silverman, J., Shapiro, A., Strassburg, B., Stevens, T., Stokes, E., Taylor, R., Tear, T., Tizard, R., Venter, O., Visconti, P., Wang, S., and Watson, J. E. M.

Abstract

Many global environmental agendas, including halting biodiversity loss, reversing land degradation, and limiting climate change, depend upon retaining forests with high ecological integrity, yet the scale and degree of forest modification remain poorly quantified and mapped. By integrating data on observed and inferred human pressures and an index of lost connectivity, we generate a globally consistent, continuous index of forest condition as determined by the degree of anthropogenic modification. Globally, only 17.4 million km2 of forest (40.5%) has high landscape-level integrity (mostly found in Canada, Russia, the Amazon, Central Africa, and New Guinea) and only 27% of this area is found in nationally designated protected areas. Of the forest inside protected areas, only 56% has high landscape-level integrity. Ambitious policies that prioritize the retention of forest integrity, especially in the most intact areas, are now urgently needed alongside current efforts aimed at halting deforestation and restoring the integrity of forests globally.

Published

2021

5. Only 40% of the world’s forests are in good health

Author

Grantham, H.S., Duncan, A., Evans, T. D., Jones, K., Beyer, H., Shuster, R., Walston, J., Ray, J., Robinson, J., Callow, M., Clements, T., Costa, H., DeGemmis, A., Elsen, P., Ervin, J., Franco, P., Goldman, E., Goetz, S., Hansen, A., Hofsvang, E., Jantz, P., Jupiter, S., Kang, A., Langhammer, P., Laurance, W.F., Lieberman, S., Linkie, M., Malhi, Y., Maxwell, S., Mendez, M., Mittermeier, R., Murray, N., Possingham, H., Radachowsky, J., Samper, C., Silverman, J., Shapiro, A., Strassburg, B., Stevens, T., Stokes, E., Taylor, R., Tear, T., Tizard, R., Venter, O., Visconti, P., Wang, S., and Watson, J.E.M.

Abstract

Many global environmental agendas, including halting biodiversity loss, reversing land degradation, and limiting climate change, depend upon retaining forests with high ecological integrity, yet the scale and degree of forest modification remains poorly quantified and mapped. By integrating data on direct and indirect forest pressures and lost forest connectivity, we generate the first globally-consistent, continuous index of forest condition as determined by degree of anthropogenic modification, which we term ‘forest health’. Globally, only 17.4 million km 2 of forest (40.5%) can be considered in high health (mostly found in Canada, Russia, the Amazon, Central Africa and New Guinea) and only 27% of this area is found in nationally-designated protected areas. Of all the world’s forests found within protected areas, only 56% can be considered in high health. Ambitious policies that prioritize the retention of forest health are now urgently needed alongside current efforts aimed at restoring the health of forests globally.

Published

2020

6. Modification of forests by people means only 40% of remaining forests have high ecosystem integrity

Author

Grantham, H.S., primary, Duncan, A., additional, Evans, T. D., additional, Jones, K., additional, Beyer, H., additional, Schuster, R., additional, Walston, J., additional, Ray, J., additional, Robinson, J., additional, Callow, M., additional, Clements, T., additional, Costa, H.M., additional, DeGemmis, A., additional, Elsen, P.R., additional, Ervin, J., additional, Franco, P., additional, Goldman, E., additional, Goetz, S., additional, Hansen, A., additional, Hofsvang, E., additional, Jantz, P., additional, Jupiter, S., additional, Kang, A., additional, Langhammer, P., additional, Laurance, W.F., additional, Lieberman, S., additional, Linkie, M., additional, Malhi, Y., additional, Maxwell, S., additional, Mendez, M., additional, Mittermeier, R., additional, Murray, N., additional, Possingham, H., additional, Radachowsky, J., additional, Samper, C., additional, Silverman, J., additional, Shapiro, A., additional, Strassburg, B., additional, Stevens, T., additional, Stokes, E., additional, Taylor, R., additional, Tear, T., additional, Tizard, R., additional, Venter, O., additional, Visconti, P., additional, Wang, S., additional, and Watson, J.E.M., additional

Published

2020

7. Improving climate and biodiversity outcomes through restoration of forest integrity.

Author

Rayden T, Jones KR, Austin K, and Radachowsky J

Subjects

Biodiversity, Agriculture, Climate Change, Ecosystem, Conservation of Natural Resources, Forests

Abstract

Targeting degraded areas in forested landscapes for restoration could deliver rapid climate mitigation and biodiversity conservation, improve resilience of forested lands to future climate change, and potentially reduce the trade-offs between nature recovery and agriculture. Although the importance of forest restoration for climate mitigation is acknowledged, current estimates of its climate mitigation potential may be underestimated because they focus predominantly on reforesting cleared areas. We built on recent analyses of forest integrity and unrealized forest biomass potential to examine the potential for restoring the integrity of degraded forests. There are over 1.5 billion ha of forests worldwide that retain 50-80% of their potential biomass. Prioritizing restoration in these areas could deliver rapid biodiversity and climate mitigation benefits, relative to restoring forest on cleared land. We applied a spatial planning approach to demonstrate how restoration interventions can be targeted to support the conservation of high-integrity forest, a potential pathway to the delivery of the 30×30 goal of the Convention on Biodiversity's Global Biodiversity Framework., (© 2023 The Authors. Conservation Biology published by Wiley Periodicals LLC on behalf of Society for Conservation Biology.)

Published

2023