85 results on '"Dalin, C"'
Search Results
2. Structure and Controls of the Global Virtual Water Trade Network
- Author
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Suweis, S., Konar, M., Dalin, C., Hanasaki, N., Rinaldo, A., and Rodriguez-Iturbe, I.
- Subjects
Physics - Geophysics ,Physics - Physics and Society - Abstract
Recurrent or ephemeral water shortages are a crucial global challenge, in particular because of their impacts on food production. The global character of this challenge is reflected in the trade among nations of virtual water, i.e. the amount of water used to produce a given commodity. We build, analyze and model the network describing the transfer of virtual water between world nations for staple food products. We find that all the key features of the network are well described by a model that reproduces both the topological and weighted properties of the global virtual water trade network, by assuming as sole controls each country's gross domestic product and yearly rainfall on agricultural areas. We capture and quantitatively describe the high degree of globalization of water trade and show that a small group of nations play a key role in the connectivity of the network and in the global redistribution of virtual water. Finally, we illustrate examples of prediction of the structure of the network under future political, economic and climatic scenarios, suggesting that the crucial importance of the countries that trade large volumes of water will be strengthened. D, Comment: 18 PAG., 4 FIGURES
- Published
- 2012
- Full Text
- View/download PDF
3. The 2023 report of the Lancet Countdown on health and climate change: the imperative for a health-centred response in a world facing irreversible harms
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Romanello, M., Napoli, C., Green, C., Kennard, H., Lampard, P., Scamman, D., Walawender, M., Ali, Z., Ameli, N., Ayeb-Karlsson, S., Beggs, P., Belesova, K., Berrang Ford, L., Bowen, K., Cai, W., Callaghan, M., Campbell-Lendrum, D., Chambers, J., Cross, T., van Daalen, K., Dalin, C., Dasandi, N., Dasgupta, S., Davies, M., Dominguez-Salas, P., Dubrow, R., Ebi, K., Eckelman, M., Ekins, P., Freyberg, C., Gasparyan, O., Gordon-Strachan, G., Graham, H., Gunther, S., Hamilton, I., Hang, Y., Hänninen, R., Hartinger, S., He, K., Heidecke, J., Hess, J., Hsu, S., Jamart, L., Jankin, S., Jay, O., Kelman, I., Kiesewetter, G., Kinney, P., Kniveton, D., Kouznetsov, R., Larosa, F., Lee, J., Lemke, B., Liu, Y., Liu, Z., Lott, M., Lotto Batista, M., Lowe, R., Odhiambo Sewe, M., Martinez-Urtaza, J., Maslin, M., McAllister, L., McMichael, C., Mi, Z., Milner, J., Minor, K., Minx, J., Mohajeri, N., Momen, N., Moradi-Lakeh, M., Morrissey, K., Munzert, S., Murray, K., Neville, T., Nilsson, M., Obradovich, N., O'Hare, M., Oliveira, C., Oreszczyn, T., Otto, M., Owfi, F., Pearman, O., Pega, F., Pershing, A., Rabbaniha, M., Rickman, J., Robinson, E., Rocklöv, J., Salas, R., Semenza, J., Sherman, J., Shumake-Guillemot, J., Silbert, G., Sofiev, M., Springmann, M., Stowell, J., Tabatabaei, M., Taylor, J., Thompson, R., Tonne, C., Treskova, M., Trinanes, J., Wagner, F., Warnecke, L., Whitcombe, H., Winning, M., Wyns, A., Yglesias-González, M., Zhang, S., Zhang, Y., Zhu, Q., Gong, P., Montgomery, H., Costello, A., Romanello, M., Napoli, C., Green, C., Kennard, H., Lampard, P., Scamman, D., Walawender, M., Ali, Z., Ameli, N., Ayeb-Karlsson, S., Beggs, P., Belesova, K., Berrang Ford, L., Bowen, K., Cai, W., Callaghan, M., Campbell-Lendrum, D., Chambers, J., Cross, T., van Daalen, K., Dalin, C., Dasandi, N., Dasgupta, S., Davies, M., Dominguez-Salas, P., Dubrow, R., Ebi, K., Eckelman, M., Ekins, P., Freyberg, C., Gasparyan, O., Gordon-Strachan, G., Graham, H., Gunther, S., Hamilton, I., Hang, Y., Hänninen, R., Hartinger, S., He, K., Heidecke, J., Hess, J., Hsu, S., Jamart, L., Jankin, S., Jay, O., Kelman, I., Kiesewetter, G., Kinney, P., Kniveton, D., Kouznetsov, R., Larosa, F., Lee, J., Lemke, B., Liu, Y., Liu, Z., Lott, M., Lotto Batista, M., Lowe, R., Odhiambo Sewe, M., Martinez-Urtaza, J., Maslin, M., McAllister, L., McMichael, C., Mi, Z., Milner, J., Minor, K., Minx, J., Mohajeri, N., Momen, N., Moradi-Lakeh, M., Morrissey, K., Munzert, S., Murray, K., Neville, T., Nilsson, M., Obradovich, N., O'Hare, M., Oliveira, C., Oreszczyn, T., Otto, M., Owfi, F., Pearman, O., Pega, F., Pershing, A., Rabbaniha, M., Rickman, J., Robinson, E., Rocklöv, J., Salas, R., Semenza, J., Sherman, J., Shumake-Guillemot, J., Silbert, G., Sofiev, M., Springmann, M., Stowell, J., Tabatabaei, M., Taylor, J., Thompson, R., Tonne, C., Treskova, M., Trinanes, J., Wagner, F., Warnecke, L., Whitcombe, H., Winning, M., Wyns, A., Yglesias-González, M., Zhang, S., Zhang, Y., Zhu, Q., Gong, P., Montgomery, H., and Costello, A.
- Published
- 2023
4. The 2022 report of the Lancet Countdown on health and climate change: health at the mercy of fossil fuels
- Author
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Romanello, M., Di Napoli, C., Drummond, P., Green, C., Kennard, H., Lampard, P., Scamman, D., Arnell, N., Ayeb-Karlsson, S., Ford, L., Belesova, K., Bowen, K., Cai, W., Callaghan, M., Campbell-Lendrum, D., Chambers, J., van Daalen, K., Dalin, C., Dasandi, N., Dasgupta, S., Davies, M., Dominguez-Salas, P., Dubrow, R., Ebi, K., Eckelman, M., Ekins, P., Escobar, L., Georgeson, L., Graham, H., Gunther, S., Hamilton, I., Hang, Y., Hänninen, R., Hartinger, S., He, K., Hess, J., Hsu, S.-C., Jankin, S., Jamart, L., Jay, O., Kelman, I., Kiesewetter, G., Kinney, P., Kjellstrom, T., Kniveton, D., Lee, J., Lemke, B., Liu, Y., Liu, Z., Lott, M., Batista, M., Lowe, R., MacGuire, F., Sewe, M., Martinez-Urtaza, J., Maslin, M., McAllister, L., McGushin, A., McMichael, C., Mi, Z., Milner, J., Minor, K., Minx, J., Mohajeri, N., Moradi-Lakeh, M., Morrissey, K., Munzert, S., Murray, K., Neville, T., Nilsson, M., Obradovich, N., O'Hare, M., Oreszczyn, T., Otto, M., Owfi, F., Pearman, O., Rabbaniha, M., Robinson, E., Rocklöv, J., Salas, R., Semenza, J., Sherman, J., Shi, L., Shumake-Guillemot, J., Silbert, G., Sofiev, M., Springmann, M., Stowell, J., Tabatabaei, M., Taylor, J., Triñanes, J., Wagner, F., Wilkinson, P., Winning, M., Yglesias-González, M., Zhang, S., Gong, P., Montgomery, H., Costello, A., Romanello, M., Di Napoli, C., Drummond, P., Green, C., Kennard, H., Lampard, P., Scamman, D., Arnell, N., Ayeb-Karlsson, S., Ford, L., Belesova, K., Bowen, K., Cai, W., Callaghan, M., Campbell-Lendrum, D., Chambers, J., van Daalen, K., Dalin, C., Dasandi, N., Dasgupta, S., Davies, M., Dominguez-Salas, P., Dubrow, R., Ebi, K., Eckelman, M., Ekins, P., Escobar, L., Georgeson, L., Graham, H., Gunther, S., Hamilton, I., Hang, Y., Hänninen, R., Hartinger, S., He, K., Hess, J., Hsu, S.-C., Jankin, S., Jamart, L., Jay, O., Kelman, I., Kiesewetter, G., Kinney, P., Kjellstrom, T., Kniveton, D., Lee, J., Lemke, B., Liu, Y., Liu, Z., Lott, M., Batista, M., Lowe, R., MacGuire, F., Sewe, M., Martinez-Urtaza, J., Maslin, M., McAllister, L., McGushin, A., McMichael, C., Mi, Z., Milner, J., Minor, K., Minx, J., Mohajeri, N., Moradi-Lakeh, M., Morrissey, K., Munzert, S., Murray, K., Neville, T., Nilsson, M., Obradovich, N., O'Hare, M., Oreszczyn, T., Otto, M., Owfi, F., Pearman, O., Rabbaniha, M., Robinson, E., Rocklöv, J., Salas, R., Semenza, J., Sherman, J., Shi, L., Shumake-Guillemot, J., Silbert, G., Sofiev, M., Springmann, M., Stowell, J., Tabatabaei, M., Taylor, J., Triñanes, J., Wagner, F., Wilkinson, P., Winning, M., Yglesias-González, M., Zhang, S., Gong, P., Montgomery, H., and Costello, A.
- Published
- 2022
- Full Text
- View/download PDF
5. Countdown on health and climate change: health at the mercy of fossil fuels
- Author
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Romanello, M., Di Napoli, C., Drummond, P., Green, C., Kennard, H., Lampard, P., Scamman, D., Arnell, N., Ayeb-Karlsson, S., Ford, L. B., Belesova, K., Bowen, K., Cai, W., Callaghan, M., Campbell-Lendrum, D., Chambers, J., van Daalen, K. R., Dalin, C., Dasandi, N., Dasgupta, S., Davies, M., Dominguez-Salas, P., Dubrow, R., Ebi, K. L., Eckelman, M., Ekins, P., Escobar, L. E., Georgeson, L., Graham
- Published
- 2022
- Full Text
- View/download PDF
6. The 2021 report of the Lancet Countdown on health and climate change: code red for a healthy future
- Author
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Romanello, M., McGushin, A., Di Napoli, C., Drummond, P., Hughes, N., Jamart, L., Kennard, H., Lampard, P., Solano Rodriguez, B., Arnell, N., Ayeb-Karlsson, S., Belesova, K., Cai, W., Campbell-Lendrum, D., Capstick, S., Chambers, J., Chu, L., Ciampi, L., Dalin, C., Dasandi, N., Dasgupta, S., Davies, M., Dominguez-Salas, P., Dubrow, R., Ebi, K.L., Eckelman, M., Ekins, P., Escobar, L.E., Georgeson, L., Grace, D., Graham, H., Gunther, S.H., Hartinger, S., He, K., Heaviside, C., Hess, J., Hsu, S.-C., Jankin, S., Jimenez, M.P., Kelman, I., Kiesewetter, G., Kinney, P.L., Kjellstrom, T., Kniveton, D., Lee, J.K.W., Lemke, B., Liu, Y., Liu, Z., Lott, M., Lowe, R., Martinez-Urtaza, J., Maslin, M., McAllister, L., McMichael, C., Mi, Z., Milner, J., Minor, K., Mohajeri, N., Moradi-Lakeh, M., Morrissey, K., Munzert, S., Murray, K.A., Neville, T., Nilsson, M., Obradovich, N., Sewe, M.O., Oreszczyn, T., Otto, M., Owfi, F., Pearman, O., Pencheon, D., Rabbaniha, M., Robinson, E., Rocklöv, J., Salas, R.N., Semenza, J.C., Sherman, J., Shi, L., Springmann, M., Tabatabaei, M., Taylor, J., Trinanes, J., Shumake-Guillemot, J., Vu, B., Wagner, F., Wilkinson, P., Winning, M., Yglesias, M., Zhang, S., Gong, P., Montgomery, H., Costello, A., Hamilton, I., Romanello, M., McGushin, A., Di Napoli, C., Drummond, P., Hughes, N., Jamart, L., Kennard, H., Lampard, P., Solano Rodriguez, B., Arnell, N., Ayeb-Karlsson, S., Belesova, K., Cai, W., Campbell-Lendrum, D., Capstick, S., Chambers, J., Chu, L., Ciampi, L., Dalin, C., Dasandi, N., Dasgupta, S., Davies, M., Dominguez-Salas, P., Dubrow, R., Ebi, K.L., Eckelman, M., Ekins, P., Escobar, L.E., Georgeson, L., Grace, D., Graham, H., Gunther, S.H., Hartinger, S., He, K., Heaviside, C., Hess, J., Hsu, S.-C., Jankin, S., Jimenez, M.P., Kelman, I., Kiesewetter, G., Kinney, P.L., Kjellstrom, T., Kniveton, D., Lee, J.K.W., Lemke, B., Liu, Y., Liu, Z., Lott, M., Lowe, R., Martinez-Urtaza, J., Maslin, M., McAllister, L., McMichael, C., Mi, Z., Milner, J., Minor, K., Mohajeri, N., Moradi-Lakeh, M., Morrissey, K., Munzert, S., Murray, K.A., Neville, T., Nilsson, M., Obradovich, N., Sewe, M.O., Oreszczyn, T., Otto, M., Owfi, F., Pearman, O., Pencheon, D., Rabbaniha, M., Robinson, E., Rocklöv, J., Salas, R.N., Semenza, J.C., Sherman, J., Shi, L., Springmann, M., Tabatabaei, M., Taylor, J., Trinanes, J., Shumake-Guillemot, J., Vu, B., Wagner, F., Wilkinson, P., Winning, M., Yglesias, M., Zhang, S., Gong, P., Montgomery, H., Costello, A., and Hamilton, I.
- Published
- 2021
7. The 2021 report of the Lancet Countdown on health and climate change: code red for a healthy future
- Author
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Romanello, M, McGushin, A, Di Napoli, C, Drummond, P, Hughes, N, Jamart, L, Kennard, H, Lampard, P, Rodriguez, BS, Arnell, N, Ayeb-Karlsson, S, Belesova, K, Cai, W, Campbell-Lendrum, D, Capstick, S, Chambers, J, Chu, L, Ciampi, L, Dalin, C, Dasandi, N, Dasgupta, S, Davies, M, Dominguez-Salas, P, Dubrow, R, Ebi, KL, Eckelman, M, Ekins, P, Escobar, LE, Georgeson, L, Grace, D, Graham, H, Gunther, SH, Hartinger, S, He, K, Heaviside, C, Hess, J, Hsu, S-C, Jankin, S, Jimenez, MP, Kelman, I, Kiesewetter, G, Kinney, PL, Kjellstrom, T, Kniveton, D, Lee, JKW, Lemke, B, Liu, Y, Liu, Z, Lott, M, Lowe, R, Martinez-Urtaza, J, Maslin, M, McAllister, L, McMichael, C, Mi, Z, Milner, J, Minor, K, Mohajeri, N, Moradi-Lakeh, M, Morrissey, K, Munzert, S, Murray, KA, Neville, T, Nilsson, M, Obradovich, N, Sewe, MO, Oreszczyn, T, Otto, M, Owfi, F, Pearman, O, Pencheon, D, Rabbaniha, M, Robinson, E, Rocklov, J, Salas, RN, Semenza, JC, Sherman, J, Shi, L, Springmann, M, Tabatabaei, M, Taylor, J, Trinanes, J, Shumake-Guillemot, J, Vu, B, Wagner, F, Wilkinson, P, Winning, M, Yglesias, M, Zhang, S, Gong, P, Montgomery, H, Costello, A, Hamilton, I, Romanello, M, McGushin, A, Di Napoli, C, Drummond, P, Hughes, N, Jamart, L, Kennard, H, Lampard, P, Rodriguez, BS, Arnell, N, Ayeb-Karlsson, S, Belesova, K, Cai, W, Campbell-Lendrum, D, Capstick, S, Chambers, J, Chu, L, Ciampi, L, Dalin, C, Dasandi, N, Dasgupta, S, Davies, M, Dominguez-Salas, P, Dubrow, R, Ebi, KL, Eckelman, M, Ekins, P, Escobar, LE, Georgeson, L, Grace, D, Graham, H, Gunther, SH, Hartinger, S, He, K, Heaviside, C, Hess, J, Hsu, S-C, Jankin, S, Jimenez, MP, Kelman, I, Kiesewetter, G, Kinney, PL, Kjellstrom, T, Kniveton, D, Lee, JKW, Lemke, B, Liu, Y, Liu, Z, Lott, M, Lowe, R, Martinez-Urtaza, J, Maslin, M, McAllister, L, McMichael, C, Mi, Z, Milner, J, Minor, K, Mohajeri, N, Moradi-Lakeh, M, Morrissey, K, Munzert, S, Murray, KA, Neville, T, Nilsson, M, Obradovich, N, Sewe, MO, Oreszczyn, T, Otto, M, Owfi, F, Pearman, O, Pencheon, D, Rabbaniha, M, Robinson, E, Rocklov, J, Salas, RN, Semenza, JC, Sherman, J, Shi, L, Springmann, M, Tabatabaei, M, Taylor, J, Trinanes, J, Shumake-Guillemot, J, Vu, B, Wagner, F, Wilkinson, P, Winning, M, Yglesias, M, Zhang, S, Gong, P, Montgomery, H, Costello, A, and Hamilton, I
- Published
- 2021
8. The 2020 report of the Lancet Countdown on health and climate change: responding to converging crises
- Author
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Watts, N, Amann, M, Arnell, N, Ayeb-Karlsson, S, Beagley, J, Belesova, K, Boykoff, M, Byass, P, Cai, W, Campbell-Lendrum, D, Capstick, S, Chambers, J, Coleman, S, Dalin, C, Daly, M, Dasandi, N, Dasgupta, S, Davies, M, Di Napoli, C, Dominguez-Salas, P, Drummond, P, Dubrow, R, Ebi, KL, Eckelman, M, Ekins, P, Escobar, LE, Georgeson, L, Golder, S, Grace, D, Graham, H, Haggar, P, Hamilton, I, Hartinger, S, Hess, J, Hsu, S-C, Hughes, N, Mikhaylov, SJ, Jimenez, MP, Kelman, I, Kennard, H, Kiesewetter, G, Kinney, PL, Kjellstrom, T, Kniveton, D, Lampard, P, Lemke, B, Liu, Y, Liu, Z, Lott, M, Lowe, R, Martinez-Urtaza, J, Maslin, M, McAllister, L, McGushin, A, McMichael, C, Milner, J, Moradi-Lakeh, M, Morrissey, K, Munzert, S, Murray, KA, Neville, T, Nilsson, M, Sewe, MO, Oreszczyn, T, Otto, M, Owfi, F, Pearman, O, Pencheon, D, Quinn, R, Rabbaniha, M, Robinson, E, Rocklov, J, Romanello, M, Semenza, JC, Sherman, J, Shi, L, Springmann, M, Tabatabaei, M, Taylor, J, Trinanes, J, Shumake-Guillemot, J, Vu, B, Wilkinson, P, Winning, M, Gong, P, Montgomery, H, Costello, A, Watts, N, Amann, M, Arnell, N, Ayeb-Karlsson, S, Beagley, J, Belesova, K, Boykoff, M, Byass, P, Cai, W, Campbell-Lendrum, D, Capstick, S, Chambers, J, Coleman, S, Dalin, C, Daly, M, Dasandi, N, Dasgupta, S, Davies, M, Di Napoli, C, Dominguez-Salas, P, Drummond, P, Dubrow, R, Ebi, KL, Eckelman, M, Ekins, P, Escobar, LE, Georgeson, L, Golder, S, Grace, D, Graham, H, Haggar, P, Hamilton, I, Hartinger, S, Hess, J, Hsu, S-C, Hughes, N, Mikhaylov, SJ, Jimenez, MP, Kelman, I, Kennard, H, Kiesewetter, G, Kinney, PL, Kjellstrom, T, Kniveton, D, Lampard, P, Lemke, B, Liu, Y, Liu, Z, Lott, M, Lowe, R, Martinez-Urtaza, J, Maslin, M, McAllister, L, McGushin, A, McMichael, C, Milner, J, Moradi-Lakeh, M, Morrissey, K, Munzert, S, Murray, KA, Neville, T, Nilsson, M, Sewe, MO, Oreszczyn, T, Otto, M, Owfi, F, Pearman, O, Pencheon, D, Quinn, R, Rabbaniha, M, Robinson, E, Rocklov, J, Romanello, M, Semenza, JC, Sherman, J, Shi, L, Springmann, M, Tabatabaei, M, Taylor, J, Trinanes, J, Shumake-Guillemot, J, Vu, B, Wilkinson, P, Winning, M, Gong, P, Montgomery, H, and Costello, A
- Abstract
For the Chinese, French, German, and Spanish translations of the abstract see Supplementary Materials section.
- Published
- 2021
9. Quantitative assessment of agricultural sustainability reveals divergent priorities among nations
- Author
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Zhang, X., Yao, G., Vishwakarma, S., Dalin, C., Komarek, A.M., Kanter, D.R., Davis, K.F., Pfeifer, K., Zhao, J., Zou, T., D'Odorico, P., Folberth, C., Rodriguez, F.G., Fanzo, J., Rosa, L., Dennison, W., Musumba, M., Heyman, A., Davidson, E.A., Zhang, X., Yao, G., Vishwakarma, S., Dalin, C., Komarek, A.M., Kanter, D.R., Davis, K.F., Pfeifer, K., Zhao, J., Zou, T., D'Odorico, P., Folberth, C., Rodriguez, F.G., Fanzo, J., Rosa, L., Dennison, W., Musumba, M., Heyman, A., and Davidson, E.A.
- Abstract
Agriculture is fundamental to all three pillars of sustainability, environment, society, and economy. However, the definition of sustainable agriculture and the capacities to measure it remain elusive. Independent and transparent measurements of national sustainability are needed to gauge progress, encourage accountability, and inform policy. Here, we developed a Sustainable Agriculture Matrix (SAM) to quantify national performance indicators in agriculture and to investigate the trade-offs and synergies based on historical data for most countries of the world. The results reveal priority areas for improvement by each country and show that the trade-offs and synergies among indicators often differ. Exceptions to common economic-versus-environmental trade-offs, for example, offer opportunities to learn from countries with synergistic pathways for multiple sustainability indicators. These SAM indicators will improve as data become more available, but this version offers a useful starting point for evaluating progress, identifying priorities for improvement, and informing national policies and actions toward sustainable agriculture.
- Published
- 2021
10. The 2020 report of The Lancet Countdown on health and climate change: responding to converging crises
- Author
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Watts, N., Amann, M., Arnell, N., Ayeb-Karlsson, S., Beagley, J., Belesova, K., Boykoff, M., Byass, P., Cai, W., Campbell-Lendrum, D., Capstick, S., Chambers, J., Coleman, S., Dalin, C., Daly, M., Dasandi, N., Dasgupta, S., Davies, M., Di Napoli, C., Dominguez-Salas, P., Drummond, P., Dubrow, R., Ebi, K.L., Eckelman, M., Ekins, P., Escobar, L.E., Georgeson, L., Golder, S., Grace, D., Graham, H., Haggar, P., Hamilton, I., Hartinger, S., Hess, J., Hsu, S.-C., Hughes, N., Jankin Mikhaylov, S., Jimenez, M.P., Kelman, I., Kennard, H., Kiesewetter, G., Kinney, P.L., Kjellstrom, T., Kniveton, D., Lampard, P., Lemke, B., Liu, Y., Liu, Z., Lott, M., Lowe, R., Martinez-Urtaza, J., Maslin, M., McAllister, L., McGushin, A., McMichael, C., Milner, J., Moradi-Lakeh, M., Morrissey, K., Munzert, S., Murray, K.A., Neville, T., Nilsson, M., Sewe, M.O., Oreszczyn, T., Otto, M., Owfi, F., Pearman, O., Pencheon, D., Quinn, R., Rabbaniha, M., Robinson, E., Rocklöv, J., Romanello, M., Semenza, K.C., Sherman, J., Shi, L., Springmann, M., Tabatabaei, M., Taylor, J., Triñanes, J., Shumake-Guillemot, J., Vu, B., Wilkinson, P., Winning, M., Gong, P., Montgomery, H., Costello, A., Watts, N., Amann, M., Arnell, N., Ayeb-Karlsson, S., Beagley, J., Belesova, K., Boykoff, M., Byass, P., Cai, W., Campbell-Lendrum, D., Capstick, S., Chambers, J., Coleman, S., Dalin, C., Daly, M., Dasandi, N., Dasgupta, S., Davies, M., Di Napoli, C., Dominguez-Salas, P., Drummond, P., Dubrow, R., Ebi, K.L., Eckelman, M., Ekins, P., Escobar, L.E., Georgeson, L., Golder, S., Grace, D., Graham, H., Haggar, P., Hamilton, I., Hartinger, S., Hess, J., Hsu, S.-C., Hughes, N., Jankin Mikhaylov, S., Jimenez, M.P., Kelman, I., Kennard, H., Kiesewetter, G., Kinney, P.L., Kjellstrom, T., Kniveton, D., Lampard, P., Lemke, B., Liu, Y., Liu, Z., Lott, M., Lowe, R., Martinez-Urtaza, J., Maslin, M., McAllister, L., McGushin, A., McMichael, C., Milner, J., Moradi-Lakeh, M., Morrissey, K., Munzert, S., Murray, K.A., Neville, T., Nilsson, M., Sewe, M.O., Oreszczyn, T., Otto, M., Owfi, F., Pearman, O., Pencheon, D., Quinn, R., Rabbaniha, M., Robinson, E., Rocklöv, J., Romanello, M., Semenza, K.C., Sherman, J., Shi, L., Springmann, M., Tabatabaei, M., Taylor, J., Triñanes, J., Shumake-Guillemot, J., Vu, B., Wilkinson, P., Winning, M., Gong, P., Montgomery, H., and Costello, A.
- Abstract
The Lancet Countdown is an international collaboration established to provide an independent, global monitoring system dedicated to tracking the emerging health profile of the changing climate. The 2020 report presents 43 indicators across five sections: climate change impacts, exposures, and vulnerabilities; adaptation, planning, and resilience for health; mitigation actions and health co-benefits; economics and finance; and public and political engagement. This report represents the findings and consensus of the 35 leading academic institutions and UN agencies that make up The Lancet Countdown, and draws on the expertise of climate scientists, geographers, engineers, experts in energy, food, and transport, economists, social, and political scientists, data scientists, public health professionals, and doctors.
- Published
- 2021
11. Groundwater Depletion Embedded in Domestic Transfers and International Exports of the United States
- Author
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Gumidyala, S., Ruess, P.J., Konar, M., Marston, L., Dalin, C., Wada, Y., Gumidyala, S., Ruess, P.J., Konar, M., Marston, L., Dalin, C., and Wada, Y.
- Abstract
The United States plays a key role in global food security by producing and exporting agricultural products. Groundwater irrigation is increasingly important in agricultural production, nearly tripling since records began in 1950. Increased reliance on groundwater and prolonged unsustainable pumping of aquifers has led to groundwater depletion in many areas. In this study, we ask: How much groundwater depletion is embedded in the domestic transfers and international agricultural exports of the United States? How much do domestic and international agricultural commodity fluxes rely on unsustainable groundwater use? To address these questions, we quantify the amount of nonrenewable groundwater that is incorporated into agricultural commodities produced in the United States and transferred both within the country and exported internationally. We find that 26.3 km urn:x-wiley:wrcr:media:wrcr24413:wrcr24413-math-0001 of nonrenewable groundwater was transferred domestically in 2002 and 2.7 km urn:x-wiley:wrcr:media:wrcr24413:wrcr24413-math-0002 was sent abroad. In 2012, 34.8 km urn:x-wiley:wrcr:media:wrcr24413:wrcr24413-math-0003 was transferred domestically and 3.7 km urn:x-wiley:wrcr:media:wrcr24413:wrcr24413-math-0004 was exported. This indicates an increase of 32% in domestic transfers and 38% in international exports. In 2002, we find that 1,491,126 kt (340 billion USD) of agricultural products reliant on nonrenewable groundwater were domestically transferred, while 119,048 kt (47 billion USD) were exported. In 2012, the mass transfer of agricultural goods reliant on unsustainable groundwater decreased, but their value in national and international supply chains increased by 54% and 31%, respectively. Our results underscore the importance of the long‐term risks posed to global agricultural supply chains from reliance on unsustainable groundwater use.
- Published
- 2020
12. 'More crop per drop': Exploring India's cereal water use since 2005
- Author
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Kayatz, B., Harris, F., Hillier, J., Adhya, T., Dalin, C., Nayak, D., Green, R., Smith, P., and Dangour, A.
- Subjects
Crops, Agricultural ,Conservation of Water Resources ,India ,Agriculture ,Oryza ,Zea mays ,Article ,Water Supply ,Water Resources ,Edible Grain ,Fertilizers ,Millets ,Sorghum ,Triticum - Abstract
India has the highest national freshwater demand globally and 91% of India's freshwater is used in the agriculture sector. Cereals account for over 50% of the dietary water footprint in India and represent a potential opportunity for reducing water use in Indian agriculture. This study combines governmental production and irrigation statistics with crop distribution maps to examine trends in annual water use for cereal production in India between 2005 and 2014. A new online water assessment tool, Cool Farm Tool Water (CFTW), was used to calculate water use and derive seasonal state-level blue and green water footprints for rice, wheat, sorghum, millet and maize. The analysis indicates that India achieved 26.4% increased total cereal production between 2005 and 2014 without additional water or land use. Cereal water footprints have declined due to higher yields for most crops and slightly lower rates of evapotranspiration. There has also been a shift in the area under production away from the Kharif (monsoon) towards the Rabi (dry) season in which total water footprints for all cereals except rice are substantially lower (-33.4% to -45.0% compared to Kharif), but show a significantly higher dependency on ground and surface water. The value of this study is two-fold. First, it provides a full assessment of production trends for the five major cereals in India for each year from 2005 to 2014 and links it to water use. Secondly, it uses updated seasonal water footprints, which demonstrate the potential for changes in cereal production practices to contribute to improved efficiency of water use in India. Future pressures on scarce water resources may encourage transition to cereals with lower irrigation dependency, in particular maize, but also sorghum and millet. In addition, increased emphasis on improving millet and sorghum yields would be of benefit to secure cereal production and reduce its overall water footprint.
- Published
- 2019
13. The 2019 report of The Lancet Countdown on health and climate change: ensuring that the health of a child born today is not defined by a changing climate
- Author
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Watts, N., Amann, M., Arnell, N., Ayeb-Karlsson, S., Belesova, K., Boykoff, M., Byass, P., Cai, W., Campbell-Lendrum, D., Capstick, S., Chambers, J., Dalin, C., Daly, M., Dasandi, N., Davies, M., Drummond, P., Dubrow, R., Ebi, K., Eckelman, M., Ekins, P., Escobar, L., Fernandez Montoya, L., Georgeson, L., Graham, H., Haggar, P., Hamilton, I., Hartinger, S., Hess, J., Kelman, I., Kiesewetter, G., Kjellstrom, T., Kniveton, D., Lemke, B., Liu, Y., Lott, M., Lowe, R., Sewe, M.O., Martinez-Urtaza, J., Maslin, M., McAllister, L., McGushin, A., Jankin Mikhaylov, S., Milner, J., Moradi-Lakeh, M., Morrissey, K., Murray, K., Munzert, S., Nilsson, M., Neville, T., Oreszczyn, T., Owfi, F., Pearman, O., Pencheon, D., Phung, D., Pye, S., Quinn, R., Rabbaniha, M., Robinson, E., Rocklöv, J., Semenza, J., Sherman, J., Shumake-Guillemot, J., Tabatabaei, M., Taylor, J., Trinanes, J., Wilkinson, P., Costello, A., Gong, P., Montgomery, H., Watts, N., Amann, M., Arnell, N., Ayeb-Karlsson, S., Belesova, K., Boykoff, M., Byass, P., Cai, W., Campbell-Lendrum, D., Capstick, S., Chambers, J., Dalin, C., Daly, M., Dasandi, N., Davies, M., Drummond, P., Dubrow, R., Ebi, K., Eckelman, M., Ekins, P., Escobar, L., Fernandez Montoya, L., Georgeson, L., Graham, H., Haggar, P., Hamilton, I., Hartinger, S., Hess, J., Kelman, I., Kiesewetter, G., Kjellstrom, T., Kniveton, D., Lemke, B., Liu, Y., Lott, M., Lowe, R., Sewe, M.O., Martinez-Urtaza, J., Maslin, M., McAllister, L., McGushin, A., Jankin Mikhaylov, S., Milner, J., Moradi-Lakeh, M., Morrissey, K., Murray, K., Munzert, S., Nilsson, M., Neville, T., Oreszczyn, T., Owfi, F., Pearman, O., Pencheon, D., Phung, D., Pye, S., Quinn, R., Rabbaniha, M., Robinson, E., Rocklöv, J., Semenza, J., Sherman, J., Shumake-Guillemot, J., Tabatabaei, M., Taylor, J., Trinanes, J., Wilkinson, P., Costello, A., Gong, P., and Montgomery, H.
- Abstract
The Lancet Countdown is an international, multidisciplinary collaboration, dedicated to monitoring the evolving health profile of climate change, and providing an independent assessment of the delivery of commitments made by governments worldwide under the Paris Agreement. The 2019 report presents an annual update of 41 indicators across five key domains: climate change impacts, exposures, and vulnerability; adaptation, planning, and resilience for health; mitigation actions and health co-benefits; economics and finance; and public and political engagement. The report represents the findings and consensus of 35 leading academic institutions and UN agencies from every continent. Each year, the methods and data that underpin the Lancet Countdown’s indicators are further developed and improved, with updates described at each stage of this report. The collaboration draws on the world-class expertise of climate scientists; ecologists; mathematicians; engineers; energy, food, and transport experts; economists; social and political scientists; public health professionals; and doctors, to generate the quality and diversity of data required.
- Published
- 2019
14. Managing China’s coal power plants to address multiple environmental objectives
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Peng, W., Wagner, F., Ramana, M.V., Zhai, H., Smalls, M., Dalin, C., Zhang, X., Mauzerall, D., Peng, W., Wagner, F., Ramana, M.V., Zhai, H., Smalls, M., Dalin, C., Zhang, X., and Mauzerall, D.
- Published
- 2018
15. Groundwater depletion embedded in international food trade
- Author
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Dalin, C., Wada, Y., Kastner, T., Puma, M.J., Dalin, C., Wada, Y., Kastner, T., and Puma, M.J.
- Abstract
Recent hydrological modelling1 and Earth observations2,3 have located and quantified alarming rates of groundwater depletion worldwide. This depletion is primarily due to water withdrawals for irrigation1,2,4, but its connection with the main driver of irrigation, global food consumption, has not yet been explored. Here we show that approximately eleven per cent of non-renewable groundwater use for irrigation is embedded in international food trade, of which two-thirds are exported by Pakistan, the USA and India alone. Our quantification of groundwater depletion embedded in the world’s food trade is based on a combination of global, cropspecific estimates of non-renewable groundwater abstraction and international food trade data. A vast majority of the world’s population lives in countries sourcing nearly all their staple crop imports from partners who deplete groundwater to produce these crops, highlighting risks for global food and water security. Some countries, such as the USA, Mexico, Iran and China, are particularly exposed to these risks because they both produce and import food irrigated from rapidly depleting aquifers. Our results could help to improve the sustainability of global food production and groundwater resource management by identifying priority regions and agricultural products at risk as well as the end consumers of these products.
- Published
- 2017
16. EFFECT OF INTENSIVE PHOTOTHERAPY ON TRANSCUTANEOUS MEASUREMENT OF BILIRUBIN BY MULTI-WAVELENGTH SPECTRAL REFLECTANCE (BILICHECK [TM])
- Author
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Bhutani, VK, Johnson, LH, Gourley, G, and Dalin, C
- Subjects
Pediatrics -- Research - Abstract
Background: Accurate and reproducible measures of serum bilirubin (TSB) may be attained in healthy term and near-term newborns by transcutaneous (TcB) measures of bilirubin using the non-invasive multi-wavelength spectral reflectance (BiliCheck TM) device. Hypothesis: A trend comparison between TSB and TcB may be evident in neonates undergoing intensive phototherapy (photoRx). Methods: Study design was generated to assess if an area of skin protected, by a patch, from phototherapy may be used to i) reliably measure TSB and ii) compare the gradient of TSB and TcB, for either exposed or unexposed areas, to define efficacy of photoRx. Measures of TSB (by HPLC and Diazo techniques) and TcB (patched and unpatched areas) were obtained simultaneously prephotoRx, 8 to 12 hours, later, every 24 hours and 8 to 12 hours after cessation of photoRx. Results: Preliminary data in 15 newborns (ranges of BW = 1103-3421g; GA = 29-40wks) show that change in consecutive serial TcB values to matched TSB values correlate by linear regression (r = 0.73). The trending of TcB and TSB is matched, concurrent and evident in a more dramatic manner in one near-term neonate (GA = 35 wks, BW = 2189 g) who had a double volume exchange transfusion (Ex Tx) while undergoing intensive phothoRx. As shown in the Figure, there is consistent gradient for TSB and TcB after the initiation of photoRx. Importantly, the rapid decline in TSB during the exchange was concurrently reflected in TcB values both for the areas exposed and unexposed to photoRx. Fall in tissue bilirubin is especially significant. Conclusions: Whereas, these preliminary data and case report suggest that, in babies receiving photoRx, skin deposition of bilirubin acutely reflects TSB values and that this trend is immediately apparent; accurate measure of TSB by TcB techniques, in babies receiving PhotoRx, requires continued study. (Supported in part by Spectrx Inc. Norcross, VA), VK Bhutani, MD, FAAP, LH Johnson, MD, FAAP, G Gourley, MD, FAAP, and C Dalin; Newborn Pediatrics, PA Hospital, Department of Pediatrics, Universities of Pennsylvania, Phila, PA, and Wisconsin--Madison, Madison, [...]
- Published
- 1999
17. Structure and Controls of the Global Virtual Water Trade Network
- Author
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Suweis S., Konar M., Dalin C., Hanasaki N., Rinaldo A., and Rodriguez-Iturbe I.
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Physics - Geophysics ,Physics - Physics and Society ,FOS: Physical sciences ,Physics and Society (physics.soc-ph) ,Model ,Geophysics (physics.geo-ph) - Abstract
Recurrent or ephemeral water shortages are a crucial global challenge, in particular because of their impacts on food production. The global character of this challenge is reflected in the trade among nations of virtual water, i.e. the amount of water used to produce a given commodity. We build, analyze and model the network describing the transfer of virtual water between world nations for staple food products. We find that all the key features of the network are well described by a model that reproduces both the topological and weighted properties of the global virtual water trade network, by assuming as sole controls each country's gross domestic product and yearly rainfall on agricultural areas. We capture and quantitatively describe the high degree of globalization of water trade and show that a small group of nations play a key role in the connectivity of the network and in the global redistribution of virtual water. Finally, we illustrate examples of prediction of the structure of the network under future political, economic and climatic scenarios, suggesting that the crucial importance of the countries that trade large volumes of water will be strengthened. D, 18 PAG., 4 FIGURES
- Published
- 2012
18. Modeling past and future structure of the global virtual water trade network
- Author
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Dalin, C., primary, Suweis, S., additional, Konar, M., additional, Hanasaki, N., additional, and Rodriguez‐Iturbe, I., additional
- Published
- 2012
- Full Text
- View/download PDF
19. Temporal dynamics of blue and green virtual water trade networks
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Konar, M., primary, Dalin, C., additional, Hanasaki, N., additional, Rinaldo, A., additional, and Rodriguez-Iturbe, I., additional
- Published
- 2012
- Full Text
- View/download PDF
20. Water for food: The global virtual water trade network
- Author
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Konar, M., primary, Dalin, C., additional, Suweis, S., additional, Hanasaki, N., additional, Rinaldo, A., additional, and Rodriguez‐Iturbe, I., additional
- Published
- 2011
- Full Text
- View/download PDF
21. Structure and controls of the global virtual water trade network
- Author
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Suweis, S., primary, Konar, M., additional, Dalin, C., additional, Hanasaki, N., additional, Rinaldo, A., additional, and Rodriguez-Iturbe, I., additional
- Published
- 2011
- Full Text
- View/download PDF
22. Measurement of Serum Bilirubin in Newborn Infants: Common Clinical Laboratory Methods Versus High Performance Liquid Chromatography (HPLC)
- Author
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Gourley, G R, primary, Bhutani, V, additional, Johnson, L, additional, Kreamer, B, additional, Kosorok, Michael R, additional, and Dalin, C, additional
- Published
- 1999
- Full Text
- View/download PDF
23. A Completely Automated GC Method To Measure Exhaled Ethane and Pentane
- Author
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Johnson, L H, primary, Dalin, C, additional, and Taylor, M, additional
- Published
- 1999
- Full Text
- View/download PDF
24. Oxidant Radicals in Expired Breath of Term and Preterm Infants and Adults
- Author
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Johnson, L H, primary, Sivieri, E, additional, Bhutani, V, additional, Dalin, C, additional, Weis, C, additional, Gerdes, J, additional, and Abbasi, S, additional
- Published
- 1999
- Full Text
- View/download PDF
25. Measurement of Serum Bilirubin in Newborn Infants: Common Clinical Laboratory Methods versus High Performance Liquid Chromatography (HPLC)† 1522
- Author
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Gourley, G, primary, Bhutani, V, additional, Johnson, L, additional, Kreamer, B, additional, Kosorok, M, additional, and Dalin, C, additional
- Published
- 1998
- Full Text
- View/download PDF
26. Need for Exchange Transfusion (Ex) in Infants with Severe BO Disease Treated with Intensive PhotoRx Alone (1991-95) or with BOX Plus Intensive PhotoRx(1996). 924
- Author
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Johnson, L H, primary, Bhutani, V K, additional, Abbasi, S, additional, Gerdes, J S, additional, Kraemer, W, additional, Dalin, C, additional, and Gourley, G, additional
- Published
- 1997
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- View/download PDF
27. Bilirubin Oxidase in Addition to Intensive Phototherapy to Eliminate or Delay Need for Exchange (Ex Tx). 923
- Author
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Johnson, L H, primary, Bhutani, V K, additional, Abbasi, S, additional, Dalin, C, additional, Kraemer, W, additional, Gerdes, J S, additional, and Gourley, G, additional
- Published
- 1997
- Full Text
- View/download PDF
28. Universal Newborn Bilirubin (SB) Screening. • 1133
- Author
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Bhutani, V K, primary, Johnson, L H, additional, Sivieri, E M, additional, Nadelson, A, additional, Dworanczyk, R, additional, Spitz, D M, additional, Grous, M K, additional, Dalin, C, additional, Cotton, T, additional, Hewson, P, additional, Abbasi, S, additional, and Gerdes, J S, additional
- Published
- 1997
- Full Text
- View/download PDF
29. Water for food: The global virtual water trade network
- Author
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Konar, M., Dalin, C., Suweis, SAMIR SIMON, Hanasaki, N., Rinaldo, Andrea, and Rodriguez Iturbe, I.
- Subjects
Integrated Model ,Flows ,Products ,Complex Networks ,Resources ,Scale - Abstract
We present a novel conceptual framework and methodology for studying virtual water trade. We utilize complex network theory to analyze the structure of the global virtual water trade associated with the international food trade. In the global virtual water trade network, the nations that participate in the international food trade correspond to the nodes, and the links represent the flows of virtual water associated with the trade of food from the country of export to the country of import. We find that the number of trade connections follows an exponential distribution, except for the case of import trade relationships, while the volume of water that each nation trades compares well with a stretched exponential distribution, indicating high heterogeneity of flows between nations. There is a power law relationship between the volume of virtual water traded and the number of trade connections of each nation. Highly connected nations are preferentially linked to poorly connected nations and exhibit low levels of clustering. However, when the volume of virtual water traded is taken into account, this structure breaks down. This indicates a global hierarchy, in which nations that trade large volumes of water are more likely to link to and cluster with other nations that trade large volumes of water, particularly when the direction of trade is considered. Nations that play a critical role in maintaining the global network architecture are highlighted. Our analysis provides the necessary framework for the development of a model of global virtual water trade aimed at applications ranging from network optimization to climate change impact evaluations.
30. Temporal dynamics of blue and green virtual water trade networks
- Author
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Konar, M., Dalin, C., Hanasaki, N., Rinaldo, A., and Rodriguez-Iturbe, I.
- Subjects
Integrated Model ,Crop Trade ,Resources - Abstract
Global food security increasingly relies on the trade of food commodities. Freshwater resources are essential to agricultural production and are thus embodied in the trade of food commodities, referred to as "virtual water trade." Agricultural production predominantly relies on rainwater (i.e., "green water"), though irrigation (i.e., "blue water") does play an important role. These different sources of water have distinctly different opportunity costs, which may be reflected in the way these resources are traded. Thus, the temporal dynamics of the virtual water trade networks from these distinct water sources require characterization. We find that 42 x 10(9) m(3) blue and 310 x 10(9) m(3) green water was traded in 1986, growing to 78 x 10(9) m(3) blue and 594 x 10(9) m(3) green water traded in 2008. Three nations dominate the export of green water resources: the USA, Argentina, and Brazil. As a country increases its export trade partners it tends to export relatively more blue water. However, as a country increases its import trade partners it does not preferentially import water from a specific source. The amount of virtual water that a country imports by increasing its import trade partners has been decreasing over time, with the exception of the soy trade. Both blue and green virtual water networks are efficient: 119 x 10(9) m(3) blue and 105 x 10(9) m(3) green water were saved in 2008. Importantly, trade has been increasingly saving water over time, due to the intensification of crop trade on more water-efficient links.
31. Climate change impacts on water sustainability of South African crop production
- Author
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Bonetti, S., Sutanudjaja, E. H., Mabhaudhi, Tafadzwanashe, Slotow, R., Dalin, C., Bonetti, S., Sutanudjaja, E. H., Mabhaudhi, Tafadzwanashe, Slotow, R., and Dalin, C.
32. Climate change impacts on water sustainability of South African crop production
- Author
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Bonetti, S., Sutanudjaja, E. H., Mabhaudhi, Tafadzwanashe, Slotow, R., Dalin, C., Bonetti, S., Sutanudjaja, E. H., Mabhaudhi, Tafadzwanashe, Slotow, R., and Dalin, C.
33. RED BLOOD CELL MALONDIALDEHYDE (RBC-MDA) & PLASMA VITAMIN E (E) LEVELS IN LOW BIRTH WEIGHT (LBW) INFANTS
- Author
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Johnson, L, primary, Cennamo, J, additional, Dalin, C, additional, and Bowen, F, additional
- Published
- 1984
- Full Text
- View/download PDF
34. THE NEED FOR A MICRO PLATELET MDA ASSAY
- Author
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Johnson, L, primary, Abbasi, S, additional, Grows, M, additional, and Dalin, C, additional
- Published
- 1984
- Full Text
- View/download PDF
35. 606 LACK OF CORRELATION BETWEEN SERUM VITAMIN E AND TOTAL LIPID LEVELS IN PRETERM INFANTS
- Author
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Abbasi, S, primary, Johnson, L, additional, Gerdes, J, additional, Dalin, C, additional, Grous, M, additional, and Otis, C, additional
- Published
- 1985
- Full Text
- View/download PDF
36. RED BLOOD CELL MALONDIALDEHYDE RBCMDA & PLASMA VITAMIN E E LEVELS IN LOW BIRTH WEIGHT LBW INFANTS
- Author
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Johnson, L., Cennamo, J., Dalin, C., and Bowen, F.
- Published
- 1984
37. The 2024 report of the Lancet Countdown on health and climate change: facing record-breaking threats from delayed action.
- Author
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Romanello M, Walawender M, Hsu SC, Moskeland A, Palmeiro-Silva Y, Scamman D, Ali Z, Ameli N, Angelova D, Ayeb-Karlsson S, Basart S, Beagley J, Beggs PJ, Blanco-Villafuerte L, Cai W, Callaghan M, Campbell-Lendrum D, Chambers JD, Chicmana-Zapata V, Chu L, Cross TJ, van Daalen KR, Dalin C, Dasandi N, Dasgupta S, Davies M, Dubrow R, Eckelman MJ, Ford JD, Freyberg C, Gasparyan O, Gordon-Strachan G, Grubb M, Gunther SH, Hamilton I, Hang Y, Hänninen R, Hartinger S, He K, Heidecke J, Hess JJ, Jamart L, Jankin S, Jatkar H, Jay O, Kelman I, Kennard H, Kiesewetter G, Kinney P, Kniveton D, Kouznetsov R, Lampard P, Lee JKW, Lemke B, Li B, Liu Y, Liu Z, Llabrés-Brustenga A, Lott M, Lowe R, Martinez-Urtaza J, Maslin M, McAllister L, McMichael C, Mi Z, Milner J, Minor K, Minx J, Mohajeri N, Momen NC, Moradi-Lakeh M, Morrisey K, Munzert S, Murray KA, Obradovich N, O'Hare MB, Oliveira C, Oreszczyn T, Otto M, Owfi F, Pearman OL, Pega F, Perishing AJ, Pinho-Gomes AC, Ponmattam J, Rabbaniha M, Rickman J, Robinson E, Rocklöv J, Rojas-Rueda D, Salas RN, Semenza JC, Sherman JD, Shumake-Guillemot J, Singh P, Sjödin H, Slater J, Sofiev M, Sorensen C, Springmann M, Stalhandske Z, Stowell JD, Tabatabaei M, Taylor J, Tong D, Tonne C, Treskova M, Trinanes JA, Uppstu A, Wagner F, Warnecke L, Whitcombe H, Xian P, Zavaleta-Cortijo C, Zhang C, Zhang R, Zhang S, Zhang Y, Zhu Q, Gong P, Montgomery H, and Costello A
- Abstract
Competing Interests: Declaration of interests Thirteen of the authors (ZA, S-CH, LJ, AM, CO, MO, JP, YP-S, DS, LB-V, MRo, MW, and HW) were compensated for their time while drafting and developing the Lancet Countdown's report. LC was supported by a grant from the National Heart, Lung, and Blood Institute of the National Institutes of Health. CD received funding from the European Research Council (FLORA, grant number 101039402). RD was supported by a grant from the High Tide Foundation and subcontracts on funds from the Wellcome Trust and US Centers for Disease Control and Prevention. GG-S received funding from the UK National Institute for Health and Care Research for the Global Health Research Group on Diet and Activity (NIHR133205, with sub-award contract number G109900-SJ1/171 with the University of Cambridge). SHG's research was supported by the National Research Foundation, Prime Minister's Office, Singapore, under its Campus for Research Excellence and Technological Enterprise programme (grant number NRF2019-THE001-0006). JJH was supported by two grants from the Wellcome Trust and a grant from the US National Science Foundation. RH, RK, and MSo acknowledge funding from Academy of Finland projects HEATCOST (grant 334798) and VFSP-WASE (grant 359421), together with EU Horizon projects FirEUrisk (grant number 101003890) and EXHAUSTION (grant number 820655). OJ was supported by grants from the National Health Medical Research Council (Heat and Health: building resilience to extreme heat in a warming world, GNT1147789); Wellcome Trust (Heat stress in ready-made garment factories in Bangladesh and the Heat inform pregnant study); and Resilience New South Wales (A new heat stress scale for general public); holds a patent for the Environmental Measurement Unit; and has received consulting fees from the National Institutes of Health. HM received funding from the Oak Foundation to support work on climate change through RealZero, is partly funded by the National Institute for Health Research's Comprehensive Biomedical Research Centre at University College London Hospitals, and received fees from Bayer Pharmaceuticals and Chiesl for sustainability consulting. JM-U was supported by grants PID2021-127107NB-I00 from Ministerio de Ciencia e Innovación (Spain) and 2021 SGR 00526 from Generalitat de Catalunya (Spain). JRo's work is supported by the Alexander von Humboldt foundation. RL, JRo, and MRo were supported by Horizon Europe through the IDAlert project (101057554) and UK Research and Innovation (reference number 10056533). RNS reports a contract with Massachusetts General Hospital. MSo and AU were supported by the Finnish Foreign Ministry project IBA-ILMA (grant number VN/13798/2023). MSp was supported by funding from the Wellcome Trust, through Our Planet Our Health (Livestock, Environment and People, award number 205212/Z/16/Z) and a Wellcome Career Development Award (Towards the full cost of diets, award number 225318/Z/22/Z). JDSh was supported by the Canadian Institutes of Health Research, the Commonwealth Fund, and the Emergency Care Research Institute and has received consulting fees from the Institute for Healthcare Research. JT was supported by the Research Council of Finland (T-Winning Spaces 2035 project), the UK Medical Research Council (PICNIC project), and the Finnish Ministry of the Environment (SEASON project). JB is employed as a consultant by the Global Climate and Health Alliance. ML received consulting fees from YarCom for advisory services and was supported by general use gifts awarded to the Center on Global Energy Policy at Columbia University, USA. JMil acknowledges consulting fees from the C40 Climate Leadership Group. CZ-C received a consultancy from the University of Alberta and was supported by contracts with her university (Universidad Peruana Cayetano Heredia), University of Leeds, WHO, and the Wellcome Trust; she was also supported by a letter of agreement between her university and the Food and Agriculture Organization's Indigenous Peoples Unit. MD was supported by the Wellcome Trust via the Complex Urban Systems for Sustainability and Health project (grants 205207/Z/16/Z and 209387/Z/17/Z). IH, S-CH, MRo, CT, and RL were supported by the Horizon Europe CATALYSE project (CATALYSE grant number 101057131, HORIZON-HLTH-2021-ENVHLTH-02, with UK Research and Innovation reference number 10041512). The work of YH, YL, DT, and QZ was supported by the National Aeronautics and Space Administration's Earth Action programme (grant number 80NSSC21K0507). AJP was supported by the Bezos Earth Fund and the Schmidt Family Foundation. ER and SD were supported by a Process-based models for climate impact attribution across sectors (PROCLIAS) grant (COST Action PROCLIAS grant CA19139), funded by European Cooperation in Science and Technology. All other authors declare no competing interests.
- Published
- 2024
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- View/download PDF
38. Impacts of the global food system on terrestrial biodiversity from land use and climate change.
- Author
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Boakes EH, Dalin C, Etard A, and Newbold T
- Subjects
- Conservation of Natural Resources, Food Supply, Agriculture, South America, Methane analysis, Biodiversity, Climate Change, Greenhouse Gases analysis
- Abstract
The global food system is a key driver of land-use and climate change which in turn drive biodiversity change. Developing sustainable food systems is therefore critical to reversing biodiversity loss. We use the multi-regional input-output model EXIOBASE to estimate the biodiversity impacts embedded within the global food system in 2011. Using models that capture regional variation in the sensitivity of biodiversity both to land use and climate change, we calculate the land-driven and greenhouse gas-driven footprints of food using two metrics of biodiversity: local species richness and rarity-weighted species richness. We show that the footprint of land area underestimates biodiversity impact in more species-rich regions and that our metric of rarity-weighted richness places a greater emphasis on biodiversity costs in Central and South America. We find that methane emissions are responsible for 70% of the overall greenhouse gas-driven biodiversity footprint and that, in several regions, emissions from a single year's food production are associated with global biodiversity loss equivalent to 2% or more of that region's total land-driven biodiversity loss. The measures we present are relatively simple to calculate and could be incorporated into decision-making and environmental impact assessments by governments and businesses., (© 2024. The Author(s).)
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- 2024
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- View/download PDF
39. The 2023 report of the Lancet Countdown on health and climate change: the imperative for a health-centred response in a world facing irreversible harms.
- Author
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Romanello M, Napoli CD, Green C, Kennard H, Lampard P, Scamman D, Walawender M, Ali Z, Ameli N, Ayeb-Karlsson S, Beggs PJ, Belesova K, Berrang Ford L, Bowen K, Cai W, Callaghan M, Campbell-Lendrum D, Chambers J, Cross TJ, van Daalen KR, Dalin C, Dasandi N, Dasgupta S, Davies M, Dominguez-Salas P, Dubrow R, Ebi KL, Eckelman M, Ekins P, Freyberg C, Gasparyan O, Gordon-Strachan G, Graham H, Gunther SH, Hamilton I, Hang Y, Hänninen R, Hartinger S, He K, Heidecke J, Hess JJ, Hsu SC, Jamart L, Jankin S, Jay O, Kelman I, Kiesewetter G, Kinney P, Kniveton D, Kouznetsov R, Larosa F, Lee JKW, Lemke B, Liu Y, Liu Z, Lott M, Lotto Batista M, Lowe R, Odhiambo Sewe M, Martinez-Urtaza J, Maslin M, McAllister L, McMichael C, Mi Z, Milner J, Minor K, Minx JC, Mohajeri N, Momen NC, Moradi-Lakeh M, Morrissey K, Munzert S, Murray KA, Neville T, Nilsson M, Obradovich N, O'Hare MB, Oliveira C, Oreszczyn T, Otto M, Owfi F, Pearman O, Pega F, Pershing A, Rabbaniha M, Rickman J, Robinson EJZ, Rocklöv J, Salas RN, Semenza JC, Sherman JD, Shumake-Guillemot J, Silbert G, Sofiev M, Springmann M, Stowell JD, Tabatabaei M, Taylor J, Thompson R, Tonne C, Treskova M, Trinanes JA, Wagner F, Warnecke L, Whitcombe H, Winning M, Wyns A, Yglesias-González M, Zhang S, Zhang Y, Zhu Q, Gong P, Montgomery H, and Costello A
- Subjects
- Humans, Global Health, Climate Change, Public Health
- Abstract
Competing Interests: Declaration of interests 14 of the authors (MRo, MWa, LJ, MBO'H, CO, HW, CdN, HK, PL, DS, CG, ZA, MY-G, and KRvD) were compensated for their time while drafting and developing the Lancet Countdown's report. OG was supported by the EU Horizon Grant: Climate Action To Advance Healthy Societies in Europe (Project 101057131–CATALYSE), for which there is overlap of data collection and preprocessing with the materials submitted in this report. MSp was supported by the Wellcome Trust Livestock, Environment and People (grant number 205212/Z/16/Z) and Wellcome Trust (grant number 225318/Z/22/Z). JT was supported by the Academy of Finland grants for the T-Winning (grant number 353327). CD was supported by the UK Natural Environment Research Council Independent Research Fellowship (grant number NE/N01524X/1), which ended in 2021, and by the European Research Council starting grant FLORA (grant number 101039402). OJ was supported by the NHMRC Investigator Grant entitled Heat and Health: Building resilience to extreme heat in a warming world (GNT20009507), the Wellcome Trust grant Heat stress in ready-made garment factories in Bangladesh (216059/Z/19/Z), and the Resilience New South Wales grant A new heat stress scale for general public (PJ-0000850). YL was supported by funding from the National Aeronautics and Space Administration (grant number: 80NSSC21K0507) for the wildfire population exposure and fire danger indicators. TO and IH were supported by the UK Research and Innovation Engineering and Physical Sciences Research Council Centre for Research in Energy Demand Solutions (grant number EP/R035288/1). MRo was supported by funding from IDAlert project (UK Research and Innovation project reference number 10056533). KB was supported by funding from the National Institute for Health and Care Research (NIHR) Centre on Non-communicable Diseases and Environmental Change (NIHR203247). All other authors declare no competing interests. The authors alone are responsible for the views expressed in this Commission, and they do not necessarily represent the views, decisions, or policies of the institutions with which they are affiliated.
- Published
- 2023
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40. Water Quality and Pollution Trading: A Sustainable Solution for Future Food Production.
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Zapata JG, Vangipuram B, Dalin C, and Erfani T
- Abstract
Nitrogen, an essential nutrient for plant growth, is commonly added to food crops in the form of manure and synthetic fertilizers. Fertilizer use has significantly increased in the past decades to meet the food demands from a rising population. Although this has boosted food production, it has come at a cost to the environment. Indeed, excess fertilizer ends up in water bodies, a pollution that causes losses in aquatic biodiversity. Better fertilizer management is therefore essential to maintaining water sustainability. Here, we develop and evaluate a nitrogen water quality trading scheme to address this challenge. Nitrogen trading incentivizes farmers to work together to invest in pollution reduction measures in order to keep nitrogen water pollution levels within a standardized limit. We build a mathematical model to represent the nitrogen trading and use it to assess the pollution reduction, the effect on the crop yield, and economical outcomes. The model is applied among local farms in the agricultural county of Suffolk, eastern England. We calculate the nitrogen load to the river from each farm and incorporate the abatement cost into the model. The results show how nitrogen water pollution could be reduced cost-effectively while simultaneously increasing the benefit for the whole catchment. Although the benefit does not increase for all the farms, the increase in benefit for the whole catchment is enough to compensate for this loss. The surplus benefit is equally distributed between all the farms, thus increasing their overall benefit. We discuss how the proposed trading model can create a platform for farmers to participate and reduce their water pollution., Competing Interests: The authors declare no competing financial interest., (© 2023 The Authors. Published by American Chemical Society.)
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- 2023
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41. The 2022 report of the Lancet Countdown on health and climate change: health at the mercy of fossil fuels.
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Romanello M, Di Napoli C, Drummond P, Green C, Kennard H, Lampard P, Scamman D, Arnell N, Ayeb-Karlsson S, Ford LB, Belesova K, Bowen K, Cai W, Callaghan M, Campbell-Lendrum D, Chambers J, van Daalen KR, Dalin C, Dasandi N, Dasgupta S, Davies M, Dominguez-Salas P, Dubrow R, Ebi KL, Eckelman M, Ekins P, Escobar LE, Georgeson L, Graham H, Gunther SH, Hamilton I, Hang Y, Hänninen R, Hartinger S, He K, Hess JJ, Hsu SC, Jankin S, Jamart L, Jay O, Kelman I, Kiesewetter G, Kinney P, Kjellstrom T, Kniveton D, Lee JKW, Lemke B, Liu Y, Liu Z, Lott M, Batista ML, Lowe R, MacGuire F, Sewe MO, Martinez-Urtaza J, Maslin M, McAllister L, McGushin A, McMichael C, Mi Z, Milner J, Minor K, Minx JC, Mohajeri N, Moradi-Lakeh M, Morrissey K, Munzert S, Murray KA, Neville T, Nilsson M, Obradovich N, O'Hare MB, Oreszczyn T, Otto M, Owfi F, Pearman O, Rabbaniha M, Robinson EJZ, Rocklöv J, Salas RN, Semenza JC, Sherman JD, Shi L, Shumake-Guillemot J, Silbert G, Sofiev M, Springmann M, Stowell J, Tabatabaei M, Taylor J, Triñanes J, Wagner F, Wilkinson P, Winning M, Yglesias-González M, Zhang S, Gong P, Montgomery H, and Costello A
- Subjects
- Humans, Global Health, Health Policy, Research Report, Climate Change, Fossil Fuels
- Abstract
Competing Interests: Declaration of interests CD was supported by the UK Natural Environment Research Council (NE/R010811/1) and the UK Natural Environment Research Council Independent Research Fellowship (NE/N01524X/1) and contributes to the Sustainable and Healthy Food Systems project supported by the Wellcome Trust (205200/Z/16/Z). MD was supported by the Wellcome Trust's Complex Urban Systems for Sustainability and Health (CUSSH) project (209387/Z/17/Z). YL was supported by the US National Aeronautics and Space Administration Applied Sciences Program (80NSSC21K0507). RL was supported by a Royal Society Dorothy Hodgkin Fellowship. MSo was supported by Horizon 2020 project EXHAUSTION (820655) and Academy of Finland HEATCOST (334798). SHG and JKWL were supported by Singapore's National Research Foundation, Singapore's Prime Minister's Office, under its Campus for Research Excellence and Technological Enterprise programme. IH was supported by the UK Research and Innovation (UKRI) Engineering and Physical Sciences Research Council Centre for Research in Energy Demand Solutions (EP/R035288/1) and UKRI APEx (NE/T001887/1). JM was supported by the German Ministry for Education and Research (01LA1826A and 03SFK5J0). ML was supported by the Sloan Foundation. All other authors declare no competing interests.
- Published
- 2022
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42. Climate change impacts on water sustainability of South African crop production.
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Bonetti S, Sutanudjaja EH, Mabhaudhi T, Slotow R, and Dalin C
- Abstract
Agricultural production in arid and semi-arid regions is particularly vulnerable to climate change, which, combined with projected food requirements, makes the sustainable management of water resources critical to ensure national and global food security. Using South Africa as an example, we map the spatial distribution of water use by seventeen major crops under current and future climate scenarios, and assess their sustainability in terms of water resources, using the water debt repayment time indicator. We find high water debts, indicating unsustainable production, for potatoes, pulses, grapes, cotton, rice, and wheat due to irrigation in arid areas. Climate change scenarios suggest an intensification of such pressure on water resources, especially in regions already vulnerable, with a country-scale increase in irrigation demand of between 6.5% and 32% by 2090. Future land use planning and management should carefully consider the spatial distribution and local sustainability of crop water requirements to reduce water consumption in water risk hotspots and guarantee long-term food security., (© 2022 The Author(s). Published by IOP Publishing Ltd.)
- Published
- 2022
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43. The 2021 report of the Lancet Countdown on health and climate change: code red for a healthy future.
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Romanello M, McGushin A, Di Napoli C, Drummond P, Hughes N, Jamart L, Kennard H, Lampard P, Solano Rodriguez B, Arnell N, Ayeb-Karlsson S, Belesova K, Cai W, Campbell-Lendrum D, Capstick S, Chambers J, Chu L, Ciampi L, Dalin C, Dasandi N, Dasgupta S, Davies M, Dominguez-Salas P, Dubrow R, Ebi KL, Eckelman M, Ekins P, Escobar LE, Georgeson L, Grace D, Graham H, Gunther SH, Hartinger S, He K, Heaviside C, Hess J, Hsu SC, Jankin S, Jimenez MP, Kelman I, Kiesewetter G, Kinney PL, Kjellstrom T, Kniveton D, Lee JKW, Lemke B, Liu Y, Liu Z, Lott M, Lowe R, Martinez-Urtaza J, Maslin M, McAllister L, McMichael C, Mi Z, Milner J, Minor K, Mohajeri N, Moradi-Lakeh M, Morrissey K, Munzert S, Murray KA, Neville T, Nilsson M, Obradovich N, Sewe MO, Oreszczyn T, Otto M, Owfi F, Pearman O, Pencheon D, Rabbaniha M, Robinson E, Rocklöv J, Salas RN, Semenza JC, Sherman J, Shi L, Springmann M, Tabatabaei M, Taylor J, Trinanes J, Shumake-Guillemot J, Vu B, Wagner F, Wilkinson P, Winning M, Yglesias M, Zhang S, Gong P, Montgomery H, Costello A, and Hamilton I
- Subjects
- Forecasting, Health Planning, Humans, Renewable Energy, Climate Change, Global Health trends
- Abstract
Competing Interests: Declaration of interests We declare no competing interests.
- Published
- 2021
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44. Correction: Multi-criteria suitability analysis for neglected and underutilised crop species in South Africa.
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Mugiyo H, Chimonyo VGP, Sibanda M, Kunz R, Nhamo L, Masemola CR, Dalin C, Modi AT, and Mabhaudhi T
- Abstract
[This corrects the article DOI: 10.1371/journal.pone.0244734.].
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- 2021
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45. Multi-criteria suitability analysis for neglected and underutilised crop species in South Africa.
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Mugiyo H, Chimonyo VGP, Sibanda M, Kunz R, Nhamo L, Masemola CR, Dalin C, Modi AT, and Mabhaudhi T
- Subjects
- Amaranthus growth & development, Climate Change, Colocasia growth & development, Sorghum growth & development, South Africa, Sustainable Development, Vigna growth & development, Agriculture methods, Crops, Agricultural growth & development
- Abstract
Several neglected and underutilised species (NUS) provide solutions to climate change and creating a Zero Hunger world, the Sustainable Development Goal 2. Several NUS are drought and heat stress-tolerant, making them ideal for improving marginalised cropping systems in drought-prone areas. However, owing to their status as NUS, current crop suitability maps do not include them as part of the crop choices. This study aimed to develop land suitability maps for selected NUS [sorghum, (Sorghum bicolor), cowpea (Vigna unguiculata), amaranth and taro (Colocasia esculenta)] using Analytic Hierarchy Process (AHP) in ArcGIS. Multidisciplinary factors from climatic, soil and landscape, socio-economic and technical indicators overlaid using Weighted Overlay Analysis. Validation was done through field visits, and area under the curve (AUC) was used to measure AHP model performance. The results indicated that sorghum was highly suitable (S1) = 2%, moderately suitable (S2) = 61%, marginally suitable (S3) = 33%, and unsuitable (N1) = 4%, cowpea S1 = 3%, S2 = 56%, S3 = 39%, N1 = 2%, amaranth S1 = 8%, S2 = 81%, S3 = 11%, and taro S1 = 0.4%, S2 = 28%, S3 = 64%, N1 = 7%, of calculated arable land of SA (12 655 859 ha). Overall, the validation showed that the mapping exercises exhibited a high degree of accuracies (i.e. sorghum AUC = 0.87, cowpea AUC = 0.88, amaranth AUC = 0.95 and taro AUC = 0.82). Rainfall was the most critical variable and criteria with the highest impact on land suitability of the NUS. Results of this study suggest that South Africa has a huge potential for NUS production. The maps developed can contribute to evidence-based and site-specific recommendations for NUS and their mainstreaming. Also, the maps can be used to design appropriate production guidelines and to support existing policy frameworks which advocate for sustainable intensification of marginalised cropping systems through increased crop diversity and the use of stress-tolerant food crops., Competing Interests: We don’t have authors with competing interest.
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- 2021
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46. The 2020 report of The Lancet Countdown on health and climate change: responding to converging crises.
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Watts N, Amann M, Arnell N, Ayeb-Karlsson S, Beagley J, Belesova K, Boykoff M, Byass P, Cai W, Campbell-Lendrum D, Capstick S, Chambers J, Coleman S, Dalin C, Daly M, Dasandi N, Dasgupta S, Davies M, Di Napoli C, Dominguez-Salas P, Drummond P, Dubrow R, Ebi KL, Eckelman M, Ekins P, Escobar LE, Georgeson L, Golder S, Grace D, Graham H, Haggar P, Hamilton I, Hartinger S, Hess J, Hsu SC, Hughes N, Jankin Mikhaylov S, Jimenez MP, Kelman I, Kennard H, Kiesewetter G, Kinney PL, Kjellstrom T, Kniveton D, Lampard P, Lemke B, Liu Y, Liu Z, Lott M, Lowe R, Martinez-Urtaza J, Maslin M, McAllister L, McGushin A, McMichael C, Milner J, Moradi-Lakeh M, Morrissey K, Munzert S, Murray KA, Neville T, Nilsson M, Sewe MO, Oreszczyn T, Otto M, Owfi F, Pearman O, Pencheon D, Quinn R, Rabbaniha M, Robinson E, Rocklöv J, Romanello M, Semenza JC, Sherman J, Shi L, Springmann M, Tabatabaei M, Taylor J, Triñanes J, Shumake-Guillemot J, Vu B, Wilkinson P, Winning M, Gong P, Montgomery H, and Costello A
- Subjects
- Conservation of Natural Resources trends, Health Policy, Humans, International Cooperation, Pandemics, SARS-CoV-2, COVID-19, Climate Change, Extreme Weather, Global Health
- Abstract
Translations: For the Chinese, French, German, and Spanish translations of the abstract see Supplementary Materials section., (Copyright © 2021 Elsevier Ltd. All rights reserved.)
- Published
- 2021
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47. Trading water: virtual water flows through interstate cereal trade in India.
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Harris F, Dalin C, Cuevas S, Lakshmikantha NR, Adhya T, Joy EJM, Scheelbeek PFD, Kayatz B, Nicholas O, Shankar B, Dangour AD, and Green R
- Abstract
Cereals are an important component of the Indian diet, providing 47% of the daily dietary energy intake. Dwindling groundwater reserves in India especially in major cereal-growing regions are an increasing challenge to national food supply. An improved understanding of interstate cereal trade can help to identify potential risks to national food security. Here, we quantify the trade between Indian states of five major cereals and the associated trade in virtual (or embedded) water. To do this, we modelled interstate trade of cereals using Indian government data on supply and demand; calculated virtual water use of domestic cereal production using state- and product-specific water footprints and state-level data on irrigation source; and incorporated virtual water used in the production of internationally-imported cereals using country-specific water footprints. We estimate that 40% (94 million tonnes) of total cereal food supply was traded between Indian states in 2011-12, corresponding to a trade of 54.0 km
3 of embedded blue water, and 99.4 km3 of embedded green water. Of the cereals traded within India, 41% were produced in states with over-exploited groundwater reserves (defined according to the Central Ground Water Board) and a further 21% in states with critically depleting groundwater reserves. Our analysis indicates a high dependency of Indian cereal consumption on production in states with stressed groundwater reserves. Substantial changes in agricultural practices and land use may be required to secure future production, trade and availability of cereals in India. Diversifying production systems could increase the resilience of India's food system., Competing Interests: Competing Interest Declaration: The authors declare no competing interests.- Published
- 2020
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48. Environmental footprint family to address local to planetary sustainability and deliver on the SDGs.
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Vanham D, Leip A, Galli A, Kastner T, Bruckner M, Uwizeye A, van Dijk K, Ercin E, Dalin C, Brandão M, Bastianoni S, Fang K, Leach A, Chapagain A, Van der Velde M, Sala S, Pant R, Mancini L, Monforti-Ferrario F, Carmona-Garcia G, Marques A, Weiss F, and Hoekstra AY
- Abstract
The number of publications on environmental footprint indicators has been growing rapidly, but with limited efforts to integrate different footprints into a coherent framework. Such integration is important for comprehensive understanding of environmental issues, policy formulation and assessment of trade-offs between different environmental concerns. Here, we systematize published footprint studies and define a family of footprints that can be used for the assessment of environmental sustainability. We identify overlaps between different footprints and analyse how they relate to the nine planetary boundaries and visualize the crucial information they provide for local and planetary sustainability. In addition, we assess how the footprint family delivers on measuring progress towards Sustainable Development Goals (SDGs), considering its ability to quantify environmental pressures along the supply chain and relating them to the water-energy-food-ecosystem (WEFE) nexus and ecosystem services. We argue that the footprint family is a flexible framework where particular members can be included or excluded according to the context or area of concern. Our paper is based upon a recent workshop bringing together global leading experts on existing environmental footprint indicators., (Copyright © 2019 The Authors. Published by Elsevier B.V. All rights reserved.)
- Published
- 2019
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49. The 2019 report of The Lancet Countdown on health and climate change: ensuring that the health of a child born today is not defined by a changing climate.
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Watts N, Amann M, Arnell N, Ayeb-Karlsson S, Belesova K, Boykoff M, Byass P, Cai W, Campbell-Lendrum D, Capstick S, Chambers J, Dalin C, Daly M, Dasandi N, Davies M, Drummond P, Dubrow R, Ebi KL, Eckelman M, Ekins P, Escobar LE, Fernandez Montoya L, Georgeson L, Graham H, Haggar P, Hamilton I, Hartinger S, Hess J, Kelman I, Kiesewetter G, Kjellstrom T, Kniveton D, Lemke B, Liu Y, Lott M, Lowe R, Sewe MO, Martinez-Urtaza J, Maslin M, McAllister L, McGushin A, Jankin Mikhaylov S, Milner J, Moradi-Lakeh M, Morrissey K, Murray K, Munzert S, Nilsson M, Neville T, Oreszczyn T, Owfi F, Pearman O, Pencheon D, Phung D, Pye S, Quinn R, Rabbaniha M, Robinson E, Rocklöv J, Semenza JC, Sherman J, Shumake-Guillemot J, Tabatabaei M, Taylor J, Trinanes J, Wilkinson P, Costello A, Gong P, and Montgomery H
- Subjects
- Communicable Diseases epidemiology, Conservation of Natural Resources, Delivery of Health Care methods, Extreme Heat adverse effects, Food Supply statistics & numerical data, Health Policy, Humans, International Cooperation, Malnutrition epidemiology, Weather, Child Health, Climate Change, Global Health
- Published
- 2019
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50. "More crop per drop": Exploring India's cereal water use since 2005.
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Kayatz B, Harris F, Hillier J, Adhya T, Dalin C, Nayak D, Green RF, Smith P, and Dangour AD
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- Agriculture statistics & numerical data, Conservation of Water Resources statistics & numerical data, Crops, Agricultural, Fertilizers, India, Millets, Oryza, Sorghum, Triticum, Zea mays, Agriculture methods, Edible Grain growth & development, Water Resources supply & distribution, Water Supply statistics & numerical data
- Abstract
India has the highest national freshwater demand globally and 91% of India's freshwater is used in the agriculture sector. Cereals account for over 50% of the dietary water footprint in India and represent a potential opportunity for reducing water use in Indian agriculture. This study combines governmental production and irrigation statistics with crop distribution maps to examine trends in annual water use for cereal production in India between 2005 and 2014. A new online water assessment tool, Cool Farm Tool Water (CFTW), was used to calculate water use and derive seasonal state-level blue and green water footprints for rice, wheat, sorghum, millet and maize. The analysis indicates that India achieved 26.4% increased total cereal production between 2005 and 2014 without additional water or land use. Cereal water footprints have declined due to higher yields for most crops and slightly lower rates of evapotranspiration. There has also been a shift in the area under production away from the Kharif (monsoon) towards the Rabi (dry) season in which total water footprints for all cereals except rice are substantially lower (-33.4% to -45.0% compared to Kharif), but show a significantly higher dependency on ground and surface water. The value of this study is two-fold. First, it provides a full assessment of production trends for the five major cereals in India for each year from 2005 to 2014 and links it to water use. Secondly, it uses updated seasonal water footprints, which demonstrate the potential for changes in cereal production practices to contribute to improved efficiency of water use in India. Future pressures on scarce water resources may encourage transition to cereals with lower irrigation dependency, in particular maize, but also sorghum and millet. In addition, increased emphasis on improving millet and sorghum yields would be of benefit to secure cereal production and reduce its overall water footprint., (Copyright © 2019 The Authors. Published by Elsevier B.V. All rights reserved.)
- Published
- 2019
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