Articles
(* denotes undergraduate students)
2020
45) Browne M, Yardimci NT, Scoffoni C, Jarrahi M, Sack L. 2020. Prediction of leaf water potential and relative water content using terahertz radiation spectroscopy. Plant Direct, in press.
44) Halbritter AH, De Boeck HJ, Eycott AE, Reinsch S, Robinson DA, Vicca S, Berauer B, Christiansen CT, Estiarte M, Grünzweig JM, Gya R, Hansen K, Jentsch A, Lee H, Linder S, Marshall J, Peñuelas J, Schmidt IK, Stuart-Haënthens E, Wilfahrt P, the ClimMani Working Group (including Scoffoni C), Vandvik V. 2020. The handbook for standardised field and laboratory measurements in terrestrial climate-change experiments and observational studies. Methods in Ecology and Evolution, in press.
44) Halbritter AH, De Boeck HJ, Eycott AE, Reinsch S, Robinson DA, Vicca S, Berauer B, Christiansen CT, Estiarte M, Grünzweig JM, Gya R, Hansen K, Jentsch A, Lee H, Linder S, Marshall J, Peñuelas J, Schmidt IK, Stuart-Haënthens E, Wilfahrt P, the ClimMani Working Group (including Scoffoni C), Vandvik V. 2020. The handbook for standardised field and laboratory measurements in terrestrial climate-change experiments and observational studies. Methods in Ecology and Evolution, in press.
2019
43) Henry C, John GP, Pan R, Bartlett MK, Fletcher LR, Scoffoni C, Sack L. 2019. A stomatal safety-efficiency trade-off constrains responses to leaf dehydration. Nature Communications 10, 3398.
42) Emery N, Hund A, Burks R, Duffy M, Scoffoni C, Swei A. 2019. Students as ecologists: Strategies for successful mentorship of undergraduate researchers. Ecology and Evolution, 9 (8): 4316-4326
41) Trueba S, Pan R, Scoffoni C, John GP, Davis S, Sack L. 2019. Thresholds for leaf damage due to dehydration: declines of hydraulic function, stomatal conductance and cellular integrity precede those for photochemistry. New Phytologist, 223, 134-149
40) Méndez-Alonzo R, Ewers F.W., Jacobsen A.L., Pratt B.R., Scoffoni C, Bartlett M.K., Sack L. 2019. Covariation between leaf hydraulics and biomechanics is driven by leaf density in Mediterranean shrubs. Trees Structure-Function. 33, 507-519
39) Earles J.M., Buckley T.N., Brodersen C.R., Busch F.A, Cano F.J., Choat B., Evans J.R., Farquhar G.D., Harwood R., Huynh M., John G.P., Miller M.L., Rockwell F.E., Sack L., Scoffoni C., Struik P.C., Wu A., Yin X., Barbour M.M. 2018. Embracing 3D complexity in leaf carbon-water exchange. Trends of Plant Science, 15-24
38) Medeiros C., Scoffoni C., John G.P., Bartlett M.K., Inman-Narahari F., Ostertag R., Cordell S., Giardina C., Sack L. 2018. Mechanistic traits distinguish Hawaiian wet and dry forests and enable strong prediction of species relative growth rates. Functional Ecology, 33, 712-734
42) Emery N, Hund A, Burks R, Duffy M, Scoffoni C, Swei A. 2019. Students as ecologists: Strategies for successful mentorship of undergraduate researchers. Ecology and Evolution, 9 (8): 4316-4326
41) Trueba S, Pan R, Scoffoni C, John GP, Davis S, Sack L. 2019. Thresholds for leaf damage due to dehydration: declines of hydraulic function, stomatal conductance and cellular integrity precede those for photochemistry. New Phytologist, 223, 134-149
40) Méndez-Alonzo R, Ewers F.W., Jacobsen A.L., Pratt B.R., Scoffoni C, Bartlett M.K., Sack L. 2019. Covariation between leaf hydraulics and biomechanics is driven by leaf density in Mediterranean shrubs. Trees Structure-Function. 33, 507-519
39) Earles J.M., Buckley T.N., Brodersen C.R., Busch F.A, Cano F.J., Choat B., Evans J.R., Farquhar G.D., Harwood R., Huynh M., John G.P., Miller M.L., Rockwell F.E., Sack L., Scoffoni C., Struik P.C., Wu A., Yin X., Barbour M.M. 2018. Embracing 3D complexity in leaf carbon-water exchange. Trends of Plant Science, 15-24
- Recommendation by Jaume Flexas and Marc Carriqui, 2019. Faculty of 1000.
38) Medeiros C., Scoffoni C., John G.P., Bartlett M.K., Inman-Narahari F., Ostertag R., Cordell S., Giardina C., Sack L. 2018. Mechanistic traits distinguish Hawaiian wet and dry forests and enable strong prediction of species relative growth rates. Functional Ecology, 33, 712-734
2018
37) Scoffoni C, Albuquerque C, Cochard H, Buckley T.N., Fletcher L.R., Bartlett M.K., Caringella M.A., Brodersen C.R., Jansen S, McElrone A.J., Sack L. 2018. Control of gas-exchange by leaf outside-xylem hydraulic conductance in Arabidopsis thaliana. Accepted in Plant Physiology
36) Klepsch M., Zhang Y., Kotowska M.M., Lamarque L.J., Nolf M., Schuldt B., Torres-Ruiz J.M., Qin D.W., Choat B., Delzon S., Scoffoni C., Cao K.F., Jansen S. 2018. Is xylem of angiosperm leaves less resistant to embolism than branches? Insights from microCT, hydraulics, and anatomy. Journal of Experimental Botany, ery231
35) Fletcher L, Cui H, Callahan H, Scoffoni C, John G, Bartlett M, Burge D, Sack L. 2018. Evolution of leaf structure and drought tolerance in species of Californian Ceanothus. American Journal of Botany, 105(10): 1672-1687.
36) Klepsch M., Zhang Y., Kotowska M.M., Lamarque L.J., Nolf M., Schuldt B., Torres-Ruiz J.M., Qin D.W., Choat B., Delzon S., Scoffoni C., Cao K.F., Jansen S. 2018. Is xylem of angiosperm leaves less resistant to embolism than branches? Insights from microCT, hydraulics, and anatomy. Journal of Experimental Botany, ery231
35) Fletcher L, Cui H, Callahan H, Scoffoni C, John G, Bartlett M, Burge D, Sack L. 2018. Evolution of leaf structure and drought tolerance in species of Californian Ceanothus. American Journal of Botany, 105(10): 1672-1687.
2017
34) Scoffoni C, Sack L. 2017. Darwin Review. The causes and consequences of leaf hydraulic decline with dehydration. Journal of Experimental Botany, 68: 4479–4496. PDF
33) Scoffoni C, John GP, Cochard H, Sack L. 2017. Testing for ion-mediated enhancement of the hydraulic conductance of the leaf xylem in diverse angiosperms. Journal of Plant Hydraulics, 4, e-004. PDF
32) Buckley TN, John GP, Scoffoni C, Sack L. 2017. The sites of evaporation within leaves. Plant Physiology, 173: 1763-1782. PDF
31) John GP, Scoffoni C, Buckley TN, Villar R, Poorter H, Sack L. 2017. The anatomical and compositional basis of leaf mass per area. Ecology Letters, 20: 412–425. PDF
30) Scoffoni C, Albuquerque C, Brodersen C, Townes S*, John GP, Bartlett MK, Buckley TN, McElrone AJ, Sack L. 2017. Outside-xylem vulnerability, not xylem embolism, controls leaf hydraulic decline during dehydration. Plant Physiology, 173: 1197-1210. PDF
29) Scoffoni C, Albuquerque C, Brodersen C, Townes S*, John GP, Cochard H, Buckley TN, McElrone AJ, Sack L. 2017. Leaf vein xylem conduit diameter influences susceptibility to embolism and hydraulic decline. New Phytologist, 213: 1076–1092. PDF
33) Scoffoni C, John GP, Cochard H, Sack L. 2017. Testing for ion-mediated enhancement of the hydraulic conductance of the leaf xylem in diverse angiosperms. Journal of Plant Hydraulics, 4, e-004. PDF
32) Buckley TN, John GP, Scoffoni C, Sack L. 2017. The sites of evaporation within leaves. Plant Physiology, 173: 1763-1782. PDF
31) John GP, Scoffoni C, Buckley TN, Villar R, Poorter H, Sack L. 2017. The anatomical and compositional basis of leaf mass per area. Ecology Letters, 20: 412–425. PDF
30) Scoffoni C, Albuquerque C, Brodersen C, Townes S*, John GP, Bartlett MK, Buckley TN, McElrone AJ, Sack L. 2017. Outside-xylem vulnerability, not xylem embolism, controls leaf hydraulic decline during dehydration. Plant Physiology, 173: 1197-1210. PDF
29) Scoffoni C, Albuquerque C, Brodersen C, Townes S*, John GP, Cochard H, Buckley TN, McElrone AJ, Sack L. 2017. Leaf vein xylem conduit diameter influences susceptibility to embolism and hydraulic decline. New Phytologist, 213: 1076–1092. PDF
2016
28) Scoffoni C, Jansen S (2016). I can see clearly now― embolism in leaf veins. Trends in Plant Sciences. 21: 723-725. PDF
27) Scoffoni C, Chatelet D, Pasquet-Kok J*, Rawls M*, Donoghue M, Edwards E, Sack L. 2016. Hydraulic basis for the evolution of photosynthetic productivity. Nature Plants. 16072. PDF
26) Sack L, Buckley T, Scoffoni C. 2016. Insight. Why are leaves hydraulically vulnerable? Journal of Experimental Botany, 67 (17): 4917-4919. PDF
25) Sack L, Ball MC, Brodersen C, Davis SD, Des Marais DL, Donovan LA, Givnish TJ, Hacke UG, Huxman T, Jansen S, Jacobsen AL, Johnson D, Koch GW, Maurel C, McCulloh K, McDowell NG, McElrone A, Meinzer FC, Melcher PJ, North G, Pellegrini M, Pockman WT, Pratt RB, Sala A, Santiago LS, Savage JA, Scoffoni C, Sevanto S, Sperry J, Tyerman SD, Way D, Holbrook NM. 2016. Plant hydraulics as a hub integrating plant and ecosystem function. Plant, Cell & Environment, 39:2085–2094. PDF
27) Scoffoni C, Chatelet D, Pasquet-Kok J*, Rawls M*, Donoghue M, Edwards E, Sack L. 2016. Hydraulic basis for the evolution of photosynthetic productivity. Nature Plants. 16072. PDF
26) Sack L, Buckley T, Scoffoni C. 2016. Insight. Why are leaves hydraulically vulnerable? Journal of Experimental Botany, 67 (17): 4917-4919. PDF
25) Sack L, Ball MC, Brodersen C, Davis SD, Des Marais DL, Donovan LA, Givnish TJ, Hacke UG, Huxman T, Jansen S, Jacobsen AL, Johnson D, Koch GW, Maurel C, McCulloh K, McDowell NG, McElrone A, Meinzer FC, Melcher PJ, North G, Pellegrini M, Pockman WT, Pratt RB, Sala A, Santiago LS, Savage JA, Scoffoni C, Sevanto S, Sperry J, Tyerman SD, Way D, Holbrook NM. 2016. Plant hydraulics as a hub integrating plant and ecosystem function. Plant, Cell & Environment, 39:2085–2094. PDF
2015
24) Scoffoni C, Kunkle J, Pasquet-Kok J*, Vuong C*, Patel AJ*, Montgomery R, Givnish TJ, Sack L. 2015. Light induced plasticity in leaf hydraulics, anatomy and gas exchange in ecologically diverse Hawaiian lobeliads. New Phytologist. 207: 43-58. PDF
23) Scoffoni C, Sack L. 2015. Are leaves “freewheelin’”? Testing for a Wheeler-type effect in leaf xylem hydraulic decline. Plant, Cell and Environment. 38: 534-543. PDF
22) Scoffoni C. 2015. Modelling the outside-xylem hydraulic conductance: towards a new understanding of leaf water relations. Plant, Cell and Environment. 38: 4-6. PDF
21) Sack L, Scoffoni C, Johnson DM, Buckley TN, Brodribb TJ. 2015. The anatomical determinants of leaf hydraulic function. In Functional and Ecological Xylem Anatomy, pp. 255-271. Ed. UG Hacke. Springer, New York. PDF
20) Buckley TN, John GP, Scoffoni C, Sack L. 2015. How does leaf anatomy influence water transport outside the xylem? Plant Physiology. 168, 1616-1635. PDF
19) Merkhofer L, Wilf P, Haas MT, Kooyman RM, Sack L, Scoffoni C, Cuneo NR. 2015. Resolving Australian analogs for an Eocene Patagonian paleorainforest using leaf size and floristics. American Journal of Botany. 102, 1160-1173. PDF
23) Scoffoni C, Sack L. 2015. Are leaves “freewheelin’”? Testing for a Wheeler-type effect in leaf xylem hydraulic decline. Plant, Cell and Environment. 38: 534-543. PDF
22) Scoffoni C. 2015. Modelling the outside-xylem hydraulic conductance: towards a new understanding of leaf water relations. Plant, Cell and Environment. 38: 4-6. PDF
21) Sack L, Scoffoni C, Johnson DM, Buckley TN, Brodribb TJ. 2015. The anatomical determinants of leaf hydraulic function. In Functional and Ecological Xylem Anatomy, pp. 255-271. Ed. UG Hacke. Springer, New York. PDF
20) Buckley TN, John GP, Scoffoni C, Sack L. 2015. How does leaf anatomy influence water transport outside the xylem? Plant Physiology. 168, 1616-1635. PDF
19) Merkhofer L, Wilf P, Haas MT, Kooyman RM, Sack L, Scoffoni C, Cuneo NR. 2015. Resolving Australian analogs for an Eocene Patagonian paleorainforest using leaf size and floristics. American Journal of Botany. 102, 1160-1173. PDF
2014
18) Scoffoni C, Vuong C*, Diep S*, Cochard H, Sack L. 2014. Leaf shrinkage with dehydration: coordination with hydraulic vulnerability and drought tolerance. Plant Physiology.164, 1772-1788. PDF
17) Sack L, Scoffoni C, John GP, Poorter H, Mason CM, Mendez-Alonzo R, Donovan LA. 2014. Leaf mass per area is independent of vein length per area: avoiding pitfalls when modeling phenotypic integration (reply to Blonder, Violle, Bentley and Enquist, 2014). Journal of Experimental Botany. 65:5115-5123. PDF
16) Granda A, Scoffoni C, Rubio-Casal AE, Sack L, Valladares F. 2014. Leaf and stem physiological responses to summer and winter extremes of woody species across temperate ecosystem. Oikos. 123:1281-1290. PDF
15) Pivovaroff J, Sharifi R, Scoffoni C, Sack L, Rundel PW. 2014. Making the best of the worst of times: traits underlying combined shade and drought tolerance of Ruscus aculeatus and R. microglossum. Functional Plant Biology. 41: 11-24. PDF
14) Sack L, Caringella M, Scoffoni C, Mason C, Rawls M*, Markesteijn L, Poorter L. 2014. Leaf vein length per unit area is not intrinsically dependent on image magnification: avoiding measurement artifacts for accuracy and precision. Plant Physiology. 166:829-838. PDF
17) Sack L, Scoffoni C, John GP, Poorter H, Mason CM, Mendez-Alonzo R, Donovan LA. 2014. Leaf mass per area is independent of vein length per area: avoiding pitfalls when modeling phenotypic integration (reply to Blonder, Violle, Bentley and Enquist, 2014). Journal of Experimental Botany. 65:5115-5123. PDF
16) Granda A, Scoffoni C, Rubio-Casal AE, Sack L, Valladares F. 2014. Leaf and stem physiological responses to summer and winter extremes of woody species across temperate ecosystem. Oikos. 123:1281-1290. PDF
15) Pivovaroff J, Sharifi R, Scoffoni C, Sack L, Rundel PW. 2014. Making the best of the worst of times: traits underlying combined shade and drought tolerance of Ruscus aculeatus and R. microglossum. Functional Plant Biology. 41: 11-24. PDF
14) Sack L, Caringella M, Scoffoni C, Mason C, Rawls M*, Markesteijn L, Poorter L. 2014. Leaf vein length per unit area is not intrinsically dependent on image magnification: avoiding measurement artifacts for accuracy and precision. Plant Physiology. 166:829-838. PDF
2013
13) Sack L, Scoffoni C. 2013. Tansley Review. Leaf venation: structure, function, development, evolution, ecology and applications in past, present and future. New Phytologist. 198: 983-1000. PDF
12) Sack L, Scoffoni C, John GP, Poorter H, Mason CM, Mendez-Alonzo R, Donovan LA. 2013. How do leaf veins influence the worldwide leaf economic spectrum? Review and synthesis. Journal of Experimental Botany 64: 4053-4080. PDF
11) John GP, Scoffoni C, Sack L. 2013. Allometry of cells and tissues within leaves. American Journal of Botany. 100:1936-1948. PDF
10) Flexas J, Scoffoni C, Gago J, Sack L. 2013. Leaf mesophyll conductance and leaf hydraulic conductance: an introduction to their measurement and coordination. Journal of Experimental Botany 64: 3965-3981. PDF
9) Li S, Zhang YJ, Ishida A, Sack L, Scoffoni C, Chen YJ, Cao KF. 2013. The heterogeneity and spatial patterning of structure and physiology across the leaf surface in giant leaves of Alocasia macrorrhiza. PLoS One. 8, e64502. PDF
12) Sack L, Scoffoni C, John GP, Poorter H, Mason CM, Mendez-Alonzo R, Donovan LA. 2013. How do leaf veins influence the worldwide leaf economic spectrum? Review and synthesis. Journal of Experimental Botany 64: 4053-4080. PDF
11) John GP, Scoffoni C, Sack L. 2013. Allometry of cells and tissues within leaves. American Journal of Botany. 100:1936-1948. PDF
10) Flexas J, Scoffoni C, Gago J, Sack L. 2013. Leaf mesophyll conductance and leaf hydraulic conductance: an introduction to their measurement and coordination. Journal of Experimental Botany 64: 3965-3981. PDF
9) Li S, Zhang YJ, Ishida A, Sack L, Scoffoni C, Chen YJ, Cao KF. 2013. The heterogeneity and spatial patterning of structure and physiology across the leaf surface in giant leaves of Alocasia macrorrhiza. PLoS One. 8, e64502. PDF
2012
8) Scoffoni C, McKown A, Rawls* M, Sack L. 2012. Dynamics of leaf hydraulic conductance with water status: quantification and analysis of species differences under steady-state. Journal of Experimental Botany. 63, 643-658. PDF
7) Bartlett MK, Scoffoni C, Sack L. 2012. The determinants of leaf turgor loss point and prediction of drought tolerance of species and biomes: a global meta-analysis. Ecology Letters. 15, 393-405. PDF
6) Bartlett MK, Scoffoni C, Ardy R*, Zhang Y, Shanwen S, Cao K, Sack L. 2012. Rapid determination of comparative drought tolerance traits: using an osmometer to predict turgor loss point. Methods in Ecology & Evolution. 3: 880-888. PDF
5) Guyot G, Scoffoni C, Sack L. 2012. Combined impacts of irradiance and dehydration on leaf hydraulic conductance: insights into vulnerability and stomatal control. Plant, Cell & Environment. 35, 857-871. PDF
4) Sack L, Scoffoni C, McKown AD, Frole K, Rawls M*, Havran JC, Tran H, Tran S. 2012. Developmentally-based scaling laws for leaf venation architecture explain global patterns. Nature communications. 3, 837. PDF
3) Sack L, Scoffoni C. 2012. Measurement of leaf hydraulic conductance and stomatal conductance and their responses to irradiance and dehydration using the evaporative flux method (EFM). Journal of Visualized Experiments. PDF
7) Bartlett MK, Scoffoni C, Sack L. 2012. The determinants of leaf turgor loss point and prediction of drought tolerance of species and biomes: a global meta-analysis. Ecology Letters. 15, 393-405. PDF
6) Bartlett MK, Scoffoni C, Ardy R*, Zhang Y, Shanwen S, Cao K, Sack L. 2012. Rapid determination of comparative drought tolerance traits: using an osmometer to predict turgor loss point. Methods in Ecology & Evolution. 3: 880-888. PDF
5) Guyot G, Scoffoni C, Sack L. 2012. Combined impacts of irradiance and dehydration on leaf hydraulic conductance: insights into vulnerability and stomatal control. Plant, Cell & Environment. 35, 857-871. PDF
4) Sack L, Scoffoni C, McKown AD, Frole K, Rawls M*, Havran JC, Tran H, Tran S. 2012. Developmentally-based scaling laws for leaf venation architecture explain global patterns. Nature communications. 3, 837. PDF
3) Sack L, Scoffoni C. 2012. Measurement of leaf hydraulic conductance and stomatal conductance and their responses to irradiance and dehydration using the evaporative flux method (EFM). Journal of Visualized Experiments. PDF
2011
2) Scoffoni C, Rawls M*, McKown A, Cochard H, Sack L. 2011. Decline of leaf hydraulic conductance with dehydration: relationship to leaf size and venation architecture. Plant Physiology 156:832-843. PDF; F1000 recommended
- Recommendation by Joseph Craine, 2011, Faculty of 1000.
2008
1) Scoffoni C, Pou A, Aasamaa K, Sack L. 2008. The rapid light response of the leaf hydraulic conductance: new evidence from two experimental methods. Plant, Cell and Environment 13:1803-1812. PDF
Protocols
4) Sack L, Scoffoni C and PrometheusWiki contributors. “PROTOCOL: Minimum epidermal conductance (gmin, a.k.a. cuticular conductance).” PrometheusWiki, 25 Mar. 2011 Web. 09 Oct. 2014. Link
3) Sack L, Bartlett MK, Creese C, Guyot G, Scoffoni C and Prometheus Wiki contributors. “PROTOCOL: Constructing and operating a hydraulics flow meter.” PrometheusWiki, 30 Sept 2011 Web. 09 Oct 2014. Link
2) Sack L, Chatelet DS, Scoffoni C and PrometheusWiki contributors. “PROTOCOL: Estimating the mesophyll surface area per leaf area from leaf cell and tissue dimensions measured from transverse cross-sections.” PrometheusWiki, 28 Jun 2013 Web. 09 Oct 2014. Link
1) Scoffoni C, Sack L and PrometheusWiki contributors. “PROTOCOL: Quantifying leaf vein traits.” PrometheusWiki, 06 Aug. 2013 Web. 09 Oct 2014. Link
3) Sack L, Bartlett MK, Creese C, Guyot G, Scoffoni C and Prometheus Wiki contributors. “PROTOCOL: Constructing and operating a hydraulics flow meter.” PrometheusWiki, 30 Sept 2011 Web. 09 Oct 2014. Link
2) Sack L, Chatelet DS, Scoffoni C and PrometheusWiki contributors. “PROTOCOL: Estimating the mesophyll surface area per leaf area from leaf cell and tissue dimensions measured from transverse cross-sections.” PrometheusWiki, 28 Jun 2013 Web. 09 Oct 2014. Link
1) Scoffoni C, Sack L and PrometheusWiki contributors. “PROTOCOL: Quantifying leaf vein traits.” PrometheusWiki, 06 Aug. 2013 Web. 09 Oct 2014. Link