Basal bud banks are the primary determinants of survival in woody legume seedlings after clipping
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[1] S. Archibald,et al. Browsing is a strong filter for savanna tree seedlings in their first growing season , 2021, Journal of Ecology.
[2] S. Mensah,et al. Factors affecting survival of seedling of Afzelia africana, a threatened tropical timber species in West Africa , 2021, Tropical Ecology.
[3] S. Archibald,et al. What drives grassland‐forest boundaries? Assessing fire and frost effects on tree seedling survival and architecture , 2020, Ecology and evolution.
[4] Stuart Demmer,et al. Vachellia sieberiana var. woodii, a high-altitude encroacher: the effect of fire, frost, simulated grazing and altitude in north-western KwaZulu-Natal, South Africa , 2019 .
[5] F. Schweingruber,et al. Handbook of standardized protocols for collecting plant modularity traits , 2019, Perspectives in Plant Ecology, Evolution and Systematics.
[6] W. Bond,et al. Human impacts in African savannas are mediated by plant functional traits. , 2018, The New phytologist.
[7] Susana Paula,et al. Unearthing belowground bud banks in fire-prone ecosystems. , 2018, The New phytologist.
[8] Dirk Eddelbuettel,et al. Extending R with C++: A Brief Introduction to Rcpp , 2018, PeerJ Prepr..
[9] W. Bond,et al. Fire frequency filters species by bark traits in a savanna–forest mosaic , 2017 .
[10] Anabelle W. Cardoso,et al. Winners and losers: tropical forest tree seedling survival across a West African forest–savanna transition , 2016, Ecology and evolution.
[11] S. Archibald,et al. A continent-wide assessment of the form and intensity of large mammal herbivory in Africa , 2015, Science.
[12] W. Bond,et al. Bud protection: a key trait for species sorting in a forest-savanna mosaic. , 2015, The New phytologist.
[13] A. Staver,et al. Fire alters ecosystem carbon and nutrients but not plant nutrient stoichiometry or composition in tropical savanna , 2015 .
[14] W. Bond,et al. Is there a ‘browse trap’? Dynamics of herbivore impacts on trees and grasses in an African savanna , 2014 .
[15] Pierre Hiernaux,et al. Savanna Vegetation-Fire-Climate Relationships Differ Among Continents , 2014, Science.
[16] Dirk Eddelbuettel,et al. Seamless R and C++ Integration with Rcpp , 2013 .
[17] R. Bradstock,et al. Defining pyromes and global syndromes of fire regimes , 2013, Proceedings of the National Academy of Sciences.
[18] Daniel J. Murphy,et al. Legume phylogeny and classification in the 21st century: Progress, prospects and lessons for other species-rich clades , 2013 .
[19] Sophia Rabe-Hesketh,et al. A Nondegenerate Penalized Likelihood Estimator for Variance Parameters in Multilevel Models , 2013, Psychometrika.
[20] W. Bond,et al. Top-down determinants of niche structure and adaptation among African Acacias. , 2012, Ecology letters.
[21] W. Bond,et al. Deciphering the distribution of the savanna biome. , 2011, The New phytologist.
[22] Dirk Eddelbuettel,et al. Rcpp: Seamless R and C++ Integration , 2011 .
[23] W. Bond,et al. Browsing and fire interact to suppress tree density in an African savanna. , 2009, Ecological applications : a publication of the Ecological Society of America.
[24] W. Bond,et al. Sapling survival in a frequently burnt savanna: mobilisation of carbon reserves in Acacia karroo , 2009, Plant Ecology.
[25] S. Gotsch,et al. Tree topkill, not mortality, governs the dynamics of savanna-forest boundaries under frequent fire in central Brazil. , 2009, Ecology.
[26] W. Bond,et al. Juggling carbon: allocation patterns of a dominant tree in a fire-prone savanna , 2009, Oecologia.
[27] Douglas Ward,et al. Drought‐induced tree death in savanna , 2009 .
[28] R. Julliard,et al. Establishment and early persistence of tree seedlings in an annually burned savanna , 2008 .
[29] J. Fisher. Anatomy of axis contraction in seedlings from a fire prone habitat. , 2008, American journal of botany.
[30] J. D. du Toit,et al. Responses of woody saplings exposed to chronic mammalian herbivory in an African savanna , 2008 .
[31] J. Midgley,et al. Fire induced stem death in an African acacia is not caused by canopy scorching , 2006 .
[32] R. Holdo. Tree growth in an African woodland savanna affected by disturbance , 2006 .
[33] W. Bond,et al. Growing tall vs growing wide: tree architecture and allometry of Acacia karroo in forest, savanna, and arid environments , 2003 .
[34] R. Ostfeld,et al. Herbivory on Acacia seedlings in an East African savanna , 2002 .
[35] W. Bond,et al. A synthesis of the demography of African acacias , 2001, Journal of Tropical Ecology.
[36] S. Higgins,et al. Fire, resprouting and variability: a recipe for grass–tree coexistence in savanna , 2000 .
[37] Jean Clobert,et al. Alternative fire resistance strategies in savanna trees , 1997, Oecologia.
[38] J. Gowda. Spines of Acacia tortilis: what do they defend and how? , 1996 .
[39] N. Owen‐Smith,et al. Effects of plant spinescence on large mammalian herbivores , 1986, Oecologia.
[40] W. Bond,et al. Corrigendum to: A handbook for the standardised sampling of plant functional traits in disturbance-prone ecosystems, with a focus on open ecosystems , 2020, Australian Journal of Botany.
[41] Wolfgang Schwanghart,et al. Spatial bias in the GBIF database and its effect on modeling species' geographic distributions , 2014, Ecol. Informatics.
[42] N. Ursino. Hydrological Minimal Model for Savanna Fire Frequency Assessment , 2013 .