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Journal articles on the topic 'Grevillea robusta'

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Published: 4 June 2021
Last updated: 20 February 2023

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1

Knight, Timothy E., and Craig D. Whitesell. "Grevillea robusta (Silver-Oak) Dermatitis." American Journal of Contact Dermatitis 3, no. 3 (September 1992): 145–49. http://dx.doi.org/10.1097/01634989-199209000-00007.

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2

Knight, Timothy E., and Craig D. Whitesell. "Grevillea robusta (Silver-Oak) Dermatitis." Dermatitis 3, no. 3 (September 1992): 145–49. http://dx.doi.org/10.1097/01206501-199209000-00007.

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3

Ahmed, Amany S., Norio Nakamura, Meselhy R. Meselhy, Makhboul A. Makhboul, Nasr El-Emary, and Masao Hattori. "Phenolic constituents from Grevillea robusta." Phytochemistry 53, no. 1 (January 2000): 149–54. http://dx.doi.org/10.1016/s0031-9422(99)00484-7.

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4

Wang, Hao, David N. Leach, Paul I. Forster, and Peter G. Waterman. "Secondary metabolites from Grevillea robusta." Biochemical Systematics and Ecology 36, no. 5-6 (May 2008): 452–53. http://dx.doi.org/10.1016/j.bse.2007.10.005.

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5

Trianoski, Rosilani, Arnaldo Barros Rezende Piccardi, Setsuo Iwakiri, Jorge Luis Monteiro de Matos, and Ghislaine Miranda Bonduelle. "Incorporação de Grevillea robusta na Produção de Painéis Aglomerados de Pinus." Floresta e Ambiente 23, no. 2 (January 22, 2016): 278–85. http://dx.doi.org/10.1590/2179-8087.141515.

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Estudos relativos ao potencial tecnológico de espécies alternativas de rápido crescimento são de grande importância, tendo em vista aumentar a oferta de matéria prima para as indústrias de base florestal, especialmente para as indústrias de painéis aglomerados. Neste contexto, este trabalho teve como objetivo avaliar a viabilidade de utilização da Grevillea robusta em diferentes misturas com Pinus taeda para a produção de painéis aglomerados, bem como, estabelecer a quantidade máxima de incorporação desta espécie numa matriz industrial. Os painéis foram produzidos com as espécies puras e em diferentes misturas, com densidade nominal de 0,70 g/cm3 e resina uréia-formaldeído (8%). Os resultados indicaram que o tratamento constituído de 20% Grevillea robusta e 80% de Pinus taeda atendem os requisitos mínimos das propriedades mecânicas segundo a norma EN 312 (além da testemunha) e que a máxima incorporação de madeira de Grevillea robusta numa matriz de Pinus é de 26%.
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6

Iwakiri, Setsuo, Jarbas Shimizu, José de Castro Silva, Cláudio Henrique Soares Del Menezzi, Carlos Augusto Puehringher, Ivan Venson, and Christine Larroca. "Produção de painéis de madeira aglomerada de Grevillea robusta A. Cunn. ex R. Br." Revista Árvore 28, no. 6 (December 2004): 883–87. http://dx.doi.org/10.1590/s0100-67622004000600013.

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Este trabalho teve como objetivo avaliar o comportamento da madeira de Grevillea robusta na produção de painéis de madeira aglomerada. Os painéis foram produzidos em densidades de 0,60 e 0,80 g/cm³ e conteúdo de resina de 6 e 8%. Os resultados de propriedades físicas e mecânicas dos painéis fabricados com densidade de 0,80 g/cm³ e conteúdo de resina de 8% evidenciaram que a madeira de Grevillea robusta pode ser utilizada como fonte alternativa de matéria-prima para produção de painéis aglomerados.
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7

Loewe Muñoz, Verónica Francisca. "Apuntes sobre algunas latifoliadas de maderas valiosas. 4. Grevillea robusta A. Cunn." Ciencia & Investigación Forestal 7, no. 1 (July 7, 1993): 25–104. http://dx.doi.org/10.52904/0718-4646.1993.181.

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Grevillea robusta es un árbol nativo de Australia, descubierto y descrito por el explorador europeo Alan Cunningham en 1827. La especie pertenece a las angiospermas, dicotiledóneas, familia Proteaceae, y es llamada simplemente silky oak, grevillea géant, roble sedoso, silver oak, he-oak, o simplemente grevillea, y su sinónimo es Grevillea umbricata A. Cunn. Esta especie australiana es la más grande de su género, que comprende más de 260 especies, alcanzando alturas de 40 m y diámetros de hasta 1,2 m. La especie ha despertado gran interés, pues se trata de un árbol de fácil adaptación, de rápido crecimiento y con objetivos múltiples. En su región de origen es la especie de mayor resistencia, regenera vigorosamente y coloniza en forma agresiva las áreas alteradas. Para ser un árbol tan grande crece rápidamente y tiene éxito en un amplio rango de condiciones climáticas y edáficas, lo que lo hace de un gran interés. El éxito que ha tenido la especie se debe entre otros factores a su variedad productiva, no quedando excluida de ningún producto o servicio. Principalmente en las áreas bajas y secas, los agricultores han encontrado que la grevillea se reproduce y maneja fácilmente, presenta buenos rendimientos de leña y postes y no compite notoriamente con los cultivos adyacentes.
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8

Ahmed, Amany, and Makboul Makboul. "Chemical investigation of Grevillea robusta A.Cunn flowers." Sphinx Journal of Pharmaceutical and Medical Sciences 2, no. 1 (October 31, 2021): 1–8. http://dx.doi.org/10.21608/sjpms.2021.95637.1000.

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9

Bhandari, Maneesh S., Aman Dabral, Rama Kant Anon, Rajendra K. Meena, and Shailesh Pandey. "Indeterminate flowering in Grevillea robusta: phenological climatic anomaly." Indian Forester 146, no. 7 (July 10, 2020): 668. http://dx.doi.org/10.36808/if/2020/v146i7/154280.

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10

Harwood, C. E., G. F. Moran, and J. C. Bell. "Genetic Differentiation in Natural Populations of Grevillea robusta." Australian Journal of Botany 45, no. 4 (1997): 669. http://dx.doi.org/10.1071/bt96073.

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Genetic variation in 23 natural populations of Grevillea robusta A.Cunn. from across the natural range of the species was examined using 20 isozyme loci assayed in young seedlings. Mean expected heterozygosity per population, He , varied from 0.080 to 0.131 with an average of 0.105. The genetic diversity of individual populations did not appear to be related to their ecological characteristics (araucarian vine forest or riverine habitat types) or their geographic locations. A genetic distance analysis indicated a significant separation of the populations into two regional groups, eight from the northern part of the natural range and the remaining 15 from central and southern areas. Between-population differences accounted for 17.9% of the total genetic variation, one-third of which was attributable to the difference between the two regional groups. Most alleles at the 20 loci occurred across most or all of the geographic range. This, and the low level of genetic differentiation between populations, suggest that genetic exchange between populations has been maintained, despite the pattern of natural distribution of the species in small, separated populations.
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11

Wang, Kui-Wu, Ting-Ting Zhang, and Lei Zhang. "Chemical Constituents and Biological Activities of Grevillea robusta." Chemistry of Natural Compounds 54, no. 1 (January 2018): 153–55. http://dx.doi.org/10.1007/s10600-018-2279-1.

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12

Shadrack Kinyua Inoti and Jemimah Achieng Ocholla. "Manure soil amendment for Grevillea robusta seedlings in the Kenyan highlands." Open Access Research Journal of Life Sciences 4, no. 2 (November 30, 2022): 043–49. http://dx.doi.org/10.53022/oarjls.2022.4.2.0077.

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Grevillea robusta seedlings are of high demand in Kenyan agricultural landscapes especially in agroforestry systems, yet the ideal soil mixture is not identified. This experiment was to determine the ideal potting soil mixture for Grevillea species. A Complete Randomized Design (CRD) with 4 treatments replicated 3 times was employed. Four treatments were used; Forest soil, Agricultural soil, Forest soil + Manure and Agricultural soil + Manure. The experiment was done for 8 months in 2020 at Egerton University tree nursery. Data was collected on seedling survival, height, root and foliage variables. One-way ANOVA was performed on the measured variables using SAS statistical package while the means were separated using LSD at P< 0.05. Results showed that Agricultural soil + Manure was significantly higher (P<0.05) in all the shoot and foliage variables compared with Agricultural soil alone except for internode length. Besides, Agricultural soil + Manure showed similar growth performance with Forest soil alone. However, the former showed significantly higher leaf length (20.2 cm) compared with Forest soil + Manure (14 cm). Results showed that Forest soil and Agricultural soil + Manure had significantly higher (P<0.05) root biomass compared with Agricultural soil (2.77 g), while root collar diameter, root length and root to shoot ratio were similar. It is, therefore, recommended that tree nurseries located far from forests can use a potting soil mixture of Agricultural soil + manure in raising Grevillea seedlings since this gives similar growth performance with forest soil.
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13

Nisgoski, Silvana, Graciela I. B. de Muñiz, and Umberto Klock. "Caracterização anatômica da madeira de Grevillea robusta A. Cunn." Ciência e Natura 20, no. 20 (December 14, 1998): 101. http://dx.doi.org/10.5902/2179460x26820.

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The wood anatomy of Grevillea robusta A. Cunn is described. Photomicrographs e photographs in electronic microscope are furnished. Vessels typicaliy in tangential pairs and groups. Parenchyma typicaliy as narrow to wide bands curving inwards between the large rays. Rays of two distinct sizes, usually homogeneous except for occasional sheath cells. Libriform fibers and not septate. Traumatic vertical intercellular canais occasionally present. Stain pith occasionally were found. The constituent elements were analyzed in function of tree position.
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14

Churms, Shirley C., and Alistair M. Stephen. "Studies of the molecular core of Grevillea robusta gum." Carbohydrate Research 167 (September 1987): 239–55. http://dx.doi.org/10.1016/0008-6215(87)80282-3.

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15

Mantello, Camila, Daiane Kestring, Valderês Sousa, Ananda Aguiar, and Anete Souza. "Development and characterization of microsatellite loci in Grevillea robusta." BMC Proceedings 5, Suppl 7 (2011): P16. http://dx.doi.org/10.1186/1753-6561-5-s7-p16.

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16

Ullah, Md Sharif, Md Al Amin Sikder, Tasnuva Sharmin, and Mohammad A. Rashid. "Pharmacological Activities of Grevillea robusta, a Medicinal Plant of Bangladesh." Bangladesh Pharmaceutical Journal 17, no. 2 (February 21, 2015): 135–37. http://dx.doi.org/10.3329/bpj.v17i2.22329.

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The objective of this study was to evaluate the crude methanol extract of leaf of Grevillea robusta as well as its hexane, carbon tetrachloride, chloroform and aqueous soluble partitionates for cytotoxic, thrombolytic, membrane stabilizing and antimicrobial activities. In the brine shrimp lethality bioassay, the crude methanolic extract of G. robusta leaf revealed the highest cytotoxic activity with LC50 values as 1.50 ± 0.45 ?g/ml as compared to 0.45 ?g/ml for vincristine sulphate. Among the extractives of G. robusta, the carbon tetrachloride soluble fraction showed 69.95±0.11% clot lysis as compared to 70.77% clot lysis by standard streptokinase. At concentration of 1.0 mg/ml, the chloroform soluble fraction inhibited 40.31 ± 0.59% and 62.93 ± 0.73% of haemolysis of RBC induced by heat and hypotonic solution as compared to 42.12% and 71.90% by acetyl salicylic acid, respectively. The test samples also showed antimicrobial activity with zone of inhibition ranging from 7.0 to 17.0 mm in diameter. The chloroform soluble partitionate demonstrated the highest zone of inhibition (17.0 mm) against Salmonella Typhi. DOI: http://dx.doi.org/10.3329/bpj.v17i2.22329 Bangladesh Pharmaceutical Journal 17(2): 135-137, 2014
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17

Santos, M. A. F., S. N. Matsmoto, F. R. C. F. Cesár, J. A. Bonfim, G. S. Araujo, and A. E. S. Viana. "Seed bank from soil of coffee plantations associated with grevillea trees." Planta Daninha 26, no. 4 (2008): 725–33. http://dx.doi.org/10.1590/s0100-83582008000400003.

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This study aimed to study the composition and dynamics of seed bank from soil of coffee plantations associated with grevilea trees in the experimental fields of the Southwest Bahia State University, on Vitória da Conquista campus. The experiments were carried out from September 2006 to May 2007. The coffee trees (Coffea arabica) were sown at three x one m spacing, associated with grevillea trees (Grevillea robusta) and maintained at densities of 277, 139, 123, 69, 62 and 31 plants ha-1, under direct sunlight. One hundred grams of soil were taken from each treatment with four repetitions and later identified and counted with a 10x magnifying glass. To determine seedling emergence, four soil samples of 1000 g were collected from each experimental field and transported to the greenhouse. Seedling emergence was observed by counts after 15, 30 and 45 days. The experimental design was randomized blocks of seven treatments (soil from different tree densities) and four replicates; the experimental unit consisted of a plastic tray (0, 30 x 0.22 x 0.06 m) containing 1.000 g of soil. The variables utilized to characterize the bank and its dynamics were: relative frequency, relative density, relative abundance, importance index and species diversity (Shannon-Weaver index).Increased number of monocotyledon seeds and sprouts were verified in the treatments maintained under full sunlight.
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18

Kalinganire, A., C. E. Harwood, M. U. Slee, and A. J. Simons. "Pollination and fruit-set of Grevillea robusta in western Kenya." Austral Ecology 26, no. 6 (December 2001): 637–48. http://dx.doi.org/10.1046/j.1442-9993.2001.01139.x.

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19

Gardner, Angela. "Poems: The women's room, After the flood, Grevillea robusta, Codon." Journal of Australian Studies 24, no. 64 (January 2000): 120–27. http://dx.doi.org/10.1080/14443050009387563.

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20

Junior, Levi De Souza, Marguerite Quoirin, and Ivar Wendling. "Miniestaquia de Grevillea robusta A. Cunn. a partir de propágulos juvenis." Ciência Florestal 18, no. 4 (December 30, 2008): 455. http://dx.doi.org/10.5902/19805098429.

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O presente estudo teve como objetivo avaliar a sobrevivência e a produtividade de minicepas no sistema de tubetes e o efeito do ácido indolbutírico (AIB) no enraizamento de miniestacas de Grevillea robusta. O experimento foi conduzido em Colombo, PR, com minicepas formadas partindo de mudas obtidas de sementes, as quais foram cultivadas no sistema de tubetes, durante o período de um ano. A sobrevivência das minicepas, após 15 coletas, foi de 100% com produtividade média de 1,7 miniestacas por minicepa e 4030 miniestacas por metro quadrado ao ano. As taxas médias de enraizamento foram 83, 79, 75 e 72% para os tratamentos com 0, 1000, 2000 e 4000 mg L-1 de AIB respectivamente, sendo os melhores níveis obtidos sem aplicação exógena de AIB. Com base nesses resultados, conclui-se que a miniestaquia de propágulos juvenis é uma opção para produção de mudas de Grevillea robusta durante o ano inteiro, sem a necessidade de aplicações de reguladores de crescimento, além de ser uma importante ferramenta para adaptação dos protocolos de propagação vegetativa em materiais adultos selecionados.
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21

Chetana, H. C., and T. Ganesh. "Importance of shade trees (Grevillea robusta) in the dispersal of forest tree species in managed tea plantations of southern Western Ghats, India." Journal of Tropical Ecology 28, no. 2 (February 13, 2012): 187–97. http://dx.doi.org/10.1017/s0266467411000721.

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Abstract:Abandoned plantations of coffee, tea and other commercial crops offer opportunities for understanding ecological processes in modified forest ecosystems. Unlike tree plantations tea is maintained as a shrub with a continuous dense short canopy that precludes large-frugivore activity thereby limiting dispersal of forest species to such areas. In this study we determine how location and density of Grevillea robusta a shade tree in tea plantations and proximity of plantations to forests influences seed arrival from forests into the plantations. We also estimate the importance of dispersal modes in the colonization processes. We laid 10 × 10-m plots at three distance intervals from the forest edge in three different plantation types with varying shade tree densities. Within the plots we laid four 1× 1-m subplots at the corners of the plot. We estimated species richness, abundance and categorized the seeds into dispersal modes in these plots. Grevillea robusta increased species richness of seeds by three times and abundance of seeds by 3–30 times compared with plantations without them. Higher density of G. robusta increased seed input changed species composition and altered species dominance in the plantations. Distance to forests influenced seed arrival in plantations without G. robusta trees and plots 95 m from the forest did not have any seeds in them. No such effect was seen in plantations with G. robusta trees. Seeds dispersed by birds or a combination of birds and mammals contribute 30% of the seeds reaching the plantations with G. robusta and this was not influenced by distance from the forest. In plantations without G. robusta bird dispersal is restricted to 25 m from the forest edge. In general density of shade trees has a strong influence on seed arrival which can negate the forest proximity effect and enhance natural forest colonization.
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22

Martiarena, Rodolfo A., Alejandra Von Wallis, Roberto A. Fernández, and Otto E. Knebel. "EFFECT OF ESTABLISHMENT TECHNIQUE COMBINATIONS ON INITIAL GROWTH OF Grevillea robusta A. Cunn." Revista Chapingo Serie Ciencias Forestales y del Ambiente XIX, no. 3 (December 2013): 387–97. http://dx.doi.org/10.5154/r.rchscfa.2012.07.046.

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23

Oke, D. O., and G. Owoeye . "Early Growth and Nutrient Accumulation of Grevillea robusta A. Cunn. in G. robusta/Maize Intercrop." Journal of Agronomy 4, no. 1 (December 15, 2004): 58–60. http://dx.doi.org/10.3923/ja.2005.58.60.

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24

Owate, Omamo Augustine, Mugo Joseph Mware, and Mwangi James Kinyanjui. "Allometric Equations for Estimating Silk Oak (Grevillea robusta) Biomass in Agricultural Landscapes of Maragua Subcounty, Kenya." International Journal of Forestry Research 2018 (October 2, 2018): 1–14. http://dx.doi.org/10.1155/2018/6495271.

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Grevillea robusta is widely interplanted with crops in Maragua subcounty, a practice that enhances biomass quantities in farmlands. However, quick tools for estimating biomass of such trees are lacking resulting in undervaluation of the farm product. This study sought to develop allometric equations for estimating tree biomass using diameter at breast height (DBH) and tree height as predictor variables. Tree biomass was computed using thirty-three (33) trees randomly selected from 12 one hectare plots established in each of the four agroecological zones (AEZs). DBH of all Grevillea robusta trees per plot was measured and three trees were selected for destructive sampling to cover the variety of tree sizes. Regression analysis was used to develop equations relating DBH/tree height to biomass based on linear, exponential, power, and polynomial functions. The polynomial and the power equations had the highest R2, lowest SEE, and MRE values, while DBH was the most suitable parameter for estimating tree biomass. The tree stem, branches, foliage, and roots biomass comprised 56.89%, 14.11%, 6.67%, and 22.32% of the total tree biomass, respectively. The mean tree biomass density (12.430±1.84 ton ha−1) showed no significant difference (p=0.09) across AEZs implying no difference in G. robusta agroforestry stocks across the AEZ. The allometric equations will support marketing of tree products by farmers and therefore better conservation and management of the tree resource.
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25

Shadrack Kinyua Inoti and Doris Cherop. "Influence of pot size on early seedling growth of Grevillea robusta and Cupressus lusitanica in Kenya." International Journal of Science and Technology Research Archive 4, no. 1 (January 30, 2023): 096–102. http://dx.doi.org/10.53771/ijstra.2023.4.1.0011.

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Pot size is vital for raising of nursery seedlings. Different sizes of pots are needed for various tree species. An experiment was set up to investigate the best pot size for Cupressus lusitanica and Grevillea robusta species. The experiment was laid down as a RCBD with 8 treatments replicated 3 times. Treatments comprised of 4 different pot sizes as follows: large, medium, small and smallest as well as two species. Forest soil mixture was used for potting and 10 pots were used per each treatment per replicate while 7 plants were randomly selected for sampling. The experiment was carried out from September 2017 for a period of 8 months. The variables measured included; shoot, foliage and roots. ANOVA was done using Genstat package while the means were separated at P< 0.001 using LSD. The results showed that large pots had significantly (P<0.001) higher values in height, shoot fresh biomass, total fresh plant biomass and seedling stem volume compared with the other pot sizes. Large pots also showed significantly higher root collar diameter (6.23 mm) compared with the medium pot (4.33 mm). For species, Cypress showed significantly superior height (27.84 cm) and number of leaves (24.52) compared with Grevillea (18.73 and 18.27 cm respectively). In conclusion, shoot fresh biomass and total fresh plant biomass were positively correlated with pot size. This study recommends the use of large pots for raising Grevillea and Cypress seedlings in the nursery since they take 8 months to attain planting size.
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26

Chuang, Ta-Hsien, Hsiu-Hui Chan, Tian-Shung Wu, and Chien-Fu Li. "Chemical Constituents and Biological Studies of the Leaves of Grevillea robusta." Molecules 16, no. 11 (November 7, 2011): 9331–39. http://dx.doi.org/10.3390/molecules16119331.

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27

Aggarwal, Pankaj K., and Shakti S. Chauhan. "Microwave drying of planks of Grevillea robusta A. Cunn. ex R." Journal of the Indian Academy of Wood Science 8, no. 2 (December 2011): 84–88. http://dx.doi.org/10.1007/s13196-012-0050-y.

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28

Yamashita, Yukiko, Katsuyoshi Matsunami, Hideaki Otsuka, Takakazu Shinzato, and Yoshio Takeda. "5-Alkylresorcinol glucosides from the leaves of Grevillea robusta Allan Cunningham." Journal of Natural Medicines 64, no. 4 (May 27, 2010): 474–77. http://dx.doi.org/10.1007/s11418-010-0420-y.

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Kalinganire, A., and John B. Hall. "Growth and biomass production of young Grevillea robusta provenances in Rwanda." Forest Ecology and Management 62, no. 1-4 (December 1993): 73–84. http://dx.doi.org/10.1016/0378-1127(93)90042-l.

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30

Fritzsons, Elenice, Antonio Aparecido Carpanezzi, Marcos Silveira Wrege, and Ananda Virgínia de Aguiar. "Zoneamento climático para a grevílea (Grevillea robusta) para o Estado do Paraná." Pesquisa Florestal Brasileira 30, no. 61 (June 30, 2010): 17–24. http://dx.doi.org/10.4336/2010.pfb.30.61.17.

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31

Ahmed, Amany. "PHYTOCHEMICAL AND BIOLOGICAL STUDY OF GREVILLEA ROBUSTA A. CUNN CULTIVATED IN EGYPT." Bulletin of Pharmaceutical Sciences. Assiut 29, no. 2 (December 31, 2006): 272–88. http://dx.doi.org/10.21608/bfsa.2006.65200.

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32

Nicolson, S. W. "Direct Demonstration of Nectar Reabsorption in the Flowers of Grevillea robusta (Proteaceae)." Functional Ecology 9, no. 4 (August 1995): 584. http://dx.doi.org/10.2307/2390148.

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33

Shailza and H. S. Grewal. "Drying and preservation techniques of foliage of Grevillea robusta and Nephrolepis exaltata." Agricultural Research Journal 55, no. 2 (2018): 383. http://dx.doi.org/10.5958/2395-146x.2018.00072.8.

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34

Parmar, Priyanka, Aman Dabral, R. K. Meena, Shailesh Pandey, Rama Kant, and M. S. Bhandari. "Genetic Diversity Analysis in Grevillea robusta using ISSR Molecular Markers." Indian Forester 145, no. 3 (March 31, 2019): 260. http://dx.doi.org/10.36808/if/2019/v145i3/144477.

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35

Fekadu, Alemu. "Cultivation of Pleurotus ostreatus on Grevillea robusta leaves at Dilla University, Ethiopia." Journal of Yeast and Fungal Research 5, no. 6 (August 11, 2014): 74–83. http://dx.doi.org/10.5897/jyfr2014.0139.

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36

Radomski, Maria Izabel, and Jorge Ribaski. "Fertilidade do solo e produtividade da pastagem em sistema silvipastoril com Grevillea robusta." Pesquisa Florestal Brasileira 32, no. 69 (March 30, 2012): 53–62. http://dx.doi.org/10.4336/2012.pfb.32.69.53.

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37

Patel, Nandita A., and SJ Patil. "Dehydration Techniques for Silver Oak (Grevillea robusta A. Cunn. ex R. Br.) leaves." Journal of Tree Sciences 35, no. 2 (2016): 92. http://dx.doi.org/10.5958/2455-7129.2016.00015.7.

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38

Yamashita, Yukiko, Katsuyoshi Matsunami, Hideaki Otsuka, Takakazu Shinzato, and Yoshio Takeda. "Grevillosides A–F: Glucosides of 5-alkylresorcinol derivatives from leaves of Grevillea robusta." Phytochemistry 69, no. 15 (November 2008): 2749–52. http://dx.doi.org/10.1016/j.phytochem.2008.08.008.

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39

AKYEAMPONG, E., L. HITIMANA, E. TORQUEBIAU, and P. C. MUNYEMANA. "Multistrata Agroforestry with Beans, Bananas and Grevillea robusta in the Highlands of Burundi." Experimental Agriculture 35, no. 3 (July 1999): 357–69. http://dx.doi.org/10.1017/s0014479799003063.

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Santos, Juscelina, Rafaella Curto, Diego Roters, and Paulo Trazzi. "POTENCIAL DE CRESCIMENTO DE Cordia trichotoma E Grevillea robusta EM PLANTIO PURO E CONSORCIADO." Enciclopédia Biosfera 14, no. 26 (December 5, 2017): 523–30. http://dx.doi.org/10.18677/encibio_2017b50.

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41

Dabral, Aman, Arzoo Shamoon, Rajendra K. Meena, Rama Kant, Shailesh Pandey, Harish S. Ginwal, and Maneesh S. Bhandari. "Genome skimming-based simple sequence repeat (SSR) marker discovery and characterization in Grevillea robusta." Physiology and Molecular Biology of Plants 27, no. 7 (July 2021): 1623–38. http://dx.doi.org/10.1007/s12298-021-01035-w.

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42

Lott, J. E., A. A. H. Khan, C. R. Black, and C. K. Ong. "Water use in a Grevillea robusta–maize overstorey agroforestry system in semi-arid Kenya." Forest Ecology and Management 180, no. 1-3 (July 2003): 45–59. http://dx.doi.org/10.1016/s0378-1127(02)00603-5.

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43

Dettmann, Mary E., and David M. Jarzen. "Pollen evidence for Late Cretaceous differentiation of Proteaceae in southern polar forests." Canadian Journal of Botany 69, no. 4 (April 1, 1991): 901–6. http://dx.doi.org/10.1139/b91-116.

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Amongst diverse and abundant fossil proteaceous pollen in southeastern Australian Late Cretaceous (Campanian–Maastrichtian) sediments are forms identical with pollen of extant taxa within subfamilies Proteoideae, Persoonioideae, Carnarvonioideae, and Grevilleoideae. Taxa identified now have disparate geographic ranges within Australasia. Sclerophyllous Adenanthos and Stirlingia (Proteoideae) are restricted to the southern Australian Mediterranean climatic region; Persoonia (Persoonioideae) ranges into higher rainfall areas of eastern and northern Australia. Grevillea exul – Grevillea robusta and Telopea (Grevilleoideae) and Carnarvonia (Carnarvonioideae) occur in or fringe rain forests in eastern Australasia, as do other members (Macadamia, Gevuina–Hicksbeachia, Knightia, and Beauprea) reported previously. Pollen evidence thereby confirms evolution of both rain forest and sclerophyll members by the Campanian–Maastrichtian. Turnover of proteaceous pollen taxa near the Cretaceous–Tertiary boundary may reflect contemporaneous modifications to the proteaceous communities. Associated with the Late Cretaceous Proteaceae were diverse conifers (Microcachrys, Lagarostrobus, Podocarpus, Dacrydium, Dacrycarpus, and Araucariaceae), Nothofagus, Ilex, Gunnera, Ascarina, Winteraceae, Trimeniaceae, and probable Epacridaceae. The vegetation, which fringed a narrow estuary separating Antarctica from southern Australia, implies a mosaic of rain forest and sclerophyll communities but has no modern analogue. Key words: Proteaceae, Late Cretaceous, Australia, Antarctica.
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44

Kasekete, Désiré Katembo, Gauthier Ligot, Jean-Pierre Mate Mweru, Thomas Drouet, Mélissa Rousseau, Adrien Moango, and Nils Bourland. "Growth, Productivity, Biomass and Carbon Stock in Eucalyptus saligna and Grevillea robusta Plantations in North Kivu, Democratic Republic of the Congo." Forests 13, no. 9 (September 16, 2022): 1508. http://dx.doi.org/10.3390/f13091508.

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Initiated by the World Wildlife Fund (WWF) more than a decade ago in North Kivu, single-species plantations of Eucalyptus saligna and Grevillea robusta constitute, with other village plantations, the current legal source of wood-energy for the communities bordering the Virunga National Park (PNVi). This study assesses the growth and productivity of these plantations in two sites with different soil and climatic conditions to predict their production over time. The study also assesses the carbon stock and long-term CO2 fixation in the biomass of the studied plantations to deduce their contribution to climate change mitigation. Non-destructive inventories were carried out during three consecutive years in 20 E. saligna and 12 G. robusta plantations in Sake and Kirumba. Analysis of the data revealed that both species have similar diametric growth while height growth and productivity were significantly higher in the E. saligna plantations. The productivity of E. saligna was also higher in Kirumba than in Sake, while that of G. robusta was higher in Sake than in Kirumba. The differences observed were mainly related to species, silviculture, altitude and concentration of bioavailable elements in the soils. The analysis of productivity evolution over time allowed us to determine optimal rotations at 8 and 12 years, respectively, for E. saligna and G. robusta plantations. The relationships between biomass or carbon stock and tree diameter were not different between the studied species but were significantly different at the stand level. If silviculture was standardized and plantations carefully monitored, carbon stock and long-term CO2 fixation would be higher in G. robusta plantations than in E. saligna plantations. These results indicate that while for productivity reasons E. saligna is the favoured species in wood-energy plantations to quickly meet the demand of the growing and disadvantaged population living in the vicinity of PNVi, carefully monitored G. robusta plantations could be more interesting in terms of carbon credits. To simultaneously optimise wood-energy production and carbon storage in the plantations initiated in North Kivu, E. saligna and G. robusta should be planted in mixture. In addition, species and site characteristics adapted silvicultural management practices must be applied to these plantations, which are very important for the region, its population and its park. Finally, the economic profitability as well as the sustainability of the plantations should be assessed in the longer term in North Kivu.
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Dordel, Julia, Suzanne W. Simard, Jürgen Bauhus, Robert D. Guy, Cindy E. Prescott, Brad Seely, Hermann Hampel, and Luciano J. Pozas. "Effects of nurse-tree crop species and density on nutrient and water availability to underplanted Toona ciliata in northeastern Argentina." Canadian Journal of Forest Research 41, no. 9 (September 2011): 1754–68. http://dx.doi.org/10.1139/x11-093.

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Cultivation of high-value hardwoods is often more difficult than cultivation of many pioneer species commonly used in fast-growing plantations. On some sites, the facilitative effects of nurse trees can be necessary for initial crop species establishment, but their competitive effects can also reduce juvenile growth rates of the crop species. To improve establishment success in mixed-species plantations, we tested the effects of the nurse-tree species Grevillea robusta A.Cunn. ex R.Br., Pinus elliottii Engelm. × Pinus caribaea Morelet, and Pinus taeda L. and four densities (0%, 25%, 50%, and 75% of the initial density) on Toona ciliata M.Roem. light, soil water, and soil nutrient availability. Growth of T. ciliata tended to increase with decreasing nurse-tree density and increasing light availability. However, growth was greater under G. robusta than under the pines, even where light conditions were similar, corresponding to mostly higher nutrient availability and higher soil water contents underneath G. robusta. Wood δ13C of T. ciliata was positively correlated with growth, foliar nutrient contents (N, P, K, Mg, Ca), and soil water content at a depth of 20–40 cm. Our results suggest that G. robusta is less competitive for soil nutrients and water than the pine nurse-tree species.
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Sanjith, D. P., Ramakrishna Hegde, Manasa P. A. Clara, Supriya K. Salimath, Karanjit Singh, and V. Maheswarappa. "Performance of Grevillea robusta A. cunn. ex r. br. under different farming and spacing regimes." Journal of Tree Sciences 39, no. 1 (2020): 52. http://dx.doi.org/10.5958/2455-7129.2020.00007.2.

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47

SMITH, D. M., N. A. JACKSON, J. M. ROBERTS, and C. K. ONG. "Reverse flow of sap in tree roots and downward siphoning of water by Grevillea robusta." Functional Ecology 13, no. 2 (April 1999): 256–64. http://dx.doi.org/10.1046/j.1365-2435.1999.00315.x.

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48

Lott, J. E., S. B. Howard, C. K. Ong, and C. R. Black. "Long-term productivity of a Grevillea robusta-based overstorey agroforestry system in semi-arid Kenya." Forest Ecology and Management 139, no. 1-3 (December 2000): 187–201. http://dx.doi.org/10.1016/s0378-1127(00)00267-x.

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49

Mburu, Francis, Stéphane Dumarçay, Jean François Bocquet, Mathieu Petrissans, and Philippe Gérardin. "Effect of chemical modifications caused by heat treatment on mechanical properties of Grevillea robusta wood." Polymer Degradation and Stability 93, no. 2 (February 2008): 401–5. http://dx.doi.org/10.1016/j.polymdegradstab.2007.11.017.

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50

Kalinganire, A. "Performance of Grevillea robusta in plantations and on farms under varying environmental conditions in Rwanda." Forest Ecology and Management 80, no. 1-3 (January 1996): 279–85. http://dx.doi.org/10.1016/0378-1127(95)03613-x.

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