Growth dynamics of container seedlings of Eucalyptus grandis x Eucalyptus urophylla and Hymenaea courbaril L.

Rocha, Maria Eunice Lima; Ristau, Ana Carolina Pinguelli; Cruz, Maria Soraia Fortado Vera; Oliveira Neto, Cândido Ferreira de; Malavasi, Marlene de Matos; Malavasi, Ubirajara Contro

doi:10.1590/0034-737X202269040006

ABSTRACT

Growth analysis (GA) is used to quantify plant development based on morphophysiological changes. GA is a practical tool to evaluate nursery techniques to make them more efficient. The objective of this essay was to quantity measure morphophysiological growth variables of Eucalyptus grandis x Eucalyptus urophylla and Hymenaea courbaril (jatoba) container seedlings to characterize growth stages. The essay was conducted in a shade house located in the western state of Paraná. GA analyses were performed at 10-day intervals on seedlings of both species. When evaluating Hymenaea courbaril seedlings results indicated increased values of height, diameter, root and shoot dry biomass up to 130 days after emergence (DAE). Seedling growth stage-based GA were 70, 100 and 130 DAE for the Eucalyptus hybrid and 50, 80, and 110 DAE for jatoba which presented accelerated, intermediate and reduced seedling growth.

Keywords:
morphological attributes; forest species; photosynthetic pigments; forest nurseries

INTRODUCTION

In Brazil, Eucalyptus spp. farming has adapted to the environmental conditions with an average productivity higher than in the centers of origin of the species (Souza et al., 2012SouzaJTTrevisanRDenardiLStangerlinDMVivianMAHaseleinCRSantiniJE2012 Qualidade da madeira serrada provenientes de árvores dominantes e média de Eucalyptus grandis submetidos a secagem. Cerne , 18:167-174). Eucalyptus urograndis or "superclone" when under ideal water, nutritional and climatic conditions show excellent primary and secondary growth (Fernandes et al., 2012FernandesALTFlorêncioTMFariaMF2012 Análise biométrica de florestas irrigadas de eucalipto nos cinco anos iniciais de desenvolvimento. Revista Brasileira de Engenharia Agrícola e Ambiental, 16:505-513). The hybrid is widely used in the forestry industry because of its great timber potential, in addition to faster cutting cycles (six and seven years), high basic density (0.50 to 0.52 g cm^-³), high lignin content (up to 29.94%), mechanical strength close to 80.82% and cellulose content around 68.41% (Gonçalves et al., 2009GonçalvesFGOliveiraJTSLuciaRMDSartórioRC2009 Estudo de algumas propriedades mecânicas da madeira de um híbrido clonal de Eucalyptus urophylla X Eucalyptus grandis. Revista Árvore , 33:501-509).

Despite the great economic potential and superior wood quality, native wood species are little considered in commercial plantations when compared to exotic species. Therefore, it is important not only to know the prospective use of those species as well as factors related to the conservation and protection of native wood species that are at risk of extinction (Bobato et al., 2008BobatoACCOpazoMAUNóbregaLHPMartinsGI2008 Métodos comparativos para recomposição de áreas de mata ciliar avaliados por análise longitudinal. Acta Scientiarum Agronomy, 30:89-95; Dias et al., 2012DiasPCOliveiraLSXavierAWendlingIVAR2012 Estaquia e miniestaquia de espécies florestais lenhosas do Brasil. Pesquisa Florestal Brasileira, 32:463-562).

Hymenaea courbaril L. (jatoba) has a wide distribution throughout Brazilian states, mainly due to its tolerance to a wide variation in edapho-climatic conditions found in degraded areas (Matheus et al., 2011MatheusMTAmaralJATSilvaDGGNevesDMPizzolECSSousaFCSantiGCGuarizHRLimaKAHoffmannRG2011 Sintomas de deficiência nutricional em Jatobá. Revista Científica Eletrônica de Engenharia Florestal, 17:89-97). Jatoba belongs to the Fabaceae family being considered either helophytic or selective xerophyte depending on its occurrence (Costa et al., 2011CostaWSouzaASouzaP2011 Ecologia, manejo, silvicultura e tecnologia de espécies nativas da mata atlântica. 3ª ed. Espécies Nativas da Mata Atlântica. Viçosa, UFV. 18p). Moreover, jatoba wood has great value in domestic and foreign markets, and can be used in the furniture industry, flooring, medicines, ingredients, in human and animal food, distilled beverages, as varnish and fuel, but illegal logging is so widespread that laws and regulations have been created in order to reduce the export of wood from illegal logging in countries of the European Union, United States and Australia (Silva et al., 2014SilvaSMMMartinsKMesquitaAGGWadtLHD2014 Genetic parameters for Hymenaea courbaril L. conservation in Southwestern Amazon. Ciência florestal, 24:87-95; Lowe et al., 2016LoweAJDormonttEEBowieMJDegenBGardnerSThomasDClarkeCRimbawantoAWiedenhoeftAYinY2016 Opportunities for improved transparency in the timber trade through scientific verification. BioScience, 66:990-998).

The morpho-physiological characteristics of seedlings can be modulated by nursery practices that confer greater tolerance or hardness to post-planting conditions. The use of seedlings with low quality quite often results in replanting and uneven stands (Eloy et al., 2014EloyECaronBOTrevisanRBehlingASchmidtDSouzaVQ2014 Determinação do período de permanência de mudas de Euclyptus grandis W. Hill ex Maiden em casa de vegetação. Comunicata Scientiae, 05:44-50) in spite of other factors (Grossnickle & Macdonald, 2018GrossnickleSCMacdonaldJE2018 Why seedlings grow: influence of plant attributes. New Forests, 49:01-34).

Stress tolerance can be explained as acclimation characterized by the process of transition from the nursery to the field. Therefore, by imposing stressful practices on seedlings, the nurseryman will aim to acclimate them. However, such practices are stressful to a greater or lesser degree (Landis et al., 2010LandisTDDumroeseRKHaaseDL2010 The container tree nursery manual: seedling processing, storage, and out planting. 7º ed. Washington, USDA Forest Service. 200p) which makes hardening beneficial or detrimental depending on plant ontogeny (Barton & Boege, 2017BartonKEBoegeK2017 Future directions in the ontogeny of plant defence: understanding the evolutionary causes and consequences. Ecology Letters, 20:403-411).

Growth analysis (GA) appears as a tool that quantifies physio-morphological changes according to species, evaluation period, photosynthetic efficiency and growth strategy. GA lacks the need for sophisticated or expensive equipment, which are replaced by simple and periodic measurements (Benincasa, 2004BenincasaMMP2004 Análise de Crescimento de Plantas (noções básicas). Jaboticabal, Funep. 42p; Falqueto et al., 2009FalquetoARCassolDMagalhães JuniorAMOliveiraACBacarinMA2009 Partição de assimilados em cultivares de arroz diferindo no potencial de produtividade de grãos. Bragantia, 68:453-461).

Based on the above, the essay aimed to characterize growth stages in seedlings of Eucalyptus grandis x Eucalyptus urophylla and Hymenaea courbaril L. propagated in containers to subsidize future hardening practice essays research.

MATERIAL AND METHODS

The essay was conducted in a shade house covered with 150-micron thick anti-UV and low-density polyethylene film located in Universidade Estadual do Oeste do Paraná, Marechal Cândido Rondon, Paraná, with coordinates of 24° 33' 24'' S, 54° 05' 67 '' W and altitude of 420 m. The climatological classification according to Koppen is the Cfa type, subtropical humid mesothermal (Alvares et al., 2013AlvaresCAStapeJLSentelhasPCGonçalves JL DeMSparovekGK2013 Köppen’s climate classification map for Brazil. Meteorologische Zeitschrift, 22:711-728).

Eucalyptus spp. and jatoba seeds were purchased from the Instituto de Pesquisas e Estudos Florestais (IPEF) and from the Rede de Sementes (Portal Amazônia), respectively.

Jatoba seeds were scarified in direction against the hypocotyl-radicle axis with a sandpaper (n° 36) to reduce tegument impermeability. Afterwards, seeds were disinfected in 10% sodium hypochlorite for 30 minutes and washed out followed by soaking in tap water for 48 hours and later sown in a 290 cm³ container. Jatoba sowing took place at on December 12, 2018 and the emergency started on December 20. The Growth analysis started on February 9, 2019 and ended on May 30, 2019 with 10-day intervals.

The propagation of Eucalyptus spp. used 120 cm³ containers with approximately five seeds each. Two weeks after emergence, germinates were selected (based on height and well-developed leaflets). According to Gomes et al. (2003GomesJMCoutoELeiteHGXavierAGarciaSLR2003 Crescimento de mudas de Eucalyptus grandis em diferentes tamanhos de tubetes e fertilização N-P-K. Revista Árvore , 27:113-127) the volume of tubes of 50 and 110 cm³ were the most suitable for Eucalyptus grandis seedlings aged close to 90 days. In addition, from this period onwards, the volumes used of the tubes were restricting the growth of the seedlings, however, on the other hand, there was greater growth in diameter, increase in dry biomass and greater rusticity for these seedlings. Therefore, the research used, based on the recommendation, the objective of the work and availability of containers provided by the University, tubes with volume equal to 120 cm³.

The sowing of eucalyptus spp. took place on August 8, 2018 with the beginning of the emergency as of August 6 of the same year. The growth analysis covered the period from November 9, 2018 to August 2, 2019 with intervals of 10 days.

Jatoba seedlings were evaluated for a period of 140 days, while for eucalyptus spp. morphometric measurements occurred up to 180 days. The analysis were carried out separately, since the objective is not to compare the species and therefore there is a discrepancy between the evaluation periods.

The containers used for the two species needed to be different due to the characteristics of each species, since Jatoba seeds are larger than eucalyptus spp. seeds, moreover, the first species forms much larger seedlings, and in this case, to soften the effects of physical limitation, different containers were chosen.

For propagation of both species, we used Humusfertil® vermicompost based on pine bark, sand as substrate, and vermiculite. During evaluation periods, a nutrient solution composed of 2 mL of KH₂PO₄ L^-1; 2 mL of MgSO₄ L^-1; 5 mL of KNO₃ L^-1; 5 mL L^-1 of Ca (NO₃)₂ 4H₂O; complete micronutrient equal to 1 mL L^-1; and 1 ml L^-1 of Fe-EDTA in 1.000 mL of distilled water was delivered (Hoagland & Arnon, 1950HoaglandDRArnonDI1950 The water culture method for growing plants without soils. Berkeley, California Agricultural Experimental Station. 347p). The nutrient solution delivered per seedling weekly was 5 mL up to 60 days after emergence followed by 10 mL until the end of evaluations.

Irrigation during propagation was carried out from a micro-sprinkler in five daily 10-minute intervals in the summer (at 06:45am, 08:45am, 12:45pm, 03:45pm and 05:45pm) and in three daily intervals during the winter (at 08:45 am, 01:45 pm and 05: 45 pm) for both species.

The experimental design used was a completely randomized one with sixteen evaluation periods, 20 repetitions per period totaling 260 Eucalyptus spp. seedlings, while with jatoba there were twelve evaluation periods, 15 repetitions per period totaling 180 seedlings.

The GA variables included height, stem diameter, above ground dry biomass (AGDB), below ground dry biomass (BGDB), leaf area (LI-3000A, Li- Cor®, USA) and Spad index (Minolta ®, chlorophyll meter RS-232). The Spad index was quantified in four Eucalyptus spp. leaves and in first and second pair of jatoba leaves during the essay.

Additionally, we calculated the slenderness index according to Ritchie et al. (2010RitchieGALandisTDDumroeseRKHaaseDL2010 Assessing plant quality. In: Landis TD, Dumroese RK & Haase DL (Eds.) The container tree nursery manual: Seedling Processing, Storage, and Outplanting. Washington, USDA Forest Service . p. 18-81), the Dickson quality index according to Dickson et al. (1960DicksonALeafALHosnerJF1960 Quality appraisal of white spruce and white pine seedling stock in nurseries. Forest Chronicle, 36:10-13), and the leaf area ratio (LAR), the absolute growth rate (AGR), the relative growth rate (RGR) and the net assimilation rate (NAR) according to Benincasa (2004BenincasaMMP2004 Análise de Crescimento de Plantas (noções básicas). Jaboticabal, Funep. 42p).

The results were tested for normality of the data with Kolmogorov-Smirnov, Cramér-von Mises, Anderson-Darling, Kuiper, Watson, Lilliefors and Shapiro-Wilk tests, while the Bartllet test was used for homogeneity. Due to the significance of the data, they were segregated and adjusted by the sigmoidal model. Graphs were constructed with Sigma Plot 12.0 and the curves were constructed according to the means and their respective standard deviations.

RESULTS AND DISCUSSION

Seedling height of Eucalyptus urophylla x Eucalyptus grandis showed accelerated growth until 110 days after emergence (DAE). After that period, seedlings reduced growth rate with a tendency to stabilize up to 180 DAE (Figure 1A).

Figure 1:
Average growth in height (A), stem diameter (B), slenderness index (C), above ground dry biomass (AGDB) (D), below ground dry biomass (BGDB) (E) and Dickson quality index (F) in Eucalyptus grandis x Eucalyptus urophylla seedlings.

In Eucalyptus spp. seedlings, stem diameter increased up to 140 DAE showing that the hybrid invests initially in height maintaining stem development for a longer time (Figure 1B). When evaluating seedling quality, a large stem diameter results in higher survivorship (Gomes & Paiva, 2011GomesJMPaivaHN2011 Viveiros Florestais: propagação sexuada. 3º ed. Viçosa, UFV . 116p).

The slenderness index (SI) expresses the ratio between seedling height and diameter. Therefore, the higher the value the lower is seedling stability (Klein et al., 2017KleinDRHessAFKreftaSMVieira FilhoMDHCiarnosckiLDCostaEA2017 Relações morfométricas para Araucaria angustifolia (Bertol.) Kuntze em Santa Catarina. Floresta, 47:501-512). The results of SI as a function of the DAE from eucalipto. seedlings (Figure 1C) tend to evolve to stability, after the maximum point observed at 90 DAE (8.76 cm mm^-1). Studies such as Gonçalves et al. (2005GonçalvesJLLMGonçalvesJLMSantarelliEGMoraes NetoSPManaraMPStapeJL2005 Produção de mudas de espécies nativas: substrato, nutrição, sombreamento e fertilização. In: Gonçalves JLM & Benedetti V (Eds.) Nutrição e fertilização florestal. Piracicaba, IPEF. p. 300-350) described that height should vary between 20 and 35 cm and stem diameter from 5 to 10 mm, resulting in a SI from 2 to 7 cm mm^-1 in seedlings of native wood species. Wendling and Dutra (2010WendlingIDutraLF2010 Produção de mudas de eucalipto por estaquia e miniestaquia. In: Wendling I & Dutra LF (Eds.) Produção de mudas de eucalipto. Colombo, Embrapa Florestas. p. 50-80) with seedlings of eucalipto concluded that the ideal height for shipping purposes is between 15 and 25 cm and stem diameter greater than 2 mm, with a SI ranging from 7.1 to 11.9 cm mm^-1.

The above ground dry biomass from eucalipto seedlings (Figure 1D) followed the trend observed for height, with increasing averages up to 160 DAE. BGDB values increased up to 140 DAE in the BGDB (Figure 1E) with posterior stabilization.

Mafia et al. (2005MafiaRGAlfenasACSiqueiraLFerreiraEMLeiteHGCavallazziJRP2005 Critério técnico para determinação da idade ótima de mudas de eucalipto para plantio. Revista Árvore , 29:947-953) reported stabilization in root development at the end of the evaluation period (i.e., approximately after 72 days) as a consequence of the mechanical limitation imposed by the container (50 cm³) used with two eucalipto clones. The above authors concluded from the root biomass that the ideal period for planting good quality seedlings of Eucalyptus urophylla Blake was at 100 DAE.

Studies have reinforced that Dickson's quality index (DQI) has been considered one of the best indicator of seedling quality, as it relates slenderness and dry biomass distribution. High DQI results in planting success since it is directly related to seedling quality (Gomes & Paiva, 2011GomesJMPaivaHN2011 Viveiros Florestais: propagação sexuada. 3º ed. Viçosa, UFV . 116p). The DQI values calculated from ours eucalipto seedlings increased up to 140 DAE (Figure 1F). Therefore, it would be recommended to send those seedlings for planting at that age.

Corroborating the results obtained with the same hybrid, propagated by cuttings, Silva et al. (2012SilvaRBGSimõesDSilvaM2012 Qualidade de mudas clonais de Eucalyptus urophylla x E. grandis em função do substrato. Revista Brasileira Engenharia Agrícola e Ambiental, 16:297-302) reported a DQI value less than 0.2 regardless of the treatments.

Leaf area (LA) values in eucalipto seedlings were increasing and linear up to 90 DAE (Figure 2A), coinciding with the phases of plant development mentioned by Peixoto and Peixoto (2004PeixotoCPPeixotoMFSP2004 Dinâmica do Crescimento vegetal (Princípios básicos). Cruz das Almas, Agrufba. 20p). The Spad index decreased with increased evaluation periods (Figure 2B). One of the reasons for such a reduction is that eucalipto leaves may present a change in color as a form of protection against the oxidation of photosynthetic pigments with anthocyanin accumulation. Araújo et al. (2018AraújoMMNavroskiMCSchornLATabaldiLARoratoDGTurchettoFZavistanoviczTCBerghettiALPAimiSCTonettoTSGasparinEDutraAFMezzomoJCGomesDRGriebelerAMSilvaMRBarbosaFMLimaMS2018 Caracterização e análise de atributos morfológicos e fisiológicos indicadores da qualidade de mudas em viveiro florestal. In: Araújo MM, Navroski MC & Schorn LA (Eds.) Produção de sementes e mudas: um enfoque na silvicultura. Santa Maria, UFSM. p. 345-382) associated leaf color change to hardening of eucalipto seedlings.

Figure 2:
Leaf area (A), Spad index (B), leaf area ratio (C), absolute growth rate (D), relative growth rate (E) and net assimilation rate (F) in Eucalyptus grandis x Eucalyptus urophylla seedlings.

Plants invest in increasing leaf area to improve photosynthetic production. However, during the vegetative development, leaves ripen and, consequently, senescence occurs. So, these photoassimilates found and stored in those structures will be redistributed. In addition, the leaf area ratio (LAR) will decrease due to the increase in the number of leaves and consequently self-shading (Benincasa, 2004BenincasaMMP2004 Análise de Crescimento de Plantas (noções básicas). Jaboticabal, Funep. 42p; Peixoto & Peixoto, 2004PeixotoCPPeixotoMFSP2004 Dinâmica do Crescimento vegetal (Princípios básicos). Cruz das Almas, Agrufba. 20p).

The leaf area ratio in eucalipto seedlings decreased up to 170 DAE with values ranging from 7.95 to 14.75 as a result of the progressive shading of the leaves in the lower third of the crown. Thus, the synthesis of photoassimilates was also reduced (Figure 2C).

The absolute growth rate (AGR) will predict the average growth rate over the entire observation period and express the relationship between the total dry biomass and the interval between evaluations (Benincasa, 2004BenincasaMMP2004 Análise de Crescimento de Plantas (noções básicas). Jaboticabal, Funep. 42p). Thus, as the morphometric variables shape the rate, it will also reduce the AGR value, demonstrating that extrinsic factors can be the main limiting factors in seedling development. In eucalipto seedlings, growth speed was accelerated up to 90 DAE (Figure 2D). The decrease of those values coincided with the reduction in leaf area, that is, for an absolute growth rate, self-shading will also be decisive in defining the way in which the growth will occur. Similar results were obtained by Lima et al. (2008LimaJDSilvaBMSMoraesWSDantasAAVAlmeidaCC2008 Efeitos da luminosidade no crescimento de mudas de Caesalpinia ferrea Mart. ex Tul. (Leguminosae, Caesalpinoideae). Acta Amazonica, 38:05-10) who associated the reduction in AGR with the increase in shade levels in Caesalpinia ferrea M.

Eucalipto seedlings showed first an accumulation in the relative growth rate (RGR) followed by a reduction after 90 DAE which also expressed reduction of height, diameter and leaf area (Figure 2E). Povhl and Onoll (2008PovhlJÁOnollEO2008 Crescimento de plantas de Salvia officinalis sob ação de reguladores de crescimento vegetal. Ciência Rural, 38:2186-2190) described that RGR of Salvia officinalis L. treated with plant regulators as well as control seedlings behaved in a similar way, first with an accelerated accumulation and later a rapid decrease.

Initial values of net assimilation rate (NAR) may be related to the increase in dry biomass, such as leaf area, since the liquid assimilation is directly linked to photosynthesis and as a consequence its better use in the production of photoassimilates. Up to 90 DAE, the hybrid Eucalyptus grandis x Eucalyptus urophylla showed an upward trend. From that and following the results of AGR and RGR, mean NAR was reduced due to the reduction in the speed of growth (Figure 2F).

Another factor that alters NAR is respiration, as it represents the relationship between what is produced and consumed by plant metabolism (i.e.. efficiency in conversion of light energy into dry biomass) (Peixoto & Peixoto, 2004PeixotoCPPeixotoMFSP2004 Dinâmica do Crescimento vegetal (Princípios básicos). Cruz das Almas, Agrufba. 20p).

After 130 DAE, jatoba seedlings started to reduce height growth rate. Regarding nursery management, plant growth limitation may result in dispatch seedlings for planting in advance (Figure 3A). Gonzaga et al. (2016GonzagaLMSilvaSSCamposSAFerreiraRPCamposANRCunhaACMCM2016 Recipientes e substratos para a produção de mudas de jatobá (Hymenaea courbaril L.). Revista Brasileira de Agropecuária Sustentável, 06:64-73) evaluated containers with volumes of 110 cm³ and plastic bags (15 cm in diameter and 20 cm in height) for propagation of jatoba seedlings. The authors reported that at 210 DAE the highest averages were calculated in seedlings produced in plastic bags. This is a consequence of the greater volume of substrate to be explored, greater nutritional availability and, consequently, favoring the formation of new roots. Ferraz and Engel (2011FerrazAVEngelVL2011 Efeito do tamanho de tubetes na qualidade de mudas de jatobá (Hymenaea courbaril L. Var. stilbocarpa (Hayne) Lee Et Lang.), ipê-amarelo (Tabebuia chrysotricha (Mart. Ex Dc.) Sandl.) e guarucaia (Parapiptadenia rigida (Benth.) Brenan). Revista Árvore, 35:413-423) recommended that the use of containers with a volume equal to or greater than 300 cm³ is not very restrictive and favors growth in seedlings height and stem diameter as well as anticipation of the production cycle.

Figure 3:
Average growth in height (A), stem diameter (B), slenderness index (C), above ground dry biomass (AGDB) (D), below ground dry biomass (BGDB) (E) and Dickson quality index (F) in Hymenaea courbaril seedlings.

Stem diameter from jatoba seedlings showed a similar trend to height (Figure 3B) with a reduction at 140 DAE. The reduction may result from the growth natural growth cycle of the species. Alternately, aboveground growth decreases to direct energy reserves to other plant structures, mainly the root, as a way of protection against environmental adversities (Mencuccini, 2014MencucciniM2014 Temporal scales for the coordination of tree carbon and water economies during droughts. Tree Physiology, 34:439-442).

In jatoba seedlings, values of SI ranged from 5.95 to 7.61 cm mm^-1 from 30 to 140 DAE. The tendency is that terrestrial plants seek a balance (aerial/root systems) to stabilize their development (Figure 3C). Gonzaga et al. (2016GonzagaLMSilvaSSCamposSAFerreiraRPCamposANRCunhaACMCM2016 Recipientes e substratos para a produção de mudas de jatobá (Hymenaea courbaril L.). Revista Brasileira de Agropecuária Sustentável, 06:64-73) reported that the SI from jatoba seedlings varied from 5.95 to 7.16 cm mm^-1 close to those calculated in this essay.

Above ground dry biomass of jatoba seedlings (Figure 3D) indicated that the highest average was obtained at 130 DAE, with reduced values after that period. In fact, the relationship between above and belowground tissues in terrestrial wood plants are complex and still little explored for some species. Therefore, understanding the dynamics, as well as the relationship between above and belowground tissues is extremely important regarding the metabolism of assimilation, absorption and transformation of the main substrates used by plants (Laclau et al., 2013LaclauJPSilvaEALambaisGRBernouxMLEMaireGStapeJLBouilletJPGonçalvesJLMJourdanCNouvellonY2013 Dynamics of soil exploration by fine roots down to a depth of 10 m throughout the entire rotation in Eucalyptus grandis plantations. Frontiers in Plant Science, 04:01-12).

Jatoba may lose leaves under certain circumstances (semi-deciduous) investing, primarily in root growth and as compensation for climatic adversities (Costa et al., 2011CostaWSouzaASouzaP2011 Ecologia, manejo, silvicultura e tecnologia de espécies nativas da mata atlântica. 3ª ed. Espécies Nativas da Mata Atlântica. Viçosa, UFV. 18p) seen in the present essay. From 100 DAE on, there was a reduction in leaf area coinciding with leaf loss, as well as a reduction in the Spad index. However, root biomass increased until the final assessment period (130 DAE) and remained close to that value at 140 DAE (Figure 3E). Comparing the increase in above ground biomass (Figure 3D) and root biomass (Figure 3E) and the difference between the lowest and highest averages, it was observed that the increase in dry biomass was 2.37 times in aboveground tissues, while it was 7.01 times for belowground ones, approximately.

Dickson's quality index of jatoba seedlings increased up to 130 DAE, coinciding with an increase in above and belowground biomasses with values greater than 0.30 (Figure 3F). However, this increase depends on factors such as crop treatment, management, type of substrate, container and stage of seedling development (Gomes et al., 2013GomesDRCaldeiraMVWDelarmelinaWMGonçalvesEOTrazziPA2013 Lodo de esgoto como substrato para a produção de mudas de Tectona grandis L. Cerne , 19:123-131).

Leaf area (LA) of jatoba seedlings showed a quadratic trend up to 90 DAE (Figure 4A). The LA of Handroanthus albus (Cham.) Mattos, guarucaia and jatoba seedlings quantified by Ferraz and Engel (2011FerrazAVEngelVL2011 Efeito do tamanho de tubetes na qualidade de mudas de jatobá (Hymenaea courbaril L. Var. stilbocarpa (Hayne) Lee Et Lang.), ipê-amarelo (Tabebuia chrysotricha (Mart. Ex Dc.) Sandl.) e guarucaia (Parapiptadenia rigida (Benth.) Brenan). Revista Árvore, 35:413-423) showed the highest averages with 300 cm³ containers compared to the 50 and 110 cm³ ones. We detected leaf spots with increased DAE, which contributed to the reduction of Spad index. The spots appeared on older leaves which evolved to necrosis and irregular spots in the leaf blade. With the increase of leaf spots there was a reduction in the pigmented area and, consequently, a reduction in the Spad index (Figure 4B).

Figure 4:
Leaf area (A), Spad index (B), leaf area ratio (C), absolute growth rate (D), relative growth rate (E) and net assimilation rate (F) in Hymenaea courbaril seedlings.

The concentration of photosynthetic pigments is strongly influenced by biotic and abiotic factors. With jatoba an increase in the number of leaves was observed, varying from 7.86 to 14.26. New leaves act as “drains” and later become productive (Taiz et al., 2017TaizLZeigerEMøllerIMMurphyA2017 Estresse abiótico. In: Blumwald E & Mittler R (Eds.) Fisiologia Vegetal. Porto Alegre, Artmed. p. 731-759). During leaf senescence or under stressful conditions that affect older leaves, some cellular constituents will be relocated. Amino acids, proteins and components related to pigmentation are degraded and transported from younger leaves to other defense-related organs for structuring new constituents, mainly for roots (Himelblau & Amasino, 2001HimelblauEAmasinoRM2001 Nutrient mobilized from leaves of Arabidopsis thaliana during leaf senescence. Journal of Plant Physiology, 158:1317-1323; Reyes-Arribas et al., 2001Reyes-ArribasTBarretJEHuberDJNellTAClarkDG2001 Leaf senescence in a non-yellowing cultivar of chrysanthemum (Dendranthema grandiflora). Physiologia Plantarum, 111:540-544). We hypothesize that there is growth limitation caused by container size because all jatoba seedlings developed leaf spots. Alternatively, leaf senescence could be influencing such symptoms. Reich (1995ReichPBWaltersMBKloeppelBDEllsworthDS1995 Different photosynthesis-nitrogen relations in deciduous hardwood and evergreen coniferous tree species. Oecologia, 104:24-30) reported that 67% of the species from tropical forests have leaf longevity greater than 10 months and in the case of jatoba, seedlings remained only four months in the shade house.

Self-shading is easily observed in jatoba seedlings, because of the conformation of its growth and leaf size and to the fact that the species requires more light in early stages of growth (Costa et al., 2011CostaWSouzaASouzaP2011 Ecologia, manejo, silvicultura e tecnologia de espécies nativas da mata atlântica. 3ª ed. Espécies Nativas da Mata Atlântica. Viçosa, UFV. 18p). Thus, leaf area rate (LAR) from jatoba seedlings also showed a reduction over DAE (Figure 4C). Variations in the relationship between the total leaf area and the total dry matter mass result from the growth strategy, both in morphological and physiological aspects (Santos Júnior et al., 2006Santos JúniorUMGonçalvesJFCFeldpauschTR2006 Growth, leaf nutrient concentration and photosynthetic nutrient use efficiency in tropical tree species planted in degraded areas in central Amazonia. Forest Ecology and Management, 226:299-309; Ferreira et al., 2009FerreiraMJGonçalvesJFCFerrazJBS2009 Photosynthetic parameters of young Brazil nut (Bertholletia excelsa H. B.) plants subjected to fertilization in a degraded area in Central Amazonia. Photosynthetica, 47:616-620).

Long-lived terrestrial plant species are vulnerable to both temperature variation and water deficit in the early stages of growth. Under stress, growth will be interrupted, and the defense process will be triggered (Hansen & Turner, 2019HansenWDTurnerMG2019 Origins of abrupt change? Postfire subalpine conifer regeneration declines nonlinearly with warming and drying. Ecological Monographs, 08:01-21).

In jatoba seedlings, there was greater growth in root biomass until the final evaluation periods, which resulted in a higher rate of growth quantified via absolute growth rate (AGR) (Figure 4D). According to Silva (2014SilvaS2014 Árvores nativas do Brasil. São Paulo, Editora Europa (Biblioteca Natureza). 168p), early growth of jatoba can occur under shading conditions. However, in order to reach reproductive maturity, it requires high incidence of light.

The relative growth rate (RGR) trend was similar to the AGR due to leaf area and dry biomasses. It is evident, therefore, that RGR can be associated with photosynthetic rate, in the same way that a high respiratory consumption is associated with a low photosynthetic rate, caused by any disturbance in plant metabolism (Figure 4E).

Net assimilation rate (NAR) varied depending on DAE as a result of the natural growth strategy which alter their development according to external stimuli (Figure 4F). Barbieri Júnior et al. (2007Barbieri JuniorDBragaLFRoqueCGSousasMP2007 Análise de crescimento de Hymenaea courbaril L. sob efeito da inoculação micorrizica e adubação fosfatada. Revista de Ciências Agro-Ambientais, 05:01-15) reported that jatoba seedlings treated with 8.400 g m^-3 of phosphorus and without the inoculation of mycorrhiza showed a reduction of NAR between 30 and 90 days DAE and evolved until stabilization at 120 DAE.

In eucalipto and jatoba seedlings, below ground dry biomass and stem diameter variables showed the highest correlation with DQI (Table 1). Binotto et al. (2010BinottoAFLúcioADLopesSJ2010 Correlations between growth variables and the Dickson quality index in forest seedlings. Cerne, 16:457-464) concluded that the root and total dry biomass as well as stem diameter were positively correlated with DQI in Eucalyptus grandis seedlings. The larger the root system, the greater the absorption of water and nutrients, resulting in greater aboveground growth and accumulation of biomass.

Thumbnail

Table 1:
Correlation among below ground dry biomass (BGDB) and diameter in Eucalyptus grandis x E. urophylla and Hymenaea courbaril seedlings with Dickson quality index (DQI)

For jatoba seedlings, in addition to DGDG mass, another variables that stood out was the correlation between Dickson's quality index and stem diameter. In this case, the latter contributed positively to the index on most days of evaluation (Table 1).

Seedlings with a larger stem diameter may have a greater field survival because of greater investment in root growth and accumulation of reserves (Gomes & Paiva, 2011GomesJMPaivaHN2011 Viveiros Florestais: propagação sexuada. 3º ed. Viçosa, UFV . 116p). Aimi et al. (2016AimiSCAraújoMMLeónEBOliveira GGdeCunha F DaS2016 Volumen de contenedores y dosis de fertilizante de liberación controlada en el crecimiento de plantas de Cabralea canjerana producidas en vivero. Bosque, 37:401-407) evaluated seedlings of Cabralea canjerana (Vell.) Mart. in the final stage of development in a nursery at 210 DAE and observed a high correlation (0.91) between stem diameter and below ground dry biomass.

Recent research about the concept of target seedling (Landis et al., 2010LandisTDDumroeseRKHaaseDL2010 The container tree nursery manual: seedling processing, storage, and out planting. 7º ed. Washington, USDA Forest Service. 200p) criticized the use of generalized values in determining seedling quality of wood species, whether exotic or native. Thus, detailed studies shall aim to determine the proper expedition stage and hardening as a function of the species.

Considering that hardening practices can be beneficial or harmful to seedling development, characterization of ontogenic or growth stages, are important to compare results of morphophysiological effects.

A major concern when determining the optimal age for dispatching seedlings to the field is that their quality will be directly related to the length of stay in the protected environment and the type of container they are cultivated. Because, these factors alone or together can contribute to the poor quality of plants. After the seedling rotation period is exceeded, the roots begin to curl, as well as the yellowing of the leaves that evolve into necrosis (Araújo et al., 2018AraújoMMNavroskiMCSchornLATabaldiLARoratoDGTurchettoFZavistanoviczTCBerghettiALPAimiSCTonettoTSGasparinEDutraAFMezzomoJCGomesDRGriebelerAMSilvaMRBarbosaFMLimaMS2018 Caracterização e análise de atributos morfológicos e fisiológicos indicadores da qualidade de mudas em viveiro florestal. In: Araújo MM, Navroski MC & Schorn LA (Eds.) Produção de sementes e mudas: um enfoque na silvicultura. Santa Maria, UFSM. p. 345-382). Thus, based on the results obtained, it is clear that the container, as well as other climatic factors, may have limited the development and accumulation of plant biomass in the final evaluation phase, approximately after 140 days for both species.

CONCLUSION

The dynamics of seedling growth indicated three growth stages of hybrid Eucalyptus grandis x Eucalyptus urophylla at 70, 100 and 130 DAE and in Hymenaea courbaril at 50, 80 and 110 DAE when propagated in containers of 120 and 290 cm³, respectively. The stages, namely initial, intermediary and final reflect variations of accelerated, constant and decreasing growth rate, respectively.

ACKNOWLEDGEMENTS, FINANCIAL SUPPORT AND FULL DISCLOSURE

CAPES, CNPq and Unioeste for financial or structural support to the author and co-authors.

REFERENCES

AimiSCAraújoMMLeónEBOliveira GGdeCunha F DaS2016 Volumen de contenedores y dosis de fertilizante de liberación controlada en el crecimiento de plantas de Cabralea canjerana producidas en vivero. Bosque, 37:401-407
AlvaresCAStapeJLSentelhasPCGonçalves JL DeMSparovekGK2013 Köppen’s climate classification map for Brazil. Meteorologische Zeitschrift, 22:711-728
AraújoMMNavroskiMCSchornLATabaldiLARoratoDGTurchettoFZavistanoviczTCBerghettiALPAimiSCTonettoTSGasparinEDutraAFMezzomoJCGomesDRGriebelerAMSilvaMRBarbosaFMLimaMS2018 Caracterização e análise de atributos morfológicos e fisiológicos indicadores da qualidade de mudas em viveiro florestal. In: Araújo MM, Navroski MC & Schorn LA (Eds.) Produção de sementes e mudas: um enfoque na silvicultura. Santa Maria, UFSM. p. 345-382
Barbieri JuniorDBragaLFRoqueCGSousasMP2007 Análise de crescimento de Hymenaea courbaril L. sob efeito da inoculação micorrizica e adubação fosfatada. Revista de Ciências Agro-Ambientais, 05:01-15
BartonKEBoegeK2017 Future directions in the ontogeny of plant defence: understanding the evolutionary causes and consequences. Ecology Letters, 20:403-411
BenincasaMMP2004 Análise de Crescimento de Plantas (noções básicas). Jaboticabal, Funep. 42p
BinottoAFLúcioADLopesSJ2010 Correlations between growth variables and the Dickson quality index in forest seedlings. Cerne, 16:457-464
BobatoACCOpazoMAUNóbregaLHPMartinsGI2008 Métodos comparativos para recomposição de áreas de mata ciliar avaliados por análise longitudinal. Acta Scientiarum Agronomy, 30:89-95
CostaWSouzaASouzaP2011 Ecologia, manejo, silvicultura e tecnologia de espécies nativas da mata atlântica. 3ª ed. Espécies Nativas da Mata Atlântica. Viçosa, UFV. 18p
DiasPCOliveiraLSXavierAWendlingIVAR2012 Estaquia e miniestaquia de espécies florestais lenhosas do Brasil. Pesquisa Florestal Brasileira, 32:463-562
DicksonALeafALHosnerJF1960 Quality appraisal of white spruce and white pine seedling stock in nurseries. Forest Chronicle, 36:10-13
EloyECaronBOTrevisanRBehlingASchmidtDSouzaVQ2014 Determinação do período de permanência de mudas de Euclyptus grandis W. Hill ex Maiden em casa de vegetação. Comunicata Scientiae, 05:44-50
FalquetoARCassolDMagalhães JuniorAMOliveiraACBacarinMA2009 Partição de assimilados em cultivares de arroz diferindo no potencial de produtividade de grãos. Bragantia, 68:453-461
FernandesALTFlorêncioTMFariaMF2012 Análise biométrica de florestas irrigadas de eucalipto nos cinco anos iniciais de desenvolvimento. Revista Brasileira de Engenharia Agrícola e Ambiental, 16:505-513
FerrazAVEngelVL2011 Efeito do tamanho de tubetes na qualidade de mudas de jatobá (Hymenaea courbaril L. Var. stilbocarpa (Hayne) Lee Et Lang.), ipê-amarelo (Tabebuia chrysotricha (Mart. Ex Dc.) Sandl.) e guarucaia (Parapiptadenia rigida (Benth.) Brenan). Revista Árvore, 35:413-423
FerreiraMJGonçalvesJFCFerrazJBS2009 Photosynthetic parameters of young Brazil nut (Bertholletia excelsa H. B.) plants subjected to fertilization in a degraded area in Central Amazonia. Photosynthetica, 47:616-620
GomesJMCoutoELeiteHGXavierAGarciaSLR2003 Crescimento de mudas de Eucalyptus grandis em diferentes tamanhos de tubetes e fertilização N-P-K. Revista Árvore , 27:113-127
GomesJMPaivaHN2011 Viveiros Florestais: propagação sexuada. 3º ed. Viçosa, UFV . 116p
GomesDRCaldeiraMVWDelarmelinaWMGonçalvesEOTrazziPA2013 Lodo de esgoto como substrato para a produção de mudas de Tectona grandis L. Cerne , 19:123-131
GonçalvesJLLMGonçalvesJLMSantarelliEGMoraes NetoSPManaraMPStapeJL2005 Produção de mudas de espécies nativas: substrato, nutrição, sombreamento e fertilização. In: Gonçalves JLM & Benedetti V (Eds.) Nutrição e fertilização florestal. Piracicaba, IPEF. p. 300-350
GonçalvesFGOliveiraJTSLuciaRMDSartórioRC2009 Estudo de algumas propriedades mecânicas da madeira de um híbrido clonal de Eucalyptus urophylla X Eucalyptus grandis. Revista Árvore , 33:501-509
GonzagaLMSilvaSSCamposSAFerreiraRPCamposANRCunhaACMCM2016 Recipientes e substratos para a produção de mudas de jatobá (Hymenaea courbaril L.). Revista Brasileira de Agropecuária Sustentável, 06:64-73
GrossnickleSCMacdonaldJE2018 Why seedlings grow: influence of plant attributes. New Forests, 49:01-34
HansenWDTurnerMG2019 Origins of abrupt change? Postfire subalpine conifer regeneration declines nonlinearly with warming and drying. Ecological Monographs, 08:01-21
HimelblauEAmasinoRM2001 Nutrient mobilized from leaves of Arabidopsis thaliana during leaf senescence. Journal of Plant Physiology, 158:1317-1323
HoaglandDRArnonDI1950 The water culture method for growing plants without soils. Berkeley, California Agricultural Experimental Station. 347p
KleinDRHessAFKreftaSMVieira FilhoMDHCiarnosckiLDCostaEA2017 Relações morfométricas para Araucaria angustifolia (Bertol.) Kuntze em Santa Catarina. Floresta, 47:501-512
LaclauJPSilvaEALambaisGRBernouxMLEMaireGStapeJLBouilletJPGonçalvesJLMJourdanCNouvellonY2013 Dynamics of soil exploration by fine roots down to a depth of 10 m throughout the entire rotation in Eucalyptus grandis plantations. Frontiers in Plant Science, 04:01-12
LandisTDDumroeseRKHaaseDL2010 The container tree nursery manual: seedling processing, storage, and out planting. 7º ed. Washington, USDA Forest Service. 200p
LimaJDSilvaBMSMoraesWSDantasAAVAlmeidaCC2008 Efeitos da luminosidade no crescimento de mudas de Caesalpinia ferrea Mart. ex Tul. (Leguminosae, Caesalpinoideae). Acta Amazonica, 38:05-10
LoweAJDormonttEEBowieMJDegenBGardnerSThomasDClarkeCRimbawantoAWiedenhoeftAYinY2016 Opportunities for improved transparency in the timber trade through scientific verification. BioScience, 66:990-998
MafiaRGAlfenasACSiqueiraLFerreiraEMLeiteHGCavallazziJRP2005 Critério técnico para determinação da idade ótima de mudas de eucalipto para plantio. Revista Árvore , 29:947-953
MatheusMTAmaralJATSilvaDGGNevesDMPizzolECSSousaFCSantiGCGuarizHRLimaKAHoffmannRG2011 Sintomas de deficiência nutricional em Jatobá. Revista Científica Eletrônica de Engenharia Florestal, 17:89-97
MencucciniM2014 Temporal scales for the coordination of tree carbon and water economies during droughts. Tree Physiology, 34:439-442
PeixotoCPPeixotoMFSP2004 Dinâmica do Crescimento vegetal (Princípios básicos). Cruz das Almas, Agrufba. 20p
PovhlJÁOnollEO2008 Crescimento de plantas de Salvia officinalis sob ação de reguladores de crescimento vegetal. Ciência Rural, 38:2186-2190
ReichPBWaltersMBKloeppelBDEllsworthDS1995 Different photosynthesis-nitrogen relations in deciduous hardwood and evergreen coniferous tree species. Oecologia, 104:24-30
Reyes-ArribasTBarretJEHuberDJNellTAClarkDG2001 Leaf senescence in a non-yellowing cultivar of chrysanthemum (Dendranthema grandiflora). Physiologia Plantarum, 111:540-544
RitchieGALandisTDDumroeseRKHaaseDL2010 Assessing plant quality. In: Landis TD, Dumroese RK & Haase DL (Eds.) The container tree nursery manual: Seedling Processing, Storage, and Outplanting. Washington, USDA Forest Service . p. 18-81
Santos JúniorUMGonçalvesJFCFeldpauschTR2006 Growth, leaf nutrient concentration and photosynthetic nutrient use efficiency in tropical tree species planted in degraded areas in central Amazonia. Forest Ecology and Management, 226:299-309
SilvaS2014 Árvores nativas do Brasil. São Paulo, Editora Europa (Biblioteca Natureza). 168p
SilvaRBGSimõesDSilvaM2012 Qualidade de mudas clonais de Eucalyptus urophylla x E. grandis em função do substrato. Revista Brasileira Engenharia Agrícola e Ambiental, 16:297-302
SilvaSMMMartinsKMesquitaAGGWadtLHD2014 Genetic parameters for Hymenaea courbaril L. conservation in Southwestern Amazon. Ciência florestal, 24:87-95
SouzaJTTrevisanRDenardiLStangerlinDMVivianMAHaseleinCRSantiniJE2012 Qualidade da madeira serrada provenientes de árvores dominantes e média de Eucalyptus grandis submetidos a secagem. Cerne , 18:167-174
TaizLZeigerEMøllerIMMurphyA2017 Estresse abiótico. In: Blumwald E & Mittler R (Eds.) Fisiologia Vegetal. Porto Alegre, Artmed. p. 731-759
WendlingIDutraLF2010 Produção de mudas de eucalipto por estaquia e miniestaquia. In: Wendling I & Dutra LF (Eds.) Produção de mudas de eucalipto. Colombo, Embrapa Florestas. p. 50-80

Publication Dates

Publication in this collection
22 July 2022
Date of issue
Jul-Aug 2022

History

Received
14 July 2021
Accepted
11 Oct 2021

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] AimiSCAraújoMMLeónEBOliveira GGdeCunha F DaS2016 Volumen de contenedores y dosis de fertilizante de liberación controlada en el crecimiento de plantas de Cabralea canjerana producidas en vivero. Bosque, 37:401-407

[2] AlvaresCAStapeJLSentelhasPCGonçalves JL DeMSparovekGK2013 Köppen’s climate classification map for Brazil. Meteorologische Zeitschrift, 22:711-728

[3] AraújoMMNavroskiMCSchornLATabaldiLARoratoDGTurchettoFZavistanoviczTCBerghettiALPAimiSCTonettoTSGasparinEDutraAFMezzomoJCGomesDRGriebelerAMSilvaMRBarbosaFMLimaMS2018 Caracterização e análise de atributos morfológicos e fisiológicos indicadores da qualidade de mudas em viveiro florestal. In: Araújo MM, Navroski MC & Schorn LA (Eds.) Produção de sementes e mudas: um enfoque na silvicultura. Santa Maria, UFSM. p. 345-382

[4] Barbieri JuniorDBragaLFRoqueCGSousasMP2007 Análise de crescimento de Hymenaea courbaril L. sob efeito da inoculação micorrizica e adubação fosfatada. Revista de Ciências Agro-Ambientais, 05:01-15

[5] BartonKEBoegeK2017 Future directions in the ontogeny of plant defence: understanding the evolutionary causes and consequences. Ecology Letters, 20:403-411

[6] BenincasaMMP2004 Análise de Crescimento de Plantas (noções básicas). Jaboticabal, Funep. 42p

[7] BinottoAFLúcioADLopesSJ2010 Correlations between growth variables and the Dickson quality index in forest seedlings. Cerne, 16:457-464

[8] BobatoACCOpazoMAUNóbregaLHPMartinsGI2008 Métodos comparativos para recomposição de áreas de mata ciliar avaliados por análise longitudinal. Acta Scientiarum Agronomy, 30:89-95

[9] CostaWSouzaASouzaP2011 Ecologia, manejo, silvicultura e tecnologia de espécies nativas da mata atlântica. 3ª ed. Espécies Nativas da Mata Atlântica. Viçosa, UFV. 18p

[10] DiasPCOliveiraLSXavierAWendlingIVAR2012 Estaquia e miniestaquia de espécies florestais lenhosas do Brasil. Pesquisa Florestal Brasileira, 32:463-562

[11] DicksonALeafALHosnerJF1960 Quality appraisal of white spruce and white pine seedling stock in nurseries. Forest Chronicle, 36:10-13

[12] EloyECaronBOTrevisanRBehlingASchmidtDSouzaVQ2014 Determinação do período de permanência de mudas de Euclyptus grandis W. Hill ex Maiden em casa de vegetação. Comunicata Scientiae, 05:44-50

[13] FalquetoARCassolDMagalhães JuniorAMOliveiraACBacarinMA2009 Partição de assimilados em cultivares de arroz diferindo no potencial de produtividade de grãos. Bragantia, 68:453-461

[14] FernandesALTFlorêncioTMFariaMF2012 Análise biométrica de florestas irrigadas de eucalipto nos cinco anos iniciais de desenvolvimento. Revista Brasileira de Engenharia Agrícola e Ambiental, 16:505-513

[15] FerrazAVEngelVL2011 Efeito do tamanho de tubetes na qualidade de mudas de jatobá (Hymenaea courbaril L. Var. stilbocarpa (Hayne) Lee Et Lang.), ipê-amarelo (Tabebuia chrysotricha (Mart. Ex Dc.) Sandl.) e guarucaia (Parapiptadenia rigida (Benth.) Brenan). Revista Árvore, 35:413-423

[16] FerreiraMJGonçalvesJFCFerrazJBS2009 Photosynthetic parameters of young Brazil nut (Bertholletia excelsa H. B.) plants subjected to fertilization in a degraded area in Central Amazonia. Photosynthetica, 47:616-620

[17] GomesJMCoutoELeiteHGXavierAGarciaSLR2003 Crescimento de mudas de Eucalyptus grandis em diferentes tamanhos de tubetes e fertilização N-P-K. Revista Árvore , 27:113-127

[18] GomesJMPaivaHN2011 Viveiros Florestais: propagação sexuada. 3º ed. Viçosa, UFV . 116p

[19] GomesDRCaldeiraMVWDelarmelinaWMGonçalvesEOTrazziPA2013 Lodo de esgoto como substrato para a produção de mudas de Tectona grandis L. Cerne , 19:123-131

[20] GonçalvesJLLMGonçalvesJLMSantarelliEGMoraes NetoSPManaraMPStapeJL2005 Produção de mudas de espécies nativas: substrato, nutrição, sombreamento e fertilização. In: Gonçalves JLM & Benedetti V (Eds.) Nutrição e fertilização florestal. Piracicaba, IPEF. p. 300-350

[21] GonçalvesFGOliveiraJTSLuciaRMDSartórioRC2009 Estudo de algumas propriedades mecânicas da madeira de um híbrido clonal de Eucalyptus urophylla X Eucalyptus grandis. Revista Árvore , 33:501-509

[22] GonzagaLMSilvaSSCamposSAFerreiraRPCamposANRCunhaACMCM2016 Recipientes e substratos para a produção de mudas de jatobá (Hymenaea courbaril L.). Revista Brasileira de Agropecuária Sustentável, 06:64-73

[23] GrossnickleSCMacdonaldJE2018 Why seedlings grow: influence of plant attributes. New Forests, 49:01-34

[24] HansenWDTurnerMG2019 Origins of abrupt change? Postfire subalpine conifer regeneration declines nonlinearly with warming and drying. Ecological Monographs, 08:01-21

[25] HimelblauEAmasinoRM2001 Nutrient mobilized from leaves of Arabidopsis thaliana during leaf senescence. Journal of Plant Physiology, 158:1317-1323

[26] HoaglandDRArnonDI1950 The water culture method for growing plants without soils. Berkeley, California Agricultural Experimental Station. 347p

[27] KleinDRHessAFKreftaSMVieira FilhoMDHCiarnosckiLDCostaEA2017 Relações morfométricas para Araucaria angustifolia (Bertol.) Kuntze em Santa Catarina. Floresta, 47:501-512

[28] LaclauJPSilvaEALambaisGRBernouxMLEMaireGStapeJLBouilletJPGonçalvesJLMJourdanCNouvellonY2013 Dynamics of soil exploration by fine roots down to a depth of 10 m throughout the entire rotation in Eucalyptus grandis plantations. Frontiers in Plant Science, 04:01-12

[29] LandisTDDumroeseRKHaaseDL2010 The container tree nursery manual: seedling processing, storage, and out planting. 7º ed. Washington, USDA Forest Service. 200p

[30] LimaJDSilvaBMSMoraesWSDantasAAVAlmeidaCC2008 Efeitos da luminosidade no crescimento de mudas de Caesalpinia ferrea Mart. ex Tul. (Leguminosae, Caesalpinoideae). Acta Amazonica, 38:05-10

[31] LoweAJDormonttEEBowieMJDegenBGardnerSThomasDClarkeCRimbawantoAWiedenhoeftAYinY2016 Opportunities for improved transparency in the timber trade through scientific verification. BioScience, 66:990-998

[32] MafiaRGAlfenasACSiqueiraLFerreiraEMLeiteHGCavallazziJRP2005 Critério técnico para determinação da idade ótima de mudas de eucalipto para plantio. Revista Árvore , 29:947-953

[33] MatheusMTAmaralJATSilvaDGGNevesDMPizzolECSSousaFCSantiGCGuarizHRLimaKAHoffmannRG2011 Sintomas de deficiência nutricional em Jatobá. Revista Científica Eletrônica de Engenharia Florestal, 17:89-97

[34] MencucciniM2014 Temporal scales for the coordination of tree carbon and water economies during droughts. Tree Physiology, 34:439-442

[35] PeixotoCPPeixotoMFSP2004 Dinâmica do Crescimento vegetal (Princípios básicos). Cruz das Almas, Agrufba. 20p

[36] PovhlJÁOnollEO2008 Crescimento de plantas de Salvia officinalis sob ação de reguladores de crescimento vegetal. Ciência Rural, 38:2186-2190

[37] ReichPBWaltersMBKloeppelBDEllsworthDS1995 Different photosynthesis-nitrogen relations in deciduous hardwood and evergreen coniferous tree species. Oecologia, 104:24-30

[38] Reyes-ArribasTBarretJEHuberDJNellTAClarkDG2001 Leaf senescence in a non-yellowing cultivar of chrysanthemum (Dendranthema grandiflora). Physiologia Plantarum, 111:540-544

[39] RitchieGALandisTDDumroeseRKHaaseDL2010 Assessing plant quality. In: Landis TD, Dumroese RK & Haase DL (Eds.) The container tree nursery manual: Seedling Processing, Storage, and Outplanting. Washington, USDA Forest Service . p. 18-81

[40] Santos JúniorUMGonçalvesJFCFeldpauschTR2006 Growth, leaf nutrient concentration and photosynthetic nutrient use efficiency in tropical tree species planted in degraded areas in central Amazonia. Forest Ecology and Management, 226:299-309

[41] SilvaS2014 Árvores nativas do Brasil. São Paulo, Editora Europa (Biblioteca Natureza). 168p

[42] SilvaRBGSimõesDSilvaM2012 Qualidade de mudas clonais de Eucalyptus urophylla x E. grandis em função do substrato. Revista Brasileira Engenharia Agrícola e Ambiental, 16:297-302

[43] SilvaSMMMartinsKMesquitaAGGWadtLHD2014 Genetic parameters for Hymenaea courbaril L. conservation in Southwestern Amazon. Ciência florestal, 24:87-95

[44] SouzaJTTrevisanRDenardiLStangerlinDMVivianMAHaseleinCRSantiniJE2012 Qualidade da madeira serrada provenientes de árvores dominantes e média de Eucalyptus grandis submetidos a secagem. Cerne , 18:167-174

[45] TaizLZeigerEMøllerIMMurphyA2017 Estresse abiótico. In: Blumwald E & Mittler R (Eds.) Fisiologia Vegetal. Porto Alegre, Artmed. p. 731-759

[46] WendlingIDutraLF2010 Produção de mudas de eucalipto por estaquia e miniestaquia. In: Wendling I & Dutra LF (Eds.) Produção de mudas de eucalipto. Colombo, Embrapa Florestas. p. 50-80

Eucalyptus urograndis
	30	40	50	60	70	80	90	100
				DAE
BGDB	0,997*	0,994*	0,997*	0,919*	0,947*	0,902*	0,823*	0,943*
Stem diameter	0,527*	0,544*	0,259*	0,839*	0,830*	0,589*	0,617*	0,712*
	110	120	130	140	150	160	170	180
BGDB	0,938*	0,752*	0,844*	0,930*	0,804*	0,568*	0,636*	0,765*
Stem diameter	0,861*	0,399*	0,391*	0,844*	0,900*	0,797*	0,846*	0,765*
Hymenaea courbaril
	30	40	50	60	70	80	90	100
				DAE
BGDB	0,890*	0,909*	0,751*	0,911*	0,653*	0,833*	0,775*	0,836*
Stem diameter	0,896*	0,334*	0,431*	0,802*	0,828*	0,737*	0,474*	0,668*
	110	120	130	140	-	-	-	-
BGDB	0,788*	0,836*	0,519*	0,760*
Stem diameter	0,853*	0,280*	0,897*	0,728*