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References
|
Araujo FF, Tiritan CS, Pereira HM, Caetano Júnior O (2008). Development of mays and soil fertility under application of organic matter and phosphorite. Braz. J. Agric. Eng. Environ. 12:507-511. |
|
|
Baptista MJ, Lopes CA, Souza RB, Furumoto O (2006). Effect of solarization and biofumigation in autumn, in the incidence of bacterial wilt and potatoes yield. Braz. J. Hortic. 24:99-102. |
|
|
Berger LRR, Stamford NP, Santos CERS, Freitas ADS, Franco LO, Stamford TCM (2013). Plant and soil characteristics affected by biofertilizers from rocks and organic matter inoculated with diazotrophic bacteria and fungi that produce chitosan. J. Soil Sci. Plant Nutr. 13:592-603. |
|
|
Boonlertnirun S, Boonraung C, Suvanasara R (2008). Application of Chitosan in Rice Production. J. Metals Mat. Min. 18:47-52. |
|
|
Costa CLL, Batista JE, Costa Junior CO, Santos AP, Silva ML (2011). Application of phosphate fertilizer in melon grown in calcareous soils. Rev. Verde. 6:7-11. |
|
|
Degenhardt J, Larsen PB, Howell SK, Kochian LV (1998). Aluminum resistance in the Arabidopsis mutant a1r-104 is caused by an aluminum-induced increase in rhizosphere pH. Plant Physiol. 117:19-27. |
|
|
Echart CL, Cavalli-Molina S (2001). Aluminum toxicity: effects, mechanisms for tolerance and genetic control. Ciência Rural 31:531-541. |
|
|
El Tarabily KA, Soaud AA, Saleh ME, Matsumoto S (2006). Isolation and characterization of sulfur bacteria, including strains of Rhizobium from calcareous soils and their effects on nutrient uptake and growth of maize (Zea mays L.). Austr. J. Agric. Res. 57:101-111. |
|
|
Embrapa – Empresa Brasileira de Pesquisa Agropecuária (2009). Manual de Análises Químicas de Solo, Plantas e Fertilizantes. Brasília 627 p. |
|
|
Embrapa – Empresa Brasileira de Pesquisa Agropecuária (2013). Sistema brasileiro de classificação de solos. Brasília 306 p. |
|
|
Franco LO, Maia RCC, Porto ALF, Messias AS, Fukushima K, Takaki GMC (2004). Heavy metal biosorption by chitin and chitosan isolated from Cunninghamella elegans (IFM 46109). Braz. J. Microbiol. 35:243-247. |
|
|
Garcia AL, Lima WG, Souza EB, Michereff SJ, Mariano RLR (2013). Characterization of Ralstonia solanacearum causing bacerial wilt bell pepper in the state of Pernambuco, Brazil. J. Plant Physiol. 95:237-245. |
|
|
Ghormade V, Deshpande MV, Paknikar KM (2010). Perspectives for nanobiotechnology enabled protection and nutrition of plants. Biotechnol. Adv. 29:792-803. |
|
|
Goy RC, Britto D, Assis OBG (2009). A Review of the antimicrobial activity of chitosan. Polym. Sci. Technol. 9:241-247. |
|
|
Guazzelli MJ, Meirelles L, Barreto R, Gonçalves A, Motter C, Rupp LC (2007). Aplicação da teoria da trofobiose no controle de pragas e doenças: uma experiência na serra gaúcha. Agricultural 4:16-19. |
|
|
Hayward AC (1994). Systematics and phylogeny of Pseudomonas solanacearum and related bacteria. In: Bacterial Wilt: The Pseudomonas solanacearum disease and its causative agent. Wallingford, CAB International pp.123-135. |
|
|
Instituto Agronômico de Pernambuco – IPA. (2008). Recomendações de adubação para o estado de Pernambuco. 212p. |
|
|
Kowalski B, Terry FJ, Herrera L, Pe-alver DS (2006). Application of soluble chitosan in vitro and in the greenhouse to increase yield and seed quality of potato minitubers. Potato Res. 49:167-176. |
|
|
Lima FS, Stamford NP, Sousa CS, Lira Junior MA, Malheiros SMM, Van Straaten P (2010). Earthworm compound and rock biofertilizer enriched in nitrogen by inoculation with free living diazotrophic bacteria. World J. Microbiol. Biotechnol. 26:1769-1777. |
|
|
Lima RCM, Stamford NP, Santos CERS, Dias SHL (2007). Lettuce yield and chemical attributes of a Latosoil as affected by PK rock biofertilizer application. Braz. J. Hortic. 25:224-229. |
|
|
Moura PM, Stamford NP, Duenhas LH, Santos CERS, Nunes GHS (2007). Effectiveness of rock biofertilizer with Acidithiobacillus on melon grown in the San Francisco Valley. Braz. J. Agric. Sci. 2:1-7. |
|
|
SAS Institute (2011). The SAS 9.2 software. Statistical analysis System for Windows. Procedure guide for personal computer. Cary (CD-ROM). |
|
|
Oliveira WS, Stamford NP, Silva EVN, Silva CERS, Freitas AD, Arnaud TMS, Sarmento BF (2014). Biofertilizer produced by interactive microbial processes affects melon yield and nutrients availability in a Brazilian semiarid soil. Austr. J. Crop Sci. 8:1124-1131. |
|
|
Peixoto AR (1997). Controle biológico da murcha bacteriana do tomateiro, por Pseudomonas spp. fluorescentes. Ciênc. Rural 27:153-160. |
|
|
Stamford NP, Moura PM, Lira Junior MA, Santos CERS, Duenhas LH, Gava CAT (2009). Chemical attributes of an Argisol of the Vale do São Francisco after melon growth with phosphate and potash rocks biofertilizers. Braz. J. Hortic. 27:447-452. |
|
|
Stamford NP, Lima RA, Lira Junior MA, Santos CERS (2008). Effectiveness of phosphate and potash rocks with Acidithiobacillus on sugar cane yield and their effects in soil chemical attributes. World J. Microbiol. Biotechnol. 24:2061-2066. |
|
|
Stamford NP, Santos PR, Santos CERS, Freitas ADS, Dias SHL, Lira Junior MA (2007). Agronomic effectiveness of biofertilizers with phosphate rock, sulphur and Acidithiobacillus in a Brazilian tableland acidic soil grown with yam bean. Biores. Technol. 98:1311–1318. |
|
|
Stamford NP, Lima RA, Lira Junior MA, Santos CERS, Dias SHL (2006). Rock biofertilizers with Acidithiobacillus on sugarcane yield and nutrient uptake in a Brazilian soil. Geomicrobiol. J. 23:261-265. |
|
|
Van Straaten P (2007). Agrogeology - the use of rocks for crops. Enviroquest, Cambridge, Ontario, Canada 440 p. |
|
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