Your search keyword '"Letícia Freitas Guimarães"' showing total 6 results

1. Geology of the cretaceous Paraná Magmatic Province at the central portion of Torres Syncline, Southern Brazil

Author

Natasha Sarde Marteleto, Valdecir de Assis Janasi, Letícia Freitas Guimarães, Liza Angélica Polo, and Amanda Alves Ferreira

Subjects

Geological mapping, Paraná Magmatic Province, geoprocessing, volcanic stratigraphy, geomorphology, Maps, G3180-9980

Abstract

ABSTRACTGeological maps of tropical areas demand special challenges due to weathering conditions, mainly where relief has low variability. Most part of Paraná Magmatic Province is included in this scenario. An exception to this situation is the southeastern portion of the province, in the state of Rio Grande do Sul, Brazil. The stratigraphic disposition of volcanic units and the characteristics of erosion of each one caused the exposition of four identified plateaus, in which outcrop, from bottom to top: (1) basalts from Torres/Vale do Sol formations; (2) Caxias do Sul dacite; (3) Barros Cassal sequence; (4) Santa Maria rhyolite. The contacts were traced using SRTM images (through altitude and slope maps), integrating previously published semi- to detailed maps and geochemical database from our group. The resulting map (1:250,000) contributes to the volcano-stratigraphic knowledge of this huge province, and allows us to suggest the review of silicic units, initially called Palmas Formation.

Published

2023

2. A New Inclusive Volcanic Risk Ranking, Part 2: Application to Latin America

Author

Letícia Freitas Guimarães, Amiel Nieto-Torres, Costanza Bonadonna, and Corine Frischknecht

Subjects

volcanic risk ranking, volcanic hazards, Latin America volcanism, exposure, vulnerability, resilience, Science

Abstract

Volcanic Risk Ranking (VRR) methods have been developed worldwide as a way to hierarchize the volcanic systems and help target strategies for risk reduction. Such hierarchization is especially important in areas characterized by a large number of active volcanoes but limited resources. This is the case of Latin America, where large populations live nearby almost 300 active volcanoes. Here we assess the volcanic systems in Latin America with at least one eruption in the last 1,000 years based on the VRR strategy presented in a companion paper that accounts for the 4 main risk factors: hazard, exposure, vulnerability and resilience. Our results reveal that, among the 123 volcanoes analyzed, Santiaguito, Tacaná and Fuego are those with the highest score in the 3-factor VRR (H×E×V), while Ecuador, Marchena and Santiago are among the systems with the lowest score. Bárcena and Pinta score zero as there is no exposure. Although vulnerability significantly contributes to the VRR score, hazard and exposure are the main factors that define the risk of Latin American volcanic systems in the proposed 3-factor VRR, while resilience contributes to its reduction in the proposed 4-factor VRR strategy. In this regard, Arenal, Copahue, Villarrica, Ubinas, Irazú and Poás are the systems with the highest number of risk reduction strategies in place. Atitlán, Almolonga and Tecuamburro are the volcanic systems with the highest score in the 4-factor VRR [(H×E×V)/(Res+1)], combining moderate hazard, exposure and vulnerability and low resilience; Bárcena, Pinta, Ecuador, Marchena and Santiago receive the lowest scores due to no or low exposure. Santiaguito, Tacaná, El Chichón and Ceboruco are characterized by high scores in the 3-factor VRR and also stand out as some of those with few risk reduction strategies implemented; thus they have intermediate to high scores also in the 4-factor VRR. Recognizing that hazard is difficult to mitigate and reducing exposure may depend on hardly feasible relocation of infrastructure and already established communities, we emphasize that measures to reduce vulnerability and increase resilience should be promoted (e.g., creating redundancy/accessibility to infrastructure, carrying out risk assessment studies, implementing early warning systems, developing emergency plans and promoting educational activities).

Published

2021

3. First record of Amblyomma dissimile Koch 1844 (Acari: Ixodidae) parasitizing a wild raptor, the Gray-lined Hawk Buteo nitidus (Latham 1790) (Accipitriformes: Accipitridae), Brazilian Amazon

Author

Ana Karoline Chaves Ferreira Neves, Ana Letícia Freitas Guimarães, Antônio Messias Costa, and Paulo Cesar Magalhães-Matos

Subjects

Ecology, Insect Science, Ecology, Evolution, Behavior and Systematics

Published

2022

4. Stratigraphy and eruptive model of the dacitic volcanism in the region of São Marcos (South Paraná Magmatic Province)

Author

Letícia Freitas Guimarães, Valdecir de Assis Janasi, Excelso Ruberti, Carlos Augusto Sommer, and Eleonora Maria Gouvêa Vasconcellos

Subjects

Stratigraphy, Geochemistry, Volcanism, Geology

Abstract

Voluminous silicic volcanic rocks from the Paraná-Etendeka Magmatic Province are exposed in the southern Brazil, where a regional synformal structure (Torres Syncline) allowed the deposition and favored the preservation of a thick sequence of these units. In the São Marcos region (Rio Grande do Sul state) the volcanic sequence comprises basaltic rubbly pahoehoe flows (Vale do Sol Fm.) overlapped by dacitic deposits (Caxias do Sul sub-type), both intruded by basaltic dykes (Esmeralda Fm.). The genetic correlation between the Caxias do Sul dacites and the Vale do Sol basalts by an AFC process, already well described in the literature, is confirmed here; the fractionation of the basaltic magmas (with the extraction of plagioclase, pyroxene and Ti-magnetite) is clear through the patterns of major and trace elements, whereas the assimilation of crust is evidenced by variations in the traces elements ratios such as Rb/Ba and Th/U. Part of the chemical variations observed in the Caxias do Sul dacites were interpreted as primary, revealing the existence of two distinct groups of samples, with subtle variations in trace elements contents (Ce, Sm, Y and Th/U), suggestive of different sources and/or variations in the assimilated crustal component. Sub-parallel to the axis of the Torres Syncline, a NW-SE-trending zone constituted by the alignment of complex structures was interpreted as the feeding system of silicic volcanism, characterized as fissural. Detailed mapping allowed the description of distinct morphological domains, designated as \"breccia domain\", \"fragmentation domain\", \"regular domain\" and \"filaments domain\", the first domain being recognized as the host rock (together with underlying banded dacites) of the intrusive flow represented by the latter. The vertical intrusive flow exhibits two preferential directions: NW, ranging from N272° to N 355°, and NE, varying from N20° to N85°. The stratigraphy of the dacitic sequence can be defined, from the base to the top, as: banded deposits, classified as rheoignimbrites, and volcanic breccias locally intruded by the dacitic feeder system referred to above, followed by hybrid deposits (characterized by synchronous volcanic breccias and lobated lavas) which gradually give place to lavas flows and finally to massive deposits. Macroscopic quantitative textural analysis (including size distribution and shape parameters analysis of fragments and vesicles) of the volcanic breccias indicate that these deposits were generated under low eruptive energy and comparative studies support the hypothesis that they correspond to block and ash deposits. An eruptive model is proposed as follows: high temperature volatile-poor dacitic magma raised in a fissural conduit system with no significant crystallization. The low content (or even absence) of crystals and high temperatures inhibited the drastic increases in the viscosity of the shallow magmatic system. A magmatic rise fast enough to inhibit intense crystallization may have led to late-stage bubble growth and, together with high magma outflow rates, to boiling over eruptions responsible for the generation of PDCs (rheoignimbrites) related either to low-explosivity events or magma fountains. This first pyroclastic phase may have allowed efficient magma degassing and viscosity increase, and was succeeded by dome extrusions. The dome structure reduced the permeability and degassing of the system, leading to a new overpressure and causing the collapse of the dome structure and originating block and ash deposits. Additionally, the fissural architecture of the feeding system possibly permitted magma migration along an extended and variably open/closed fissure, leading to the occurrence of isolated magma batches evolving differently in terms of viscosity and degassing. This condition would be responsible for the occurrence of active and inactive vents, or vents with distinct eruptive dynamics spatially and/or temporally separated along the fissure system. Over time, the dome extrusion evolved towards new explosive events as relatively gas-rich magma ascent through the active shallow plumbing system or lava dome collapse caused rapid decompression and fragmentation. Finally, a gradual loss of eruptive energy and the widening of the active vent may have led to the explosive-effusive transition responsible for the generation of the hybrid deposits and lava flows. Grandes volumes de rochas vulcânicas ácidas relacionadas à Província Magmática Paraná Etendeka afloram na região sul do Brasil, onde uma estrutura sinformal regional, o Sinclinal de Torres, permitiu a colocação e favoreceu a preservação de espessas sequências vulcânicas. Na região de São Marcos (Rio Grande do Sul) a sequência vulcânica compreende derrames basálticos tipo rubbly pahoehoe (Fm. Vale do Sol) sobrepostos por depósitos dacíticos (sub-tipo Caxias do Sul), além de diques basálticos (Fm. Esmeralda) intrudindo todo o pacote. A correlação genética entre os dacitos Caxias do Sul e os basaltos Vale do Sol, através de processos de AFC, já bem definida na literatura, é aqui confirmada; o fracionamento dos basaltos (com extração de plagioclásio, piroxênio e ti-magnetita) fica claro através dos padrões de elementos maiores e traço, enquanto que a assimilação crustal é evidenciada pelas variações observadas nas razões de elementos traço como Rb/Ba e Th/U. As variações químicas observadas nas amostras de dacito foram caracterizadas como primárias e revelam a existência de dois grupos distintos, com variações sutis no conteúdo de elementos traço como Ce, Sm, Y e nas razões Th/U, sugerindo variações de fonte e/ou do componente crustal assimilado. Sub-paralela ao eixo do Sinclinal de Torres, com uma direção NW-SE, uma zona marcada pelo alinhamento de estruturas complexas foi interpretada como o sistema alimentador do vulcanismo ácido, caracterizado como fissural. O mapeamento de detalhe de tais estruturas permitiu o reconhecimento de domínios morfológicos distintos, denominados como \"domínio de brecha\", \"domínio de fragmentação\", \"domínio regular\" e \"domínio de filamentos\", sendo o primeiro reconhecido como a rocha encaixante (juntamente com os depósitos dacíticos bandados subjacentes) do fluxo intrusivo caracterizado pelos últimos domínios. O fluxo intrusivo vertical exibe duas direções: NW - variando de N272° a N355°, e NE, variando de N20° a N85°. A estratigrafia dos depósitos dacíticos pode ser definida, da base para o topo, em: depósitos bandados, interpretados como reoignimbritos, e brechas vulcânicas, ambos localmente intrudidos pelo sistema alimentador descrito anteriormente. O conjunto é sobreposto por depósitos híbridos (caracterizados pela ocorrência síncrona de brechas vulcânicas e lavas lobadas) que transicionam para derrames de lava e depósitos maciços. Análise textural quantitativa macroscópica das brechas vulcânicas (incluindo freqüência de distribuição de tamanho e parâmetros de forma tanto dos fragmentos quanto das vesículas) indica que tais depósitos foram gerados em eventos de baixa energia e um estudo comparativo dá suporte ao modelo de depósitos tipo block and ash. O seguinte modelo eruptivo para o vulcanismo ácido da região é proposto: um magma dacítico de altas temperaturas e relativamente empobrecido em voláteis ascendeu por um conduto fissural sem cristalização significativa. O baixo conteúdo de cristais e as elevadas temperaturas inibiram o aumento da viscosidade do sistema raso. Uma ascensão suficientemente rápida para inibir intensa cristalização permitiu uma nucleação e crescimento de vesículas tardio que, juntamente com elevada taxa de extrusão, possivelmente acarretaram a ocorrência de erupções tipo boiling over, responsáveis pela geração dos PDCs (reoignimbritos), relacionados a eventos de baixa explosividade ou a magma fountain. Esta fase inicial piroclástica permitiu uma desgaseificação eficiente e um consequente aumento na viscosidade do magma, resultando em uma fase de extrusão de corpos dômicos. A estrutura dômica gerada reduziu a permeabilidade e a degaseificação do sistema, resultando em uma nova sobrepressão, levando ao colapso da estrutura e gerando os depósitos block and ash. Ademais, a arquitetura fissural do sistema alimentador possivelmente permitiu a movimentação lateral do magma em ascensão ao longo de fissuras extensas e variavelmente abertas e fechadas, permitindo a ocorrência de corpos de magma isolados evoluindo distintamente em termos de viscosidade e desgaseificação. Esta condição favoreceu a ocorrência de vents ativos e inativos, ou mesmo com dinâmicas eruptivas distintas, espacial e temporalmente lado a lado ao longo do sistema de fissuras. Ao longo do tempo, a extrusão sob a forma de domos evoluiu para nova fase explosiva conforme novos fluxos magmáticos relativamente enriquecidos em voláteis ascenderam pelo conduto ativo ou o colapso do domo causou rápida descompressão e fragmentação do magma subjacente. Finalmente, a perda gradual da energia eruptiva, junto ao alargamento do vent ativo, levou à ocorrência dos depósitos híbridos e derrames de lavas.

Published

2019

5. Caracteristicas físicas e químicas e modelo eruptivo para os riolitos tipo Santa Maria (Província Magmática Paraná) na região de Gramado Xavier, RS

Author

Letícia Freitas Guimarães, Valdecir de Assis Janasi, Evandro Fernandes de Lima, and Antonio Jose Ranalli Nardy

Subjects

Geology

Abstract

Os riolitos Santa Maria correspondem a uma seqüência efusiva de rochas vítreas a hipocristalinas aflorantes na porção sul da Província Magmática Paraná, sul do Brasil. Mapeamentos de detalhe na região de Barros Cassal - Gramado Xavier mostraram que eles correspondem à sequência superior do magmatismo de baixo Ti, que é caracterizado por uma sucessão de basaltos pahoehoe - basaltos rubbly - dacitos - andesitos e dacitos - riolitos. Do ponto de vista químico, os riolitos são homogêneos, com 71-73% de SiO2, 0,65-0,70% de TiO2 e enriquecidos em K2O (4-5%) e outros elementos incompatíveis (210-300 ppm Rb; 680-930 ppm Ba; ~ 350 ppm de Zr e \'Sigma\' REE ~ 300 ppm) em comparação com as unidades dacíticas precedentes. Do ponto de vista isotópico, correspondem à unidade mais evoluída, com razões \'ANTPOT.87 Sr\'/ \'ANTPOT.86 \'Sr\'IND.(134)\' = 0,7230 a 0,7255, razões \'ANTPOT.143 Nd\'/\'ANTPOT.\'144\' Nd IND.(134)\' = 0,51204 a 0,51205 e correspondentes valores mais negativos para \"épsilon\"\'Nd IND.(134)\' = -8,2 e -8,4. Petrograficamente, são rochas porfiríticas com microfenocristais de plagioclásio, pigeonita e Ti-magnetita. Os cristais de plagioclásio, principal fase mineral, apresentam feições de reabsorção e zonamento composicional inverso, além de razões \'ANTPOT.87 Sr\'/\'ANTPOT.86 \'Sr\'IND.(134)\' sistematicamente mais elevados que as obtidas para rocha total (0,7267 a 0,7280), sendo classificados como antecristais, cuja cristalização se deu, possivelmente, nas bordas do conduto. Modelamentos AFC mostram que os riolitos Santa Maria podem ter sido gerados por 30-40% de cristalização de magmas parentais com composição equivalente à composição de um andesito basáltico da Sequencia Barros Cassal e de 8-15% de assimilação de composições graníticas equivalentes à composição de granitos neoproterozóicos regionais (Granitóides Garopaba). Os magmas geradores dos riolitos Santa Maria caracterizam-se por elevadas temperaturas (média de 970°C), baixos teores de água (0,7 a 1,1% -para a fase inicial de cristalização e 0,2% para a fase final), e viscosidades da ordem de \'10 POT.5\' a \'10 POT.6\' Pa.s. Estas características permitiram uma forma de ocorrência não explosiva, que resultou em estruturas particulares de fluxos lobados e derrames de lava, corroboradas pelos resultados obtidos através de estudos de anisotropia de susceptibilidade magnética. The Santa Maria rhyolites correspond to a sequence of effusive glassy to hipocrystalline rocks that outcrop in the southern portion of Paraná Magmatic Province, southern Brazil. Detailed field work in the Barros Cassal - Gramado Xavier region allows recognize that they correspond to the uppermost sequence of the low-Ti magmatism, which is characterized by a succession of pahoehoe basalt-rubbly basalt-dacite-dacite and andesite-rhyolite. The rhyolites are chemically homogeneous, with 71-73 wt% SiO2, 0.65-0.70 wt% TiO2 and are enriched in K2O (4-5 wt%) and other incompatible elements (210-300 ppm Rb; 680-930 ppm Ba; ~350 ppm Zr and \'Sigma\" REE ~300 ppm) when compared to the previous dacite units. Isotopically, it is the most evolved unit of all succession with the highest initial \'ANTPOT.87 Sr\'/\'ANTPOT.86 \'Sr\'IND.(134)\' (0.7230 to 0.7256) and \'ANTPOT.143 Nd\'/\'ANTPOT. 144\'Nd\'IND.(134)\' = 0,51204 to 0,51205, corresponding to negative \'épsilon\'\'Nd IND.(134)\' (-8,2 to -8,4). The rhyolites are porphyritic with microphenocrysts of plagioclase, pigeonite and Ti-magnetite. The plagioclase microphenocrysts show resorption features and inverse compositional zoning, with \'ANTPOT.87 Sr\'/ \'ANTPOT.86 \'Sr IND.(134)\' higher than those obtained for whole rock, indicating that they may correspond to antecrysts which crystallized near the walls of the conduit, and were affected by crustal contamination. AFC models indicate that the Santa Maria rhyolites may be generated by 30-40% of crystallization of basaltic andesite parental magmas with 8-15% of assimilation of granitic crust similar to regional Neoproterozoic granites (Garopaba Granitoid). The rhyolite magmas are characterized by high temperatures (970°C), low water contents (0.7 to 1.1% for the initial phase and 0.2% for the final stage) and viscosities around \'10 POT.5\' to \'10 POT.6\' Pa.s. These characteristics allowed an effusive extrusion, which resulted in peculiar structures as lava-domes, as corroborated by the results of anisotropy of magnetic susceptibility.

Published

2015

6. A New Inclusive Volcanic Risk Ranking, Part 1: Methodology

Author

Amiel Nieto-Torres, Leticia Freitas Guimarães, Costanza Bonadonna, and Corine Frischknecht

Subjects

volcanic risk, hazard, exposure, vulnerability, resilience, mexican volcanoes, Science

Abstract

The ever-increasing population living near active volcanoes highlights the need for the implementation of effective risk reduction measures to save lives and reduce the impact of volcanic unrest and eruptions. To help identify volcanic systems associated with potential high risk and prioritize risk reduction strategies, we introduce a new Volcanic Risk Ranking (VRR) methodology that integrates hazard, exposure, and vulnerability as factors that increase risk, and resilience as a factor that reduces risk. Here we present a description of the methodology using Mexican volcanoes as a case study, while a regional application to Latin American volcanoes is presented in a companion paper (Guimarães et al., submitted). With respect to existing strategies, the proposed VRR methodology expands the parameters associated with hazard and exposure and includes the analysis of 4 dimensions of vulnerability (physical, systemic, social, economic) and of resilience. In particular, we propose 41 parameters to be analyzed, including 9 hazard parameters, 9 exposure parameters, 10 vulnerability parameters and 13 resilience parameters. Since the number of parameters evaluated for each risk factor is different, they are normalized to have the same weight based on dedicated sensitivity analyses. In order to best illustrate the methodology, the proposed VRR is here applied to 13 Mexican volcanoes and compared with other approaches. We found that the volcanoes associated with the highest combination of hazard, exposure and vulnerability (3-factor VRR) for this geographic area are Tacaná and El Chichón regardless of the analyzed time window of eruption occurrence (i.e.,

Published

2021