Emisión de gases de efecto invernadero por incendios forestales en tres comunidades arbóreas de Michoacán

Ruben Ortiz-Mendoza; Marco Aurelio González Tagle; Diego Pérez Salicrup; Óscar Alberto Aguirre Calderón; Wibke Himmelsbach; Luis Gerardo Cuéllar Rodríguez

Emisión de gases de efecto invernadero por incendios forestales en tres comunidades arbóreas de Michoacán

Ortiz-Mendoza, Ruben ^[1] ; González-Tagle, Marco Aurelio ^[1] ; Pérez-Salicrup, Diego Rafael ^[2] ; Aguirre-Calderón, Oscar Alberto ^[1] ; Himmelsbach, Wibke ^[1] ; Cuéllar-Rodríguez, Luis Gerardo ^[1]
1. [1] Universidad Autónoma de Nuevo León
  
  Universidad Autónoma de Nuevo León
  
  México
2. [2] Universidad Nacional Autónoma de México
  
  Universidad Nacional Autónoma de México
  
  México
Localización: Ecosistemas y Recursos Agropecuarios, ISSN-e 2007-901X, ISSN 2007-9028, Vol. 12, Nº. 1 (Enero-Abril 2025), 2025
Idioma: español
DOI: 10.19136/era.a12n1.4184
Títulos paralelos:
- Greenhouse gas emission due to forest fires in three tree communities in Michoacán
Enlaces
- Texto completo (pdf)
Resumen
- español
  Los incendios forestales consumen grandes cantidades de combustible forestal y emiten gases de efecto invernadero a la atmosfera, principalmente de CO2y CO. El objetivo de este trabajo fue calcular las emisiones en quemas de la capa de hojarasca, así como las emisiones considerando todos los estratos vegetales en la Reserva de la Biosfera Mariposa Monarca que nos indiquen si las comunidades arbóreas corresponden o no a una misma cama de combustible. Para lo cual se quemó la capa de hojarasca de las comunidades arbóreas de oyamel, pino-oyamel y pino-encino. También se usó el programa CONSUME para calcular las emisiones de todos los estratos. Se obtuvo que la capa de hojarasca con menor emisión total correspondió a oyamel con 46 gr kg-1respecto a los 647 y 437 gr kg-1registrados en pino-oyamel y pino-encino, respectivamente, (p< 0.05). Se obtuvieron modelos de predicción de emisión de CO2, CO, CH4, NO2y NOXque explicaron el 74% de las emisiones generadas por las quemas. Con CONSUME se obtuvo mayor emisión en la comunidad de oyamel. La emisión presentó una correlación de 85% con el consumo, con 43% más de consumo en combustible de baja humedad respecto a los combustibles con alta humedad. Las comunidades integradas por pino no presentaron variación de emisión, pero la elevada carga de combustibles influyó en una alta emisión, por lo que la reducción de la carga de combustibles reduciría significativamente la presencia y potencial de un incendio forestal, así como las emisiones.
- English
  The forest fires consume large amounts of forest fuel and emit greenhouse gases into the atmosphere, mainly CO2 and CO. The objective of this work was to calculate the emission from burning of the litter layer, and to calculate the emissions considering all vegetation strata in the Mariposa Monarch Biosphere Reserve to Indicate If the arboreal community correspond or not to same fuelbeds. For this purpose, the litter layer in arboreal community the oyamel, pine-oyamel and pine-oak was burned. The CONSUME program was used to calculate emissions of all the strata. It was obtained that the litter layer with the lowest total emissions corresponded to fir with 46 g kg-1 compared to 647, and 437 g kg-1 recorded in pine-fir and pine-oak, respectively (p< 0.05). Emission prediction models were obtained for CO2, CO, CH4, NO2 and NOX, which explained 74% of the emissions generated from burning. With CONSUME, the oyamel community obtained higher emissions. The emission presented a correlation of 85% with consumption, with 43% higher consumption in low humidity fuels compared to high humidity fuels. Communities composed of pine did not show any variation in emissions, the high fuel load influences a high emission from a fire, so that a higher emission from a fire can be expected.
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