Varying relationships between fire radiative power and fire size at a global scale

Laurent, Pierre; Mouillot, Florent; Moreno, M. Vanesa; Ye, Chao; Ciais, Philippe

doi:10.5194/bg-16-275-2019

Cited by 55 publications

(32 citation statements)

References 71 publications

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“…Other than CRB incidences, the radiant heat output, i.e. fire intensity from each event, is also an important parameter ( Laurent et al., 2019 ). Therefore, the parameter FRP is helpful to estimate the pixel-integrated FRP (in megawatts; MW).…”

Section: Resultsmentioning

confidence: 99%

Impact of crop residue burning in Haryana on the air quality of Delhi, India

Saxena

Sonwani

Srivastava

et al. 2021

Heliyon

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Crop residue burning (CRB) over northern India is a major air quality and human health issue. The present study assesses the impact of PM 10 , PM 2.5 , NO 2 and SO 2 , emitted during CRB activities in Haryana on the air quality of Delhi. The transition from pre-burning to burning period, in both rabi and kharif seasons, shows considerable increase in pollutant concentrations. PM 10 and PM 2.5 concentrations exceeded NAAQS limits by 2–3 times, while NO 2 and SO 2 stayed within the limits. MODIS fire observations used to estimate CRB fire counts (confidence ≥80%) shows that rabi (burning period) fires in Haryana are ~3 times higher and more intense than in kharif. Furthermore, backward trajectories shows air mass movement from Haryana, Punjab and Pakistan. Thus, pollutants emitted reach Delhi via air masses, deteriorating its air quality. Meteorological conditions influence pollutant concentrations during both seasons. Frequent dust storms in rabi, and Dusshera and Diwali firework celebrations in kharif season exacerbate air pollution. In rabi, PM 10 and PM 2.5 have a significant negative association with (relative humidity) RH and positive association with (air temperature) AT. High AT during pre-monsoon, accompanied by low RH, loosens up soil particles and they can easily disperse. Stronger winds in rabi season promote NO 2 and SO 2 dispersion. In kharif, lower AT, higher RH and slower winds exist. Both PM 10 and PM 2.5 have a negative association with AT and (wind speed) WS. With lower temperature and slower winds during winter, pollutants are trapped within the boundary layer and are unable to disperse. As expected, NO 2 has a significant negative association with AT in Haryana. However, in case of Delhi, the association is significant but positive, and could be due to the odd-even scheme imposed by the Delhi government. More research is needed to determine the health effects of Haryana's rabi CRB activities on Delhi.

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Section: Resultsmentioning

confidence: 99%

Impact of crop residue burning in Haryana on the air quality of Delhi, India

Saxena

Sonwani

Srivastava

et al. 2021

Heliyon

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“…A global review of fire intensities by Laurent et al (2019) based on remote sensing data indicated that the largest and most intense fires occur in Australia, the grasslands of Kazakhstan, Namibia, the Sahel and Patagonia. High intensity fires also occur in the forested areas of the western United States and Boreal North America.…”

Section: Resultsmentioning

confidence: 99%

Unprecedented long-distance transport of macroscopic charcoal from a large, intense forest fire in eastern Australia: Implications for fire history reconstruction

Woodward

Haines

2020

The Holocene

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Macroscopic charcoal records from wetland sediment cores are used to reconstruct long-term records of fire frequency. A central premise for the use of this tool is that macroscopic charcoal (>125 μm) represents local fires involving local vegetation. Several records reveal that there may often be exceptions to these guidelines. Previous studies have shown that particles larger than 1 cm long can travel at least 20 km from the location of a fire. We present observations of unprecedented long-distance transport of large (⩽5 cm long) charcoal particles at least 50 km from a fire west of Sydney, Australia. Factors that contribute to long-distance transport of large charcoal particles are fire intensity, upper level wind speed and landscape topography. The fires west of Sydney were large and intense, upper level (~10 km) winds exceeded 90 km h-1, and the topography east of the fire was flat or undulating. Smoke plumes from intense fires like this can reach an altitude of at least 15 km. Charcoal morphology also contributed to long-distance transport in this case. Eucalyptus trees can produce large quantities of aerodynamically efficient particles; from paper thin, smooth, decorticating bark and large sclerophyllous leaves. The presence of large macroscopic charcoal particles in wetland sediments does not automatically indicate local fires and could result from distant, large, intense fires. Large, intense fires can occur in Australia, the grasslands of Kazakhstan, Namibia, the Sahel and Patagonia. High intensity fires also occur in the forested areas of the western United States and Boreal North America. Fires in these regions could result in long-distance transport of large macroscopic charcoal particles under the right circumstances. Local charcoal flux studies are therefore critical for the interpretation of macroscopic charcoal records. We cannot rely on information from areas with different fire regimes, fire intensities or vegetation types.

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“…YHR, the major wheat-producing area in China, is located in the vast flat plain in eastern China. Figure 1a shows the daily number of satellite fire counts in YHR, where cropland, especially wheat, dominates the vegetation cover (Gong et al, 2019;Lei and Yuan, 2013;Van Der Werf et al, 2010). The limited duration of agricultural fire combined with the low temporal resolution of MODIS may increase the difficulty of signal capture and lead to underestimation of fire counts Song, 2009, 2010;Giglio et al, 2009;Randerson et al, 2012;Yin et al, 2019).…”

Section: Fire-induced Surface Albedo Changementioning

confidence: 99%

“…The most concentrated area of burning in eastern China is the Yellow-Huai River area (YHR), which connects the middle and lower reaches of the Yellow River and Yangtze River. YHR is the major wheat-producing area in China (Lei and Yuan, 2013). An extremely typical pollution episode was triggered by BB emissions from YHR in June 2012, during which a yellow haze blanketed the Yangtze River Delta (YRD) (Ding et al, 2013a;Huang et al, 2012b;Xie et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Biomass-burning-induced surface darkening and its impact on regional meteorology in eastern China

et al. 2020

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Abstract. Biomass burning has attracted great concerns for the emission of particular matters and trace gases, which substantially impacts air quality, human health, and climate change. Meanwhile, large areas of dark char, carbon residue produced in incomplete combustion, can stick to the surface over fire-prone areas after open burning, leading to a sharp drop in surface albedo, so-called “surface darkening”. However, exploration into such surface albedo declines and the radiative and meteorological effects is still fairly limited. As one of the highest-yield agricultural areas, eastern China features intensive straw burning every early summer, the harvest season for winter wheat, which was particularly strong in 2012. Satellite retrievals show that the surface albedo decline over fire-prone areas was significant, especially in the near-infrared band, which can reach −0.16. Observational evidence of abnormal surface warming was found by comparing radiosonde and reanalysis data. Most sites around intensive burned scars show a positive deviation, extending especially in the downwind area. Comparisons between “pre-fire” and “post-fire” from 2007 to 2015 indicated a larger temperature bias of the forecast during the post-fire stage. The signal becomes more apparent between 14:00 and 20:00 LT. Weather Research and Forecasting model coupled with Chemistry (WRF-Chem) simulations suggest that including surface darkening can decrease model bias and well-captured temperature variation after burning at sites in fire areas and their adjacent area. This work highlights the importance of biomass burning induced albedo change in weather forecast and regional climate.

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Varying relationships between fire radiative power and fire size at a global scale

Cited by 55 publications

References 71 publications

Impact of crop residue burning in Haryana on the air quality of Delhi, India

Impact of crop residue burning in Haryana on the air quality of Delhi, India

Unprecedented long-distance transport of macroscopic charcoal from a large, intense forest fire in eastern Australia: Implications for fire history reconstruction

Biomass-burning-induced surface darkening and its impact on regional meteorology in eastern China

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