Evaluation of the carbon content of aerosols from the burning of biomass in the Brazilian Amazon using thermal, optical and thermal-optical analysis methods

Soto-Garcia, LL; Andreae, M. O.; Andreae, T. W.; Artaxo, Paulo; Maenhaut, Willy; Kirchstetter, Thomas W.; Novakov, T.; Chow, J. C.; Mayol-Bracero, O.

doi:10.5194/acp-11-4425-2011

Cited by 24 publications

(10 citation statements)

References 85 publications

(128 reference statements)

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“…Over half of it is volatile upon heating to 360 • C and largely water soluble (Soto-García et al, 2011). Even greater OC fractions were observed in the wet season (Gunthe et al, 2009) and both periods reveal a larger OC fraction (up to 90 %) in the Aitken size range.…”

Section: Discussionmentioning

confidence: 93%

“…The relative impact on boundary layer CCN in this distant region will depend upon the precursors that are available to influence growth to CCN sizes and/or what other aerosol and CCN are already present at this location (e.g., combustion aerosol). The mean FT size distribution above the inversion for higher CO has a mode diameter of about a factor of 2 smaller (about an order of magnitude less mass per particle) than observed in combustion outflow near SA using these same instruments (Moore II et al, 2003) and far smaller than sizes reported for Amazon biomass burning at the surface (Rissler et al, 2006;Soto-García et al, 2011). However, deep convection over the Amazon has been found to loft aerosol to 10 km while scavenging about 90 % of the accumulation mode before advection out over the Pacific (Andreae et al, 2001).…”

Section: Discussionmentioning

confidence: 98%

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Free troposphere as a major source of CCN for the equatorial pacific boundary layer: long-range transport and teleconnections

et al. 2013

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Airborne aerosol measurements in the central equatorial Pacific during PASE (Pacific Atmospheric Sulfur Experiment) revealed that cloud condensation nuclei (CCN) activated in marine boundary layer (MBL) clouds were strongly influenced by entrainment from the free troposphere (FT). About 65% entered at sizes effective as CCN in MBL clouds, while ~25% entered the MBL too small to activate but subsequently grew via gas to particle conversion. The remaining ~10% were inferred to be sea salt aerosol.

FT aerosols at low carbon monoxide (CO) mixing ratios (< 63 ppbv) were mostly volatile at 360 °C with a number mode peak of around 30–40 nm dry diameter and tended to be associated with cloud outflow from distant (3000 km or more) deep convection. Higher CO concentrations were commonly associated with trajectories from South America and the Amazon region (ca. ~10 000 km away) and occurred in layers indicative of combustion sources (biomass burning season) partially scavenged by precipitation. These had number modes near 60–80 nm dry diameter with a large fraction of CCN.2 (those activated at 0.2% supersaturation and representative of MBL clouds) prior to entrainment into the MBL. Flight averaged concentrations of CCN.2 were similar for measurements near the surface, below the inversion and in the FT just above the inversion, confirming that subsidence and entrainment of FT aerosol strongly influenced MBL CCN.2. Concurrent flight-to-flight variations of CCN.2 at all altitudes below 3 km also imply MBL CCN.2 concentrations were in quasi-equilibrium with the FT over a 2–3 day timescale.

The observed FT transport over thousands of kilometers indicates teleconnections between MBL CCN and cloud-scavenged sources of both natural and/or residual combustion origin. Nonetheless, in spite of its importance, this source of CCN number is not well represented in most current models and is generally not detectable by satellite because of the low aerosol scattering in such layers as a result of cloud scavenging. In addition, our measurements confirm nucleation in the MBL was not evident during PASE and argue against a localized linear relation in the MBL between dimethyl sulfide (DMS) and CCN suggested by the CLAW hypothesis. However, when the FT is not impacted by long-range transport, sulfate aerosol derived from DMS pumped aloft in the ITCZ (Inter-Tropical Convergence Zone) can provide a source of CCN to the boundary layer via FT teleconnections involving more complex non-linear processes

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Section: Discussionmentioning

confidence: 93%

Section: Discussionmentioning

confidence: 98%

Free troposphere as a major source of CCN for the equatorial pacific boundary layer: long-range transport and teleconnections

et al. 2013

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“…We run the broadband and narrowband detectors with staggered gains and combine the signals from the high-gain broadband output with the low-gain narrowband output in order to maximize the detectable BC mass (per particle) range. The band ratio, calculated from the ratio of the broadband to narrowband signals, depends on the boiling-point temperature and the spectral emissivity of the incandescent material, thus providing information to distinguish BC particles from, e.g., metal particles (Stephens et al, 2003). The calibration of the SP2 was conducted up to a mass of 70 fg BC.…”

Section: Nebulizer/sp2-setupmentioning

confidence: 99%

“…Ice cores offer a unique medium to study the variability of BC concentrations over long time periods, but analyses that require large sample volumes result in low time (or depth) resolution. Furthermore, the filter-based methods have the potential to over-or underestimate the BC mass concentration due to analytical artifacts, such as charring of organic carbon (Soto-García et al, 2011), dust interference (Wang et al, 2012) or filter efficiency (Torres et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Optimized method for black carbon analysis in ice and snow using the Single Particle Soot Photometer

Wendl¹,

Menking²,

Farber³

et al. 2014

Preprint

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Abstract. In this study we attempt to optimize the method for measuring black carbon (BC) in snow and ice using a single particle soot photometer (SP2). Beside the previously applied ultrasonic (CETAC) and Collison-type nebulizers we introduce a jet (APEX-Q) nebulizer to aerosolize the aqueous sample for SP2 analysis. Both CETAC and APEX-Q require small sample volumes (few milliliters) which makes them suitable for ice core analysis. The APEX-Q shows the least size-dependent nebulizing efficiency in the BC particle diameter range of 100–1000 nm. The CETAC has the advantage that air and liquid flows can be monitored continuously. All nebulizer-types require a calibration with BC standards for the determination of the BC mass concentration in unknown aqueous samples. We found Aquadag to be a suitable material for preparing calibration standards. Further, we studied the influence of different treatments for fresh discrete snow and ice samples as well as the effect of storage. The results show that samples are best kept frozen until analysis. Once melted, they should be sonicated for 25 min, immediately analyzed while being stirred and not be refrozen.

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“…BC has been studied in Antarctic snow since the late 1980s and early 1990s (Chýlek et al, 1987(Chýlek et al, , 1992Warren and Clarke, 1990). These initial studies used filter-based methods, which could under-or overestimate BC concentrations due to some analytical artifacts (Soto-García et al, 2011;Torres et al, 2014;Wang et al, 2012). Studies using the SP2 started appearing more than two decades later, aiming at recent snow rBC concentrations (Casey et al, 2017;Khan et al, 2019), near-surface air (Khan et al, 2018), recent-past ice cores (couple centuries - Bisiaux et al, 2012aBisiaux et al, , 2012b and the past millennia (Arienzo et al, 2017).…”

Section: Comparison With Other Rbc Records In Antarcticamentioning

confidence: 99%

Refractory Black carbon (rBC) variability in a 47-year West Antarctic Snow and Firn core

Marquetto¹,

Kaspari²,

Simões³

2019

Preprint

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Abstract. Black carbon (BC) is an important climate-forcing agent that affects snow albedo. In this work, we present a record of refractory black carbon (rBC) variability, measured from a 20-meter deep snow and firn core drilled in West Antarctica (79°55'34.6"S, 94°21'13.3"W) during the 2014–2015 austral summer. The core was analyzed using a Single Particle Soot Photometer (SP2) coupled to a CETAC Marin-5 nebulizer. Results show a well-defined seasonality with geometric mean concentrations of 0.015 µg L−1 for the wet season (summer/fall) and 0.057 µg L−1 for the dry season (winter/spring). The core was dated to 47 years (1968–2015) using rBC seasonality as the main parameter, along with Na, S and Sr variations. The annual rBC concentration geometric mean was 0.03 µg L−1, the lowest of all rBC cores in Antarctica referenced in this work, while the annual rBC flux was 6.25 µg m−2 a−1, the lowest flux in West Antarctica records so far. No long-term trend was observed. Snow albedo changes in the site due to BC were simulated using SNICAR-online and found to be very low comparing to clean snow (−0.48 %). Fire spots inventory and BC emission estimates from the Southern Hemisphere suggest Australia and Southern Hemisphere South America as the most probable emission sources of BC to the drilling site. Spectral analysis (REDFIT method) of the BC record showed cycles related to the Antarctic Oscillation (AAO) but not to El Niño Southern Oscillation ENSO, and comparison with time series of co-registered Na record suggest BC transport to the site not to be related to the intrusion of marine air masses.

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Evaluation of the carbon content of aerosols from the burning of biomass in the Brazilian Amazon using thermal, optical and thermal-optical analysis methods

Cited by 24 publications

References 85 publications

Free troposphere as a major source of CCN for the equatorial pacific boundary layer: long-range transport and teleconnections

Free troposphere as a major source of CCN for the equatorial pacific boundary layer: long-range transport and teleconnections

Optimized method for black carbon analysis in ice and snow using the Single Particle Soot Photometer

Refractory Black carbon (rBC) variability in a 47-year West Antarctic Snow and Firn core

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