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1. Biomass Production a Stronger Driver of Cellulosic Ethanol Yield than Biomass Quality

   https://doi.org/10.2134/agronj2016.08.0454  

   Sanford, Gregg R.; Oates, Lawrence G.; Roley, Sarah S.; Duncan, David S.; Jackson, Randall D.; Robertson, G. Philip; Thelen, Kurt D. (January 2017, Agronomy Journal)
2. A woody biomass burial

   https://doi.org/10.1126/science.ads2592  

   Yao, Yuan (September 2024, Science)

   Ancient, buried wood points to a possible low-cost method to store carbon 

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3. Biomass combustion produces ice-active minerals in biomass-burning aerosol and bottom ash

   https://doi.org/10.1073/pnas.1922128117  

   Jahn, Leif G.; Polen, Michael J.; Jahl, Lydia G.; Brubaker, Thomas A.; Somers, Joshua; Sullivan, Ryan C. (September 2020, Proceedings of the National Academy of Sciences)

   null (Ed.)

   Ice nucleation and the resulting cloud glaciation are significant atmospheric processes that affect the evolution of clouds and their properties including radiative forcing and precipitation, yet the sources and properties of atmospheric ice nucleants are poorly constrained. Heterogeneous ice nucleation caused by ice-nucleating particles (INPs) enables cloud glaciation at temperatures above the homogeneous freezing regime that starts near −35 °C. Biomass burning is a significant global source of atmospheric particles and a highly variable and poorly understood source of INPs. The nature of these INPs and how they relate to the fuel composition and its combustion are critical gaps in our understanding of the effects of biomass burning on the environment and climate. Here we show that the combustion process transforms inorganic elements naturally present in the biomass (not soil or dust) to form potentially ice-active minerals in both the bottom ash and emitted aerosol particles. These particles possess ice-nucleation activities high enough to be relevant to mixed-phase clouds and are active over a wide temperature range, nucleating ice at up to −13 °C. Certain inorganic elements can thus serve as indicators to predict the production of ice nucleants from the fuel. Combustion-derived minerals are an important but understudied source of INPs in natural biomass-burning aerosol emissions in addition to lofted primary soil and dust particles. These discoveries and insights should advance the realistic incorporation of biomass-burning INPs into atmospheric cloud and climate models. These mineral components produced in biomass-burning aerosol should also be studied in relation to other atmospheric chemistry processes, such as facilitating multiphase chemical reactions and nutrient availability. 

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4. Refractive Indices of Biomass Burning Aerosols Obtained from African Biomass Fuels Using RDG Approximation

   https://doi.org/10.3390/atmos11010062  

   Sarpong, Emmanuel; Smith, Damon; Pokhrel, Rudra; Fiddler, Marc N.; Bililign, Solomon (January 2020, Atmosphere)

   null (Ed.)

   Biomass burning (BB) aerosols contribute to climate forcing, but much is still unknown about the extent of this forcing, owing partially to the high level of uncertainty regarding BB aerosol optical properties. A key optical parameter is the refractive index (RI), which influences the absorbing and scattering properties of aerosols. This quantity is not measured directly, but it is obtained by fitting the measured scattering cross section and extinction cross section to a theoretical model using the RI as a fitting parameter. We used the Rayleigh–Debye–Gans (RDG) approximation to retrieve the complex RI of freshly emitted BB aerosol from two fuels (eucalyptus and olive) from Africa in the spectral range of 500–580 nm. Experimental measurements were carried out using cavity ring-down spectroscopy to measure extinction over the range of wavelengths of 500–580 nm and nephelometry to measure scattering at three wavelengths of 450, 550, and 700 nm for size-selected BB aerosol particles. The fuels were combusted in a tube furnace at a temperature of 800 °C, which is representative of the flaming stage of burning. Filter samples were collected and imaged using tunneling electron microscopy to obtain information on the morphology and size of the particles, which was used in the RDG calculations. The mean radii of the monomers were 27.8 and 31.5 nm for the eucalyptus and the olive fuels, respectively. The components of the retrieved complex RI were in the range of 1.31 ≤ n ≤ 1.56 and 0.045 ≤ k ≤ 0.468. The real and complex parts of the RI increase with increasing particle mobility diameter. The real part of the RI is lower, and the imaginary part is higher than what was recommended in literature for black carbon generated by propane or field measurements from fires of mixed wood samples. Fuel dependent results from controlled laboratory experiments can be used in climate modeling efforts and to constrain field measurements from biomass burning. 

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5. Ionic Liquids in Biomass Processing

   https://doi.org/10.1002/ijch.201800140  

   Amarasekara, Ananda S. (November 2018, Israel Journal of Chemistry)