Supplement of Atmos. Meas. Tech., 8, 45 46, 25 http://www.atmos-meas-tech.net/8/45/25/ doi:.594/amt-8-45-25-supplement Author(s) 25. CC Attribution 3. License. Supplement of Multi-wavelength optical measurement to enhance thermal/optical analysis for carbonaceous aerosol L.-W. A. Chen et al. Correspondence to: L.-W. A. Chen (antony.chen@unlv.edu)
Table S. List of abbreviations and acronyms used in the paper. Abbreviations/Acronyms Descriptions A Filter sampling area ATN, ATN λ Transmittance attenuation (general, at wavelength λ) BC, BC d Black carbon (general, diesel elemental carbon equivalent) BrC Brown carbon CV-RMSR Coefficient of variance of root mean square residual EC, ECR, ECR λ, ECT, ECT λ, [EC] Elemental carbon (general, reflectance adjusted, reflectance adjusted at wavelength λ, transmittance adjusted, transmittance adjusted at wavelength λ, areal concentration on filter) He Helium IMPROVE Interagency Monitoring of Protected Visual Environments MAE, MAE, MAE,EC Mass absorption efficiency (general, at wavelength λ, of elemental carbon at wavelength λ) Multiple scattering effect coefficient at wavelength λ M Ne OC, OCR, OCT, OCR λ, OCT λ Neon Organic carbon (general, reflectance adjusted, reflectance adjusted at wavelength λ, transmittance adjusted, transmittance adjusted at wavelength λ) PM, PM 2.5 Particulate matter (general, less 2.5 µm aerodynamic diameter) POC Pyrolyzed organic carbon R, LR, LR, FR, FR Reflectance (general, laser relative, laser relative at wavelength λ, filter absolute, filter absolute at wavelength λ) RD Relative difference T, LT, LT, FT, FT, FT,i, FT,f Transmittance (general, laser relative, laser relative at wavelength λ, filter absolute, filter absolute at wavelength λ, filter absolute at wavelength λ before thermal analysis, filter absolute at wavelength λ after thermal analysis) TC Total carbon TOA Thermal/optical analysis TSA Thermal/spectral analysis V Filter sampling volume α, α( ), BC, BrC Absorption Ångström exponent (general, at wavelength λ, of black carbon, of brown carbon) b Regression intercept b abs Absorption coefficient m Regression slope p T-test p value β Shadowing effect coefficient at wavelength λ Wavelength τ a, τ a,, τ a,λ,bc, τ a,λ,brc Absorption optical depth (general, at wavelength λ, at wavelength λ due to black carbon, at wavelength λ due to brown carbon) 2
Lasers 45 98 nm 8-Leg Optical Fibers Filter Sample Heated up to 84 C Tranmittance Photodiode Reflectance Photodiode Quartz Light Pipes 9 8 LR & LT 7 6 5 4 3 2 5 98 78 45 6 5 4 3 5 9 6 4 3 2. Filter Reflectance & Transmittance (FR & FT) 7 98 78 45 88 45 8 FR. FT 6 5 4 3 2. 5 9 7.. 5 5 (d) FT 8. 2 5. 7 5 FR. 9 8 Filter Reflectance & Transmittance (FR & FT) 88 45 (c) 98 78 45 LR & LT 88 45 Laser Reflectance & Transmittance mv) (LR & LT in mv 88 45 Laser Reflectance & Transmittance mv (LR & LT in mv) 98 78 45 (b) (a) 5 5 (e) (f) Figure S. Configuration of (a) the multi-wavelength module and (b) interface to a thermal/optical carbon Analyzer. Example of typical thermal/spectral analysis (TSA) thermogram for: (c) Fresno ambient and (d) diesel exhaust samples. Laser reflectance (LR, solid lines) and transmittance (LT, dashed lines) at 7 wavelengths (45, 45,,, 78, 88, and 98 nm) are reported in millivolts (mv) as detected by the photodiodes. Absolute filter reflectance and transmittance (FR /FT ) for (c) and (d) are shown in (e) and (f), respectively, after calibrating LR and LT against reflectance and transmittance measurements by the Lambda 35 integrating-sphere spectrometer. FR is between. and (i.e., %) while FT is generally <. (%). The temperature steps follow the IMPROVE_A protocol: OC (4 C), OC2 (28 C), OC3 (48 C), OC4 (58 C), EC (58 C), EC2 (74 C), and EC3 (84 C) with oxygen introduced at the beginning of EC. The last carbon peak corresponds to the internal methane standard. 3
Reflectance (%) Transmittance (%) 8 7 FSH65 %R FSH74 %R 6 FSH77 %R 5 FSH99 %R 4 FSH22 %R 3 FSH73 %R FSH7 %R 2 FSH8 %R 2 4 6 8 2 4 Wavelength (nm) Reflectance (b) (a) 2 FSH65 %T 8 FSH74 %T FSH77 %T 6 FSH99 %T 4 FSH22 %T FSH73 %T 2 FSH7 %T FSH8 %T 2 4 6 8 2 4 Wavelength (nm) Transmittance (c) Figure S2. (a) Fresno Supersite PM 2.5 samples acquired from year 23 serving as transfer standards for calibrating the reflectance and transmittance measurement of a multi-wavelength carbon analyzer. Also shown are the spectral (b) reflectance and (c) transmittance of these samples as quantified by an integrating-sphere spectrometer (Lambda 35, Perkin Elmer, Massachusetts, USA). Dashed lines correspond to wavelengths of the thermal/spectral analysis by the multi-wavelength carbon analyzer. 4
EC Concentration (µg/cm 2 ) 5 2 9 6 98 88 78 y = 3.47x 2 +.x R² =. y = 2.53x 2 +.82x R² =. y = 2.39x 2 +.9x R² =. y =.7x 2 +.75x R² =. y =.77x 2 +.48x R² =.94 3 45 455 45 2 3 4 ATN y =.x 2 +.44x R² =. y =.87x 2 +.38x R² =. Figure S3. Calibration of ATN of the 7-wavelength carbon analyzer with EC loading ([EC]) measured during the EC2 step of IMPROVE_A analysis of a diesel exhaust sample (CIFQ74, acquired from the Gasoline/Diesel Split Study). Regressions are based on Eq. (6). Calculated τ a,.. 45 nm nm 88 nm.... Measured τ a, Figure S4. Measured τ a, (45,, and 88 nm are shown) compared with τ a, fitted from Eq. (7) assuming a two-component model. All samples in this study are included. 5
τ a,.6.4.2.8.6.4.2 y = 323.63x - R² = y = 2E+x -4.44 R² = 2 4 6 8 2 Wavelength λ (nm) (a) Measured BC Fraction BrC Fraction τ a,.6.4.2.8.6.4.2 y = 5E+2x -4.89 R² = y = 82.359x - R² = 2 4 6 8 2 Wavelength λ (nm) (b) Measured BC Fraction BrC Fraction Figure S5. Decomposition of measured absorption optical depth (τ a, ) from (a) Fresno ambient and (b) Reno wildfire samples into the BC and BrC contributions based on their distinct spectral dependence of light absorption. See text for details. 6