Lowenthal Douglas, Zielinska Barbara, Samburova Vera, Collins Don, Taylor Nathan, Kumar Naresh
a Desert Research Institute , Reno , NV , USA.
J Air Waste Manag Assoc. 2015 Mar;65(3):249-60. doi: 10.1080/10962247.2014.986307.
Studies were conducted at Great Smoky Mountains National Park (NP) (GRSM), Tennessee, Mount Rainier NP (MORA), Washington, and Acadia NP (ACAD), Maine, to evaluate assumptions used to estimate aerosol light extinction from chemical composition. The revised IMPROVE equation calculates light scattering from concentrations of PM2.5 sulfates, nitrates, organic carbon mass (OM), and soil. Organics are assumed to be nonhygroscopic. Organic carbon (OC) is converted to OM with a multiplier of 1.8. Experiments were conducted to evaluate assumptions on aerosol hydration state, the OM/OC ratio, OM hygroscopicity, and mass scattering efficiencies. Sulfates were neutralized by ammonium during winter at GRSM (W, winter) and at MORA during summer but were acidic at ACAD and GRSM (S, summer) during summer. Hygroscopic growth was mostly smooth and continuous, rarely exhibiting hysteresis. Deliquescence was not observed except infrequently during winter at GRSM (W). Water-soluble organic carbon (WSOC) was separated from bulk OC with solid-phase absorbents. The average OM/OC ratios were 2.0, 2.7, 2.1, and 2.2 at GRSM (S), GRSM (W), MORA, and ACAD, respectively. Hygroscopic growth factors (GF) at relative humidity (RH) 90% for aerosols generated from WSOC extracts averaged 1.19, 1.06, 1.13, and 1.16 at GRSM (S), GRSM (W), MORA, and ACAD, respectively. Thus, the assumption that OM is not hygroscopic may lead to underestimation of its contribution to light scattering.
Studies at IMPROVE sites conducted in U.S. national parks showed that aerosol organics comprise more PM2.5 mass and absorb more water as a function of relative humidity than is currently assumed by the IMPROVE equation for calculating chemical light extinction. Future strategies for reducing regional haze may therefore need to focus more heavily on understanding the origins and control of anthropogenic sources of organic aerosols.
在美国田纳西州的大烟山国家公园(GRSM)、华盛顿州的雷尼尔山国家公园(MORA)和缅因州的阿卡迪亚国家公园(ACAD)开展了研究,以评估用于根据化学成分估算气溶胶光消光的假设。修订后的IMPROVE方程根据细颗粒物(PM2.5)中硫酸盐、硝酸盐、有机碳质量(OM)和土壤的浓度来计算光散射。假定有机物不具有吸湿性。有机碳(OC)通过乘以1.8的系数转换为OM。开展了实验来评估关于气溶胶水合状态、OM/OC比率、OM吸湿性和质量散射效率的假设。在大烟山国家公园冬季(W,冬季)以及雷尼尔山国家公园夏季期间,硫酸盐被铵中和,但在夏季,阿卡迪亚国家公园和大烟山国家公园(S,夏季)的硫酸盐呈酸性。吸湿增长大多是平滑且连续的,很少表现出滞后现象。除了在大烟山国家公园冬季(W)偶尔出现外,未观察到潮解现象。用水溶性有机碳(WSOC)与固相吸附剂从总OC中分离出WSOC。在大烟山国家公园(S)、大烟山国家公园(W)、雷尼尔山国家公园和阿卡迪亚国家公园,平均OM/OC比率分别为2.0、2.7、2.1和2.2。由WSOC提取物产生的气溶胶在相对湿度(RH)为90%时的吸湿增长因子(GF)在大烟山国家公园(S)、大烟山国家公园(W)、雷尼尔山国家公园和阿卡迪亚国家公园分别平均为1.19、1.06、1.13和1.16。因此,OM不具有吸湿性这一假设可能会导致低估其对光散射的贡献。
在美国国家公园的IMPROVE站点开展的研究表明,与目前用于计算化学光消光的IMPROVE方程所假定的情况相比,气溶胶有机物占细颗粒物(PM2.5)质量的比例更大,并且作为相对湿度的函数吸收的水分更多。因此,未来减少区域雾霾的策略可能需要更加侧重于了解有机气溶胶人为源的来源和控制。
