Aerosol particles experience hygroscopic growth in the ambient atmosphere. Their optical properties – especially the aerosol light scattering – are therefore strongly dependent on the ambient relative humidity (RH). In-situ light scattering measurements of long-term observations are usually performed under dry conditions (RH>30–40%). The knowledge of this RH effect is of eminent importance for climate forcing calculations or for the comparison of remote sensing with in-situ measurements. This study combines measurements and model calculations to describe the RH effect on aerosol light scattering for the first time for aerosol particles present in summer and fall in the high Arctic. For this purpose, a field campaign was carried out from July to October 2008 at the Zeppelin station in Ny-?lesund, Svalbard. The aerosol light scattering coefficient σsp(λ) was measured at three distinct wavelengths (λ=450, 550, and 700 nm) at dry and at various, predefined RH conditions between 20% and 95% with a recently developed humidified nephelometer (WetNeph) and with a second nephelometer measuring at dry conditions with an average RH<10% (DryNeph). In addition, the aerosol size distribution and the aerosol absorption coefficient were measured. The scattering enhancement factor f(RH, λ) is the key parameter to describe the RH effect on σsp(λ) and is defined as the RH dependent σsp(RH, λ) divided by the corresponding dry σsp(RHdry, λ). During our campaign the average f(RH=85%, λ=550 nm) was 3.24±0.63 (mean ± standard deviation), and no clear wavelength dependence of f(RH, λ) was observed. This means that the ambient scattering coefficients at RH=85% were on average about three times higher than the dry measured in-situ scattering coefficients. The RH dependency of the recorded f(RH, λ) can be well described by an empirical one-parameter equation. We used a simplified method to retrieve an apparent hygroscopic growth factor g(RH), defined as the aerosol particle diameter at a certain RH divided by the dry diameter, using the WetNeph, the DryNeph, the aerosol size distribution measurements and Mie theory. With this approach we found, on average, g(RH=85%) values to be 1.61±0.12 (mean±standard deviation). No clear seasonal shift of f(RH, λ) was observed during the 3-month period, while aerosol properties (size and chemical composition) clearly changed with time. While the beginning of the campaign was mainly characterized by smaller and less hygroscopic particles, the end was dominated by larger and more hygroscopic particles. This suggests that compensating effects of hygroscopicity and size determined the temporal stability of f(RH, λ). During sea salt influenced periods, distinct deliquescence transitions were observed. At the end we present a method on how to transfer the dry in-situ measured aerosol scattering coefficients to ambient values for the aerosol measured during summer and fall at this location.
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机译:气溶胶颗粒在环境大气中经历吸湿性增长。因此,它们的光学特性(尤其是气溶胶光散射)在很大程度上取决于环境相对湿度(RH)。长期观察的原位光散射测量通常在干燥条件下(RH> 30–40%)进行。对RH效应的了解对于气候强迫计算或遥感与现场测量的比较非常重要。这项研究结合了测量和模型计算,首次描述了夏季和秋季高北极地区出现的气溶胶颗粒对RH对气溶胶光散射的影响。为此,2008年7月至10月在斯瓦尔巴特群岛Ny-?lesund的Zeppelin站进行了野战。气溶胶的光散射系数σ sp (λ)在干燥和各种预定义的RH条件(介于20%和95%之间)的三个不同波长(λ= 450、550和700 nm)下测量,最近开发的加湿浊度计(WetNeph)以及第二个浊度计在干燥条件下进行测量,平均相对湿度<10%(DryNeph)。另外,测量了气溶胶尺寸分布和气溶胶吸收系数。散射增强因子 f (RH,λ)是描述RH对σ sp (λ)的影响的关键参数,并定义为与RH相关的σ sp (RH,λ)除以相应的干σ sp (RH dry ,λ)。在我们的宣传活动中,平均 f (RH = 85%,λ= 550 nm)为3.24±0.63(平均值±标准偏差),并且 f (观察到RH,λ)。这意味着RH = 85%时的环境散射系数平均要比干法测量的原位散射系数高大约三倍。记录的f(RH,λ)的RH依赖性可以通过经验的一参数方程很好地描述。我们使用WetNeph,DryNeph和气溶胶尺寸,使用一种简化的方法来检索表观吸湿性生长因子 g (RH),定义为特定RH下的气溶胶粒径除以干直径。分布测量和米氏理论。通过这种方法,我们发现平均 g (RH = 85%)值为1.61±0.12(平均值±标准偏差)。在三个月的时间内,没有观察到明显的f(RH,λ)季节性变化,而气溶胶特性(尺寸和化学组成)则随时间明显变化。虽然运动的开始主要以较小和较少吸湿的颗粒为特征,但结束时以较大和较多吸湿的颗粒为主导。这表明吸湿性和尺寸的补偿作用决定了 f (RH,λ)的时间稳定性。在海盐影响期间,观察到明显的潮解转变。最后,我们提出了一种方法,该方法如何将干燥的原位测量气溶胶散射系数转换为夏季和秋季在此位置测得的气溶胶的环境值。
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