Your search keyword '"Kanaya, Yugo"' showing total 9 results

1. Implementation of HONO into the chemistry–climate model CHASER (V4.0): roles in tropospheric chemistry.

Author

Ha, Phuc Thi Minh, Kanaya, Yugo, Taketani, Fumikazu, Andrés Hernández, Maria Dolores, Schreiner, Benjamin, Pfeilsticker, Klaus, and Sudo, Kengo

Subjects

*TROPOSPHERIC chemistry, *ACID deposition, *TROPOSPHERIC ozone, *CHEMICAL models, *NITROUS acid, *GAS phase reactions

Abstract

Nitrous acid (HONO) is an important atmospheric gas given its contribution to the cycles of NO x and HO x , but its role in global atmospheric photochemistry is not fully understood. This study implemented three pathways of HONO formation in the chemistry–climate model CHASER (MIROC-ESM) to explore three physical phenomena: gas-phase kinetic reactions (GRs), direct emission (EM), and heterogeneous reactions on cloud and aerosol particles (HRs). We evaluated the simulations by the atmospheric aircraft-based measurements from EMeRGe-Asia-2018 (Effect of Megacities on the Transport and Transformation of Pollutants on the Regional to Global Scales), ATom-1 (atmospheric tomography), observations from the ship R/V Mirai, EANET (Acid Deposition Monitoring Network in eastern Asia)/EMEP (European Monitoring and Evaluation Programme) ground-based stationary observations, and the OMI (Ozone Monitoring Instrument). We showed that the inclusion of the HONO chemistry in the modelling process reduced the model bias against the measurements for PM 2.5 , NO 3- /HNO 3 , NO 2 , OH, HO 2 , O 3 , and CO, especially in the lower troposphere and the North Pacific (NP) region. We found that the retrieved global abundance of tropospheric HONO was 1.4 TgN. Of the three source pathways, HRs and EM contributed 63 % and 26 % to the net HONO production, respectively. We also observed that reactions on the aerosol surfaces contributed larger amounts of HONO (51 %) than those on the cloud surfaces (12 %). The model exhibited significant negative biases for daytime HONO in the Asian off-the-coast region, compared with the airborne measurements by EMeRGe-Asia-2018, indicating the existence of unknown daytime HONO sources. Strengthening of aerosol uptake of NO 2 near the surface and in the middle troposphere, cloud uptake, and direct HONO emission were all potential yet-unknown HONO sources. The most promising daytime source for HONO found in this study was the combination of enhanced aerosol uptake of NO 2 and surface-catalysed HNO 3 photolysis (maxST + JANO3-B case), which could also remedy the model bias for NO 2 and O 3 during EMeRGe. We also found that the simulated HONO abundance and its impact on NO x –O 3 chemistry were sensitive to the yield of the heterogeneous conversion of NO 2 to HONO (vs. HNO 3). Inclusion of HONO reduced global tropospheric NO x (NO + NO 2) levels by 20.4 %, thereby weakening the tropospheric oxidizing capacity (OH, O 3) occurring for NO x -deficit environments (remote regions and upper altitudes), which in turn increased CH 4 lifetime (13 %) and tropospheric CO abundance (8 %). The calculated reduction effect on the global ozone level reduced the model overestimates for tropospheric column ozone against OMI spaceborne observations for a large portion of the North Hemisphere. HRs on the surfaces of cloud particles, which have been neglected in previous modelling studies, were the main drivers of these impacts. This effect was particularly salient for the substantial reductions of levels of OH (40 %–67 %) and O 3 (30 %–45 %) in the NP region during summer, given the significant reduction of the NO x level (50 %–95 %). In contrast, HRs on aerosol surfaces in China (Beijing) enhanced OH and O 3page928 winter mean levels by 600 %–1700 % and 10 %–33 %, respectively, with regards to their minima in winter. Furthermore, sensitivity simulations revealed that the heterogeneous formation of HONO from NO 2 and heterogenous photolysis of HNO 3 coincided in the real atmosphere. Nevertheless, the global effects calculated in the combined case (enhancing aerosol uptakes of NO 2 and implementing heterogeneous photolysis of HNO 3), which most captured the measured daytime HONO level, still reduced the global tropospheric oxidizing capacity. Overall, our findings suggest that a global model that does not consider HONO heterogeneous mechanisms (especially photochemical heterogeneous formations) may erroneously predict the effect of HONO in remote areas and polluted regions. [ABSTRACT FROM AUTHOR]

Published

2023

2. Dominance of the residential sector in Chinese black carbon emissions as identified from downwind atmospheric observations during the COVID-19 pandemic.

Author

Kanaya, Yugo, Yamaji, Kazuyo, Miyakawa, Takuma, Taketani, Fumikazu, Zhu, Chunmao, Choi, Yongjoo, Ikeda, Kohei, Tanimoto, Hiroshi, Yamada, Daichi, Narita, Daiju, Kondo, Yutaka, and Klimont, Zbigniew

Subjects

*CARBON emissions, *CARBON-black, *COVID-19 pandemic, *SOOT, *CLIMATE change & health, *COVID-19, *POLLUTION control costs

Abstract

Emissions of black carbon (BC) particles from anthropogenic and natural sources contribute to climate change and human health impacts. Therefore, they need to be accurately quantified to develop an effective mitigation strategy. Although the spread of the emission flux estimates for China have recently narrowed under the constraints of atmospheric observations, consensus has not been reached regarding the dominant emission sector. Here, we quantified the contribution of the residential sector, as 64% (44–82%) in 2019, using the response of the observed atmospheric concentration in the outflowing air during Feb–Mar 2020, with the prevalence of the COVID-19 pandemic and restricted human activities over China. In detail, the BC emission fluxes, estimated after removing effects from meteorological variability, dropped only slightly (− 18%) during Feb–Mar 2020 from the levels in the previous year for selected air masses of Chinese origin, suggesting the contributions from the transport and industry sectors (36%) were smaller than the rest from the residential sector (64%). Carbon monoxide (CO) behaved differently, with larger emission reductions (− 35%) in the period Feb–Mar 2020, suggesting dominance of non-residential (i.e., transport and industry) sectors, which contributed 70% (48–100%) emission during 2019. The estimated BC/CO emission ratio for these sectors will help to further constrain bottom-up emission inventories. We comprehensively provide a clear scientific evidence supporting mitigation policies targeting reduction in residential BC emissions from China by demonstrating the economic feasibility using marginal abatement cost curves. [ABSTRACT FROM AUTHOR]

Published

2021

3. A new TROPOMI product for tropospheric NO2 columns over East Asia with explicit aerosol corrections.

Author

Liu, Mengyao, Lin, Jintai, Kong, Hao, Boersma, K. Folkert, Eskes, Henk, Kanaya, Yugo, He, Qin, Tian, Xin, Qin, Kai, Xie, Pinhua, Spurr, Robert, Ni, Ruijing, Yan, Yingying, Weng, Hongjian, and Wang, Jingxu

Subjects

TROPOSPHERIC aerosols, TROPOSPHERIC ozone, AEROSOLS, NEW product development, NITROGEN dioxide, CONCENTRATION gradient

Abstract

We present a new product with explicit aerosol corrections, POMINO-TROPOMI, for tropospheric nitrogen dioxide (NO2) vertical column densities (VCDs) over East Asia, based on the newly launched TROPOspheric Monitoring Instrument with an unprecedented high horizontal resolution. Compared to the official TM5-MP-DOMINO (OFFLINE) product, POMINO-TROPOMI shows stronger concentration gradients near emission source locations and better agrees with MAX-DOAS measurements (R2=0.75 ; NMB=0.8 % versus R2=0.68 , NMB=-41.9 %). Sensitivity tests suggest that implicit aerosol corrections, as in TM5-MP-DOMINO, lead to underestimations of NO2 columns by about 25 % over the polluted northern East China region. Reducing the horizontal resolution of a priori NO2 profiles would underestimate the retrieved NO2 columns over isolated city clusters in western China by 35 % but with overestimates of more than 50 % over many offshore coastal areas. The effect of a priori NO2 profiles is more important under calm conditions. [ABSTRACT FROM AUTHOR]

Published

2020

4. Rapid reduction in black carbon emissions from China: evidence from 2009–2019 observations on Fukue Island, Japan.

Author

Kanaya, Yugo, Yamaji, Kazuyo, Miyakawa, Takuma, Taketani, Fumikazu, Zhu, Chunmao, Choi, Yongjoo, Komazaki, Yuichi, Ikeda, Kohei, Kondo, Yutaka, and Klimont, Zbigniew

Subjects

CARBON-black, ATMOSPHERIC chemistry, METEOROLOGICAL research, WEATHER forecasting, PARTICULATE matter, EMISSION inventories, SOOT, AIR masses

Abstract

A long-term, robust observational record of atmospheric black carbon (BC) concentrations at Fukue Island for 2009–2019 was produced by unifying the data from a continuous soot monitoring system (COSMOS) and a Multi-Angle Absorption Photometer (MAAP). This record was then used to analyze emission trends from China. We identified a rapid reduction in BC concentrations of (-5.8±1.5) % yr -1 or - 48 % from 2010 to 2018. We concluded that an emission change of (-5.3±0.7) % yr -1 , related to changes in China of as much as -4.6 % yr -1 , was the main underlying driver. This evaluation was made after correcting for the interannual meteorological variability (IAV) by using the regional atmospheric chemistry model simulations from the Weather Research and Forecasting (WRF) and Community Multiscale Air Quality (CMAQ) models (collectively WRF/CMAQ) with the constant emissions. This resolves the current fundamental disagreements about the sign of the BC emissions trend from China over the past decade as assessed from bottom-up emission inventories. Our analysis supports inventories reflecting the governmental clean air actions after 2010 (e.g., MEIC1.3, ECLIPSE versions 5a and 6b, and the Regional Emission inventory in ASia (REAS) version 3.1) and recommends revisions to those that do not (e.g., Community Emissions Data System – CEDS). Our estimated emission trends were fairly uniform across seasons but diverse among air mass origins. Stronger BC reductions, accompanied by a reduction in carbon monoxide (CO) emissions, occurred in regions of south-central East China, while weaker BC reductions occurred in north-central East China and northeastern China. Prior to 2017, the BC and CO emissions trends were both unexpectedly positive in northeastern China during winter months, which possibly influenced the climate at higher latitudes. The pace of the estimated emissions reduction over China surpasses the Shared Socioeconomic Pathways (SSPs with reference to SSP1, specifically) scenarios for 2015–2030, which suggests highly successful emission control policies. At Fukue Island, the BC fraction of fine particulate matter (PM 2.5) also steadily decreased over the last decade. This suggests that reductions in BC emissions started without significant delay when compared to other pollutants such as NOx and SO2 , which are among the key precursors of scattering PM 2.5. [ABSTRACT FROM AUTHOR]

Published

2020

5. Sources of atmospheric black carbon and related carbonaceous components at Rishiri Island, Japan: The roles of Siberian wildfires and of crop residue burning in China.

Author

Zhu, Chunmao, Kanaya, Yugo, Yoshikawa-Inoue, Hisayuki, Irino, Tomohisa, Seki, Osamu, and Tohjima, Yasunori

Subjects

SOOT, WILDFIRES, CROP residues, BIOMASS burning

Abstract

Abstract A field study was conducted to clarify sources of atmospheric black carbon and related carbonaceous components at Rishiri Island, Japan. We quantified equivalent black carbon (eBC) particle mass and the absorption Ångström exponent (AAE), atmospheric CO and CH 4 , in addition to levoglucosan in total suspended particles, a typical tracer of biomass burning. Sixteen high eBC events were identified attributable to either anthropogenic sources or biomass burning in Siberia/China. These events were often accompanied by increases of co-emitted gases such as CH 4 and CO. Specifically, we observed pollution events with elevated eBC, AAE, levoglucosan, and CH 4 CO slope in late July 2014, which were attributed to forest fires in Siberia by reference to the FLEXPART model footprint and fire hotspots. In autumn, drastic increases of eBC, AAE, and levoglucosan were observed, accompanied by an eBC–CO slope of >15 ng m−3/ppb, resulting from long-range transport of emissions from extensive burning of crop residue on the Northeast China Plain. Other than the sources of fossil fuel combustion in China and forest fires in Siberia, we report for the first time that pollution events in northern Japan are caused by crop residue burning in China. This study elucidated valuable information that will improve understanding of the effects of biomass burning in East Asia on atmospheric carbonaceous components. Graphical abstract Image 1 Highlights • Equivalent BC, levoglucosan, AAE, CO, and CH 4 were observed at Rishiri Island. • FLEXPART simulations and fire spots showed sources of pollutants in high eBC events. • Siberian forest fires caused elevated levels of carbonaceous components in summer. • Crop residue burning in China elevated carbonaceous components in autumn. Events of elevated carbonaceous components in the Asian outflow region showed impacts of Siberian wildfires and of crop residue burning in China. [ABSTRACT FROM AUTHOR]

Published

2019

6. Sensitivity analysis of source regions to PM 2.5 concentration at Fukue Island, Japan.

Author

Ikeda, Kohei, Yamaji, Kazuyo, Kanaya, Yugo, Taketani, Fumikazu, Pan, Xiaole, Komazaki, Yuichi, Kurokawa, Jun-ichi, and Ohara, Toshimasa

Subjects

SENSITIVITY analysis, AERODYNAMICS, EMISSIONS (Air pollution), GEOCHEMISTRY, AMMONIUM, SULFATES, ISLANDS

Abstract

The authors analyze the sensitivities of source regions in East Asia to PM2.5(particulate matter with an aerodynamic diameter of ≤2.5 µm) concentration at Fukue Island located in the western part of Japan by using a regional chemical transport model with emission sensitivity simulations for the year 2010. The temporal variations in PM2.5concentration are generally reproduced, but the absolute concentration is underestimated by the model. Chemical composition of PM2.5in the model is compared with filter sampling data in spring; simulated sulfate, ammonium, and elemental carbon are consistent with observations, but mass concentration of particulate organic matters is underestimated. The relative contribution from each source region shows the seasonal variation, especially in summer. The contribution from central north China (105°E–124°E, 34°N–42°N) accounts for 50–60% of PM2.5at Fukue Island except in summer; it significantly decreases in summer (18%). Central south China (105°E–123°E, 26°N–34°N) has the relative contribution of 15–30%. The contribution from the Korean Peninsula is estimated at about 10% except in summer. The domestic contribution accounts for about 7% in spring and autumn and increases to 19% in summer. We also estimate the relative contribution to daily average concentration in high PM2.5days (>35 μg m−3). Central north China has a significant contribution of 60–70% except in summer. The relative contribution from central south China is estimated at 46% in summer and about 30% in the other seasons. The contributions from central north and south China on high PM2.5days are generally larger than those of their seasonal mean contributions. The domestic contribution is smaller than the seasonal mean value in every season; it is less than 10% even in summer. These model results suggest that foreign anthropogenic sources have a substantial impact on attainment of the atmospheric environmental standard of Japan at Fukue Island.Implications: The contribution from several source regions in East Asia to PM2.5 concentration at Fukue Island, a remote island located in the western part of Japan and close to the Asian continent, is estimated using a three-dimensional chemical transport model. The model results suggest that PM2.5 that is attributed to foreign anthropogenic sources have a larger contribution than that of domestic pollution and have a substantial impact on attainment of the atmospheric environmental standard of Japan at Fukue Island. [ABSTRACT FROM AUTHOR]

Published

2014

7. Contributions of biogenic volatile organic compounds to the formation of secondary organic aerosols over Mt. Tai, Central East China

Author

Fu, Pingqing, Kawamura, Kimitaka, Kanaya, Yugo, and Wang, Zifa

Subjects

*VOLATILE organic compounds & the environment, *AEROSOLS, *ISOPRENE, *MOUNTAINS, *TRACERS (Biology), *GAS chromatography/Mass spectrometry (GC-MS), *SUMMER

Abstract

Abstract: To better understand the contribution of biogenic volatile organic compounds to the formation of secondary organic aerosol (SOA) in high mountain regions, ambient aerosols were collected at the summit of Mt. Tai (1534 m, a.s.l.), Central East China (CEC) during the Mount Tai Experiment 2006 campaign (MTX2006) in early summer. Biogenic SOA tracers for the oxidation of isoprene, α/β-pinene, and β-caryophyllene were measured using gas chromatography/mass spectrometry. Most of the biogenic SOA tracers did not show clear diurnal variations, suggesting that they are formed during long-range atmospheric transport or over relatively long time scales. Although isoprene- and α/β-pinene-derived SOA tracers did not correlate with levoglucosan (a biomass burning tracer), β-caryophyllinic acid showed a good correlation with levoglucosan, indicating that crop residue burning may be a source for this acid. Total concentrations of isoprene oxidation products are much higher than those of α/β-pinene and β-caryophyllene oxidation products. The averaged ratio of isoprene to α/β-pinene oxidation products (Riso/pine) was 4.9 and 6.7 for the daytime and nighttime samples, respectively. These values are among the highest in the aerosols reported in different geographical regions, which may be due to the large isoprene fluxes and relatively high levels of oxidants such as OH in CEC. Using a tracer-based method, we estimated the concentrations of secondary organic carbon (SOC) derived from isoprene, α/β-pinene, and β-caryophyllene to be 0.42–3.1 μgC m−3 (average 1.6 μgC m−3) during the daytime and 0.11–4.2 μgC m−3 (1.7 μgC m−3) during the nighttime. These values correspond to 2.9–23% (10%) and 3.2–28% (9.8%) of the total OC concentrations, in which isoprene-derived SOC accounts for 58% and 63% of total SOC during the daytime and nighttime, respectively. This study suggests that isoprene is a more significant precursor for biogenic SOA than α/β-pinene and β-caryophyllene at high altitudes in CEC. [Copyright &y& Elsevier]

Published

2010

8. Influence of Beijing outflow on Volatile Organic Compounds (VOC) observed at a mountain site in North China Plain

Author

Suthawaree, Jeeranut, Kato, Shungo, Pochanart, Pakpong, Kanaya, Yugo, Akimoto, Hajime, Wang, Zifa, and Kajii, Yoshizumi

Subjects

*VOLATILE organic compounds, *MOUNTAINS, *AIR quality, *BIOMASS energy, *BIOMASS burning, *PHOTOCHEMISTRY, *AIR masses

Abstract

Abstract: In order to elucidate an impact of Beijing outflow on air quality in the mountainous area, measurement campaign was carried out in Mt. Mang, located 40km north of Beijing in September 2007. Volatile Organic Compounds (VOC) observed at the site were mainly influenced by air masses arriving from urban areas. No significant impact of local emission was found. Correlation plots between selected VOC suggests several major emission sources as internal combustion, industrial emission, and coal, oil and biofuel burning. Air masses were classified into “polluted” (influence of Beijing and its satellite cities) and “clean” air mass by using backward trajectory analysis. Two air mass categories revealed significant different characteristics and mixing ratios. Reaction with OH is a major factor controlling mixing ratio of “clean” air mass while impact of dilution is also play important role on “polluted” air mass. Estimation of photochemical age of “polluted” air mass by assuming “clean” air mass for background mixing ratios reveals an averaged of 1.5–1.8days. [Copyright &y& Elsevier]

Published

2012

9. Sensitivity analysis of source regions to PM2.5 concentration at Fukue Island, Japan.

Author

Ikeda K, Yamaji K, Kanaya Y, Taketani F, Pan X, Komazaki Y, Kurokawa J, and Ohara T

Subjects

Atmosphere chemistry, China, Asia, Eastern, Japan, Models, Theoretical, Particle Size, Seasons, Spatio-Temporal Analysis, Air Pollutants analysis, Ammonium Compounds analysis, Carbon analysis, Environmental Monitoring, Particulate Matter analysis, Sulfates analysis

Abstract

Unlabelled: The authors analyze the sensitivities of source regions in East Asia to PM2.5 (particulate matter with an aerodynamic diameter of < or = 2.5 microm) concentration at Fukue Island located in the western part of Japan by using a regional chemical transport model with emission sensitivity simulations for the year 2010. The temporal variations in PM2.5 concentration are generally reproduced, but the absolute concentration is underestimated by the model. Chemical composition of PM2.5 in the model is compared with filter sampling data in spring; simulated sulfate, ammonium, and elemental carbon are consistent with observations, but mass concentration of particulate organic matters is underestimated. The relative contribution from each source region shows the seasonal variation, especially in summer. The contribution from central north China (105 degrees E-124 degrees E, 34 degrees N-42 degrees N) accounts for 50-60% of PM2.5 at Fukue Island except in summer; it significantly decreases in summer (18%). Central south China (105 degrees E-123 degrees E, 26 degrees N-34 degrees N) has the relative contribution of 15-30%. The contribution from the Korean Peninsula is estimated at about 10% except in summer. The domestic contribution accounts for about 7% in spring and autumn and increases to 19% in summer. We also estimate the relative contribution to daily average concentration in high PM2.5 days (> 35 microg m(-3)). Central north China has a significant contribution of 60-70% except in summer. The relative contribution from central south China is estimated at 46% in summer and about 30% in the other seasons. The contributions from central north and south China on high PM2.5 days are generally larger than those of their seasonal mean contributions. The domestic contribution is smaller than the seasonal mean value in every season; it is less than 10% even in summer. These model results suggest that foreign anthropogenic sources have a substantial impact on attainment of the atmospheric environmental standard of Japan at Fukue Island., Implications: The contribution from several source regions in East Asia to PM2.5 concentration at Fukue Island, a remote island located in the western part of Japan and close to the Asian continent, is estimated using a three-dimensional chemical transport model. The model results suggest that PM2.5 that is attributed to foreign anthropogenic sources have a larger contribution than that of domestic pollution and have a substantial impact on attainment of the atmospheric environmental standard of Japan at Fukue Island.

Published

2014