Horizontal Distance of Each Cumulus and Cloud Broadening Distance Determine Cloud Cover

Sato, Yousuke; Miyamoto, Yoshinari; Nishizawa, Seiya; Yashiro, Hisashi; Kajikawa, Yoshiyuki; Yoshida, Ryuji; Yamaura, Tsuyoshi; Tomita, Hirofumi

doi:10.2151/sola.2015-019

Cited by 5 publications

(5 citation statements)

References 25 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…So far, SCALE-LES has produced promising results for cloud dynamics with idealized experiments at resolution up to 35 m, much higher than typical NWP research (e.g., [35] and [36]). The model also performs well for real cases.…”

Section: A the Scale-les Modelmentioning

confidence: 99%

“Big Data Assimilation” Toward Post-Petascale Severe Weather Prediction: An Overview and Progress

et al. 2016

Self Cite

View full text Add to dashboard Cite

Following the invention of the telegraph, electronic computer, and remote sensing, "big data" is bringing another revolution to weather prediction. As sensor and computer technologies advance, orders of magnitude bigger data are produced by new sensors and high-precision computer simulation or "big simulation." Data assimilation (DA) is a key to numerical weather prediction (NWP) by integrating the real-world sensor data into simulation. However, the current DA and NWP systems are not designed to handle the "big data" from next-generation sensors and big simulation. Therefore, we propose "big data assimilation" (BDA) innovation to fully utilize the big data. Since October 2013, the Japan's BDA project has been exploring revolutionary NWP at 100-m mesh refreshed every 30 s, orders of magnitude finer and faster than the current typical NWP systems, by taking advantage of the fortunate combination of next-generation technologies: the 10-petaflops K computer, phased array weather radar, and geostationary satellite Himawari-8. So far, a BDA prototype system was developed and tested with real-world retrospective local rainstorm cases. This paper summarizes the activities and progress of the BDA project, and concludes with perspectives toward the post-petascale supercomputing era.

show abstract

Section: A the Scale-les Modelmentioning

confidence: 99%

“Big Data Assimilation” Toward Post-Petascale Severe Weather Prediction: An Overview and Progress

et al. 2016

Self Cite

View full text Add to dashboard Cite

show abstract

“…An increase in the concentration of atmospheric aerosols increases the number and concentration of cloud particles, as aerosols serve as cloud condensation nuclei and ice nuclei. As a result, aerosols affect precipitation on the ground, and influence radiative processes through cloud lifetime, and changes in cloud cover and volume (e.g., Miyamoto, 2021; Miyamoto et al, 2020; Sato et al, 2015). This is called the “lifetime effect” (Albrecht, 1989).…”

Section: Introductionmentioning

confidence: 99%

PM_2.5 decrease with precipitation as revealed by single‐point ground‐based observation

Fujino

Miyamoto

2022

Atmospheric Science Letters

Self Cite

View full text Add to dashboard Cite

This study analyzed the observed data of precipitation and PM2.5 concentration collected over two and a half years at Tsujido, Fujisawa City, to examine a quantitative relationship between the two quantities. It was observed that the PM2.5 concentration decreased as precipitation increased. A composite analysis revealed that the PM2.5 concentration on average decreases by 20.99% 1 h after the onset of precipitation as compared to that 1 h before, which is statistically significant based on a paired t‐test. The PM2.5 concentrations decreased over 8 h period from 5 h (−5 h) before to 3 h (+3 h) after the onset of precipitation, with a particularly dramatic decrease at the onset of precipitation. Analysis of PM2.5 scavenging rates by precipitation intensity showed that the scavenging rate was 2.03% for light precipitation events, 28.15% for moderate precipitation events, and 26.75% for heavy precipitation events, indicating that the scavenging rate increased with moderate precipitation intensity and above. It is suggested that the deposition processes of rainout and washout are effective in reducing PM2.5 concentration with precipitation.

show abstract

“…As shown in Figure , the estimated parameter changed the atmosphere mainly for regions where shallow clouds are climatologically dominant. Shallow clouds generally cover a broad area and play an important role in the Earth's energy budget (e.g., Randall et al, ; Sato et al, ). As mentioned above, the decrease in B 1 decelerates the autoconversion; therefore, vapor and clouds stay longer in the atmosphere.…”

Section: Resultsmentioning

confidence: 99%

“…The autoconversion process dominates the formation of drizzle in stratiform clouds (Liu & Daum, ). The stratiform clouds control the radiation budget of the Earth due to their broad coverage of the Earth surface (e.g., Randall et al, ; Sato et al, ). It is also important to estimate accurate autoconversion parameters for better treatment of clouds in climate models.…”

Section: Methodsmentioning

confidence: 99%

Online Model Parameter Estimation With Ensemble Data Assimilation in the Real Global Atmosphere: A Case With the Nonhydrostatic Icosahedral Atmospheric Model (NICAM) and the Global Satellite Mapping of Precipitation Data

et al. 2018

Self Cite

View full text Add to dashboard Cite

This study aims to improve precipitation forecasts by estimating model parameters of a numerical weather prediction model with an ensemble-based data assimilation method. We implemented the parameter estimation algorithm into a global atmospheric data assimilation system NICAM-LETKF, which incorporates Nonhydrostatic Icosahedral Atmospheric Model (NICAM) and the Local Ensemble Transform Kalman Filter (LETKF). This study estimated a globally uniform model parameter of a large-scale condensation scheme known as the B 1 parameter of Berry's parameterization. We conducted an online estimation of the B 1 parameter using the Global Satellite Mapping of Precipitation (GSMaP) data and successfully reduced NICAM's precipitation forecast bias relative to the GSMaP data, especially for weak rains. The estimated B 1 parameter evolved toward the optimal value obtained by manual tuning. The parameter estimation also mitigated a dry bias for the lower troposphere in the Tropics. However, the estimated B 1 intensified biases for cloud water mixing ratio and outgoing long-wave radiation in the regions where shallow clouds are dominant. This is because only precipitation data were used to estimate the optimal value of B 1 , and more constraints will be required to obtain a suitable value for climatological simulations.

show abstract

Horizontal Distance of Each Cumulus and Cloud Broadening Distance Determine Cloud Cover

Cited by 5 publications

References 25 publications

“Big Data Assimilation” Toward Post-Petascale Severe Weather Prediction: An Overview and Progress

“Big Data Assimilation” Toward Post-Petascale Severe Weather Prediction: An Overview and Progress

PM_2.5 decrease with precipitation as revealed by single‐point ground‐based observation

Online Model Parameter Estimation With Ensemble Data Assimilation in the Real Global Atmosphere: A Case With the Nonhydrostatic Icosahedral Atmospheric Model (NICAM) and the Global Satellite Mapping of Precipitation Data

Contact Info

Product

Resources

About

Horizontal Distance of Each Cumulus and Cloud Broadening Distance Determine Cloud Cover

Cited by 5 publications

References 25 publications

“Big Data Assimilation” Toward Post-Petascale Severe Weather Prediction: An Overview and Progress

“Big Data Assimilation” Toward Post-Petascale Severe Weather Prediction: An Overview and Progress

PM2.5 decrease with precipitation as revealed by single‐point ground‐based observation

Online Model Parameter Estimation With Ensemble Data Assimilation in the Real Global Atmosphere: A Case With the Nonhydrostatic Icosahedral Atmospheric Model (NICAM) and the Global Satellite Mapping of Precipitation Data

Contact Info

Product

Resources

About

PM_2.5 decrease with precipitation as revealed by single‐point ground‐based observation