Calculation of longwave radiation fluxes in atmospheres

Feigelson, E. M.; Fomin, B. A.; Gorchakova, I. A.; Rozanov, Eugene; Timofeyev, Yu. M.; Trotsenko, A. N.; Schwarzkopf, Malte

doi:10.1029/91jd00449

Cited by 15 publications

(9 citation statements)

References 21 publications

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“…The results of calculations by the approximate method [13,14] have shown that the values of ascending fluxes up to 6 km high are calculates within an accuracy of 1-3%. The maximal deviation of ascending flux values in different climatic zones are 8-14 W/m 2 .…”

Section: Algorithm Of Estimationmentioning

confidence: 99%

“…For a cloudless atmosphere, we calculated ITF by atmospheric gases (Н 2 О, СО 2 , and О 3 ) and aerosol. The accuracy of the method for calculating long infrared radiation fluxes was esti mated by comparison with line by line calculations [13,14]. The respective results of a comparison between solar and thermal radiation fluxes for cloud less and clouded atmosphere are presented in [13].…”

Section: Algorithm Of Estimationmentioning

confidence: 99%

“…Approximated methods for calculating inte grated fluxes of solar [12,13] and thermal [13,14] radiation were used with the integrated transmission function (ITF) of the atmosphere involved. The method of calculating integrated solar radia tion fluxes in the short infrared region of 0.2-4.0 μm is based on the solution of radiation transfer equation in the δ Eddington approximation.…”

Section: Algorithm Of Estimationmentioning

confidence: 99%

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Radiation and temperature effects of the intensive injection of dust aerosol into the atmosphere

Gorchakova

Мохов

Rublev³

2015

Izv. Atmos. Ocean. Phys.

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Based on the measurements at the AERONET station (Ilorin, Nigeria), quantitative estimates of radiation and temperature effects of dust aerosol during the intensive sand storm in the Sahara Desert from January 28 to February 6, 2000, are obtained. The model used in calculations implies particles of dust aerosol being no more than 15 μm in radius (according to the data from AERONET station); another model takes into account large particles (LPs) up to 60 μm in radius and involves a spectral variation in the OPAC refraction index. In the short infrared region, the optical thickness of aerosol weakening increases with LPs taken into account in the aerosol model; the albedo of aerosol single scattering reduces in comparison to the respective optical parameters of the first model. Dust aerosol cools the earth's surface. In the presence of LPs in dust aerosol, the surface-atmosphere system can both cool and warm, while if LPs less than 15 μm in size are not taken into account, the surface cools. The rate of cooling of the 10 m near surface atmospheric layer changes in the interval of -(4-21)°C/day without the influence of LPs over 15 μm in size on solar radi ation transfer taken into account; if this influence is taken into account, the rate is -(6-36)°C/day. In the long infrared region, the surface-atmosphere system warms more intensively if LPs are taken into account by the aerosol model. The heating rate of the 10 m near surface atmospheric layer does not exceed 0.5°C/day during the entire period of dust emission without LPs taken into account (AERONET algo rithm); if LPs are taken into account (modeling results), heating rate reaches a maximal value of 0 .6°C/day.

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Section: Algorithm Of Estimationmentioning

confidence: 99%

Section: Algorithm Of Estimationmentioning

confidence: 99%

Section: Algorithm Of Estimationmentioning

confidence: 99%

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Radiation and temperature effects of the intensive injection of dust aerosol into the atmosphere

Gorchakova

Мохов

Rublev³

2015

Izv. Atmos. Ocean. Phys.

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“…The first algorithm [ Fomin , 1994] was independently tested [ Kuntz and Hofner , 1999] and the properties of the second one based on the “linear in τ” approximation [ Wiscombe , 1976] for vertically inhomogeneous atmosphere are well known. It is also worthy of note that a large family of calculations obtained with earlier versions of FLBLM was published long ago as benchmark calculations for the validation of radiation codes being used in climate models [ Feigelson et al , 1991; Fomin and Gershanov , 1997]. Of course these calculations have been used for FKDM validation.…”

Section: Validationsmentioning

confidence: 99%

A k‐distribution technique for radiative transfer simulation in inhomogeneous atmosphere: 1. FKDM, fast k‐distribution model for the longwave

Fomin

2004

J. Geophys. Res.

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[1] A new technique for developing k-distributions is described. This new technique requires almost half of the computational effort yet is at least as accurate as other published k-distribution methods. Its novelty consists in the use of real atmospheric flux calculations to guide both the position of spectral bands and the k terms within each band; previous methods have not used such a guiding principle. Wave number subintervals which have similar atmospheric absorption behavior are chosen, then a representative absorption coefficient for such a wave number interval is set to the value which best fit the results of line-by-line calculations of fluxes and heating rates. This method of choosing one absorption coefficient to represent a large wave number subinterval contrasts with other published methods and is responsible in large part for the improved computational efficiency. It is worth noting that this new technique works as well in the stratosphere as the troposphere, so it can be applied to the processing of satellite data retrievals as well as in weather and climate forecasting. An example of the application of the new technique to the longwave part of the spectrum is presented. A fast k-distribution model (FKDM) suitable for use in weather and climate prediction has been created using 23 k-distribution terms, which is nearly half as many as other k-distribution models. The molecular species represented in the model are H 2 O, CO 2 , O 3 , N 2 O, CH 4 , and CFC-11,12,113. FKDM has been developed and validated using a fast line-by-line model (FLBLM). Validations have covered the tropical, midlatitude summer, midlatitude winter, subarctic summer, subarctic winter standard atmospheres, four atmospheres from the Spectral Radiance Experiment campaign, and one case of real tropical atmosphere. It has been found that the FKDM cooling rate accuracy is as follows: 0.15 and 0.2 K day À1 in troposphere for standard and real atmospheres, respectively, and 0.9 K day À1 in all the cases at altitudes below 70 km. Upward and downward flux errors are below 4 W m À2 (usually 1-2 W m À2 ) in every case.

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“…In doing so to allow for an actual atmosphere heterogeneity the modified scaled content approximation is considered that exploits a set of effective parameters based upon the CurtisGodson approximation. Thus in order to simulate the JR photon optical path-length from the path coordinate 1=1' towards the atmosphere top (1=0) within each Av the scaled content for each i is calculated using u(O,l')= Jp(l)dl (11) where p ( I is the scaled density (g/rn3) defined as Al (1) = I I ii g (9(l)) i (12) re P,! ) t\ e g'(O) ) and ] is the reference pressure ofthe path evaluated separately for each I by the formula like P = P(l)w'(l)dl I w'(l)dl (13) The following notation are used in expressions (1 1)-(13):L is the path length ( in km); e(l), P(l) are the temperature and pressure at current path coordinate 1, respectively; p' (1) is the actual density, and n,, f , m, are the model tunable parameters.…”

Section: Narrow-band Radiation Transfer Model Useful In Processing Ismentioning

confidence: 99%

<title>Line-by-line radiative parameters databases in atmosphere sensing and modeling applications</title>

Trotsenko

Rublev

Fomin

et al. 1995

Atmospheric Sensing and Modeling II

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This work is mainly focused on the application of the line-by-line (LBL) radiative parameters databases in processing satellite low-resolution measurements of outgoing solar and JR radiation associated with two space instruments such as the Scanner of Radiation Budget (ScaRab on Meteor-3/7 experiment) and ISTOK-1 (PRIRODA-MIR mission). Details of the efficient computer techniques for a routine but accurate calculations of solar and JR radiative parameters in order to develop the benchmark databases are briefly described. Some practical results are presented that involve the utilization of line-byline benchmarks in the ScaRaB measurement validation. The narrow-band model designed for the ISTOK-1 measurement processing and developed on the basis on the LBL precalculations is presented. Keywords: Earth radiation budget, line-by-line technique, benchmark calculation database, aerosols, broken cloudiness, narrow-band radiative transfer model. . GENERAL REMARKSSince the reliable and well-documented compilation atlases containing line parameters of the atmosphere gases absorption bands became available' fairly wide set of more or less sophisticated numerical models based upon the line-by-line (LBL) technique have been developed.2 As it is known these models enable the most straightforward and accurate calculation of different both the solar and the JR radiative transfer characteristics in the atmosphere. However in spite of the noticeable progress either in the modem computer facilities or in the improvement of numerical releases of the LBL technique by itself a practical application of such models as a direct component of the algorithms to process measurements involving parameters of the Earth-atmosphere outgoing radiation is as a rule associated with the instruments representative of the narrow operating diapason and the high spectral resolution. Unfortunately this is caused by copious amounts of computer time consumed in performing the accurate spectral and spatial integration within the framework of usually repeated radiative parameter calculations that in turn makes the accurate LBL based models impractical from the point of view of their direct employment in processing the wide-band radiative measurements. In the same time the last does not mean that the LBL models may not be efficiently used with application to the wide-band measurement processing. In particular these models may be utilized to form the databases containing so-called benchmark radiative calculations2, i.e. sufficiently extensive data sets of calculated radiative transfer parameters obtained for a wide series of fixed realizations of the atmosphere and Earth surface state. Specially composed such databases may be evidently used to develop, tune and validate the computationally efficient parameterized models, i.e. those based upon various approximate approaches of the radiative transfer theory, that may be ultimately exploited as the direct problem component of the procedures designed for the secondary satellite data processing. One of such paramete...

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Calculation of longwave radiation fluxes in atmospheres

Cited by 15 publications

References 21 publications

Radiation and temperature effects of the intensive injection of dust aerosol into the atmosphere

Radiation and temperature effects of the intensive injection of dust aerosol into the atmosphere

A k‐distribution technique for radiative transfer simulation in inhomogeneous atmosphere: 1. FKDM, fast k‐distribution model for the longwave

<title>Line-by-line radiative parameters databases in atmosphere sensing and modeling applications</title>

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