The behaviour of a mixed-layer model of the convective boundary layer coupled to a big leaf model of surface energy partitioning
| ISSN: |
1573-1472
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|---|---|
| Keywords: |
Atmospheric boundary layer ; Diurnal variability ; Latent heat flux ; Priestley-Taylor coefficient ; Surface resistance
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| Source: |
Springer Online Journal Archives 1860-2000
|
| Topics: |
Geosciences
Physics
|
| Notes: |
Abstract Daily mean values of the Priestley-Taylor coefficient, α¯, are derived from a simple model of the daily growth of a convective boundary layer. For a particular control set of driving environmental variables, α¯ is related to the prescribed bulk surface resistance, rS by 1/α¯ = 1/α0 + mrS for parameters α0 and m. The dependence of the parameters α0 and m on weather is explored and a potential use of this linear relation to provide information about regional values of rS is indicated.
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| Type of Medium: |
Electronic Resource
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| URL: |
| _version_ | 1798296604451536896 |
|---|---|
| autor | Huntingford, C. Monteith, J. L. |
| autorsonst | Huntingford, C. Monteith, J. L. |
| book_url | http://dx.doi.org/10.1023/A:1001110819090 |
| datenlieferant | nat_lic_papers |
| hauptsatz | hsatz_simple |
| identnr | NLM193502194 |
| issn | 1573-1472 |
| journal_name | Boundary layer meteorology |
| materialart | 1 |
| notes | Abstract Daily mean values of the Priestley-Taylor coefficient, α¯, are derived from a simple model of the daily growth of a convective boundary layer. For a particular control set of driving environmental variables, α¯ is related to the prescribed bulk surface resistance, rS by 1/α¯ = 1/α0 + mrS for parameters α0 and m. The dependence of the parameters α0 and m on weather is explored and a potential use of this linear relation to provide information about regional values of rS is indicated. |
| package_name | Springer |
| publikationsjahr_anzeige | 1998 |
| publikationsjahr_facette | 1998 |
| publikationsjahr_intervall | 8004:1995-1999 |
| publikationsjahr_sort | 1998 |
| publisher | Springer |
| reference | 88 (1998), S. 87-101 |
| schlagwort | Atmospheric boundary layer Diurnal variability Latent heat flux Priestley-Taylor coefficient Surface resistance |
| search_space | articles |
| shingle_author_1 | Huntingford, C. Monteith, J. L. |
| shingle_author_2 | Huntingford, C. Monteith, J. L. |
| shingle_author_3 | Huntingford, C. Monteith, J. L. |
| shingle_author_4 | Huntingford, C. Monteith, J. L. |
| shingle_catch_all_1 | Huntingford, C. Monteith, J. L. The behaviour of a mixed-layer model of the convective boundary layer coupled to a big leaf model of surface energy partitioning Atmospheric boundary layer Diurnal variability Latent heat flux Priestley-Taylor coefficient Surface resistance Atmospheric boundary layer Diurnal variability Latent heat flux Priestley-Taylor coefficient Surface resistance Abstract Daily mean values of the Priestley-Taylor coefficient, α¯, are derived from a simple model of the daily growth of a convective boundary layer. For a particular control set of driving environmental variables, α¯ is related to the prescribed bulk surface resistance, rS by 1/α¯ = 1/α0 + mrS for parameters α0 and m. The dependence of the parameters α0 and m on weather is explored and a potential use of this linear relation to provide information about regional values of rS is indicated. 1573-1472 15731472 Springer |
| shingle_catch_all_2 | Huntingford, C. Monteith, J. L. The behaviour of a mixed-layer model of the convective boundary layer coupled to a big leaf model of surface energy partitioning Atmospheric boundary layer Diurnal variability Latent heat flux Priestley-Taylor coefficient Surface resistance Atmospheric boundary layer Diurnal variability Latent heat flux Priestley-Taylor coefficient Surface resistance Abstract Daily mean values of the Priestley-Taylor coefficient, α¯, are derived from a simple model of the daily growth of a convective boundary layer. For a particular control set of driving environmental variables, α¯ is related to the prescribed bulk surface resistance, rS by 1/α¯ = 1/α0 + mrS for parameters α0 and m. The dependence of the parameters α0 and m on weather is explored and a potential use of this linear relation to provide information about regional values of rS is indicated. 1573-1472 15731472 Springer |
| shingle_catch_all_3 | Huntingford, C. Monteith, J. L. The behaviour of a mixed-layer model of the convective boundary layer coupled to a big leaf model of surface energy partitioning Atmospheric boundary layer Diurnal variability Latent heat flux Priestley-Taylor coefficient Surface resistance Atmospheric boundary layer Diurnal variability Latent heat flux Priestley-Taylor coefficient Surface resistance Abstract Daily mean values of the Priestley-Taylor coefficient, α¯, are derived from a simple model of the daily growth of a convective boundary layer. For a particular control set of driving environmental variables, α¯ is related to the prescribed bulk surface resistance, rS by 1/α¯ = 1/α0 + mrS for parameters α0 and m. The dependence of the parameters α0 and m on weather is explored and a potential use of this linear relation to provide information about regional values of rS is indicated. 1573-1472 15731472 Springer |
| shingle_catch_all_4 | Huntingford, C. Monteith, J. L. The behaviour of a mixed-layer model of the convective boundary layer coupled to a big leaf model of surface energy partitioning Atmospheric boundary layer Diurnal variability Latent heat flux Priestley-Taylor coefficient Surface resistance Atmospheric boundary layer Diurnal variability Latent heat flux Priestley-Taylor coefficient Surface resistance Abstract Daily mean values of the Priestley-Taylor coefficient, α¯, are derived from a simple model of the daily growth of a convective boundary layer. For a particular control set of driving environmental variables, α¯ is related to the prescribed bulk surface resistance, rS by 1/α¯ = 1/α0 + mrS for parameters α0 and m. The dependence of the parameters α0 and m on weather is explored and a potential use of this linear relation to provide information about regional values of rS is indicated. 1573-1472 15731472 Springer |
| shingle_title_1 | The behaviour of a mixed-layer model of the convective boundary layer coupled to a big leaf model of surface energy partitioning |
| shingle_title_2 | The behaviour of a mixed-layer model of the convective boundary layer coupled to a big leaf model of surface energy partitioning |
| shingle_title_3 | The behaviour of a mixed-layer model of the convective boundary layer coupled to a big leaf model of surface energy partitioning |
| shingle_title_4 | The behaviour of a mixed-layer model of the convective boundary layer coupled to a big leaf model of surface energy partitioning |
| sigel_instance_filter | dkfz geomar wilbert ipn albert fhp |
| source_archive | Springer Online Journal Archives 1860-2000 |
| timestamp | 2024-05-06T09:54:44.926Z |
| titel | The behaviour of a mixed-layer model of the convective boundary layer coupled to a big leaf model of surface energy partitioning |
| titel_suche | The behaviour of a mixed-layer model of the convective boundary layer coupled to a big leaf model of surface energy partitioning |
| topic | TE-TZ U |
| uid | nat_lic_papers_NLM193502194 |