Ls Land Issue Ls Models 05 Meadow 25 |VERIFIED|
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L'Anse aux Meadows is a French-English name which can be translated as "Grassland Bay" (lit. "[the] bay with [the] grasslands"). How the village itself came to be named "L'Anse aux Meadows" is debated. One possibility is that "L'Anse aux Meadows" is a corruption of the French designation L'Anse aux Méduses, which means "Jellyfish Cove". A more recent supposition is that the name derives from "L'Anse à la Médée" (Medea Cove") the name it bears on an 1862 French naval chart. Whether Medea or Medusa, it is possible that the name refers to a French naval vessel. The shift to "Meadows" from Méduses or Médée may have occurred because of folk etymology linking the name to the open landscape around the cove, with many meadows.
Updates to the plans are underway in some coastal communities, and the Oregon Coastal Management Program is creating guidance for localities on estuary planning for a changing climate and rising seas. Future EMPs will also have to address new knowledge and issues that have emerged over the past 40 years, including the federal listing of endangered salmon; the role of forage fish; the decline of adjacent habitat; and the economic and ecological importance of eelgrass meadows, salt marsh, forested tidal wetlands, and other coastal habitats.
Healthy estuaries are key to clean water in the coastal zone. Tidal wetlands and marshes remove sediments and pollutants, providing high-quality refuge for juvenile fish, including commercially important species, especially salmon, that depend on clear, cool water.1 And eelgrass meadows help lessen the local effects of ocean acidification and low oxygen, known as hypoxia.2
In this study, we provide evidence that spatial structure is distinct even when species occur in well-mixed multispecies meadows, and we suggest that size-dependent plant traits have a strong influence on the distribution and maintenance of tropical marine plant communities. This study offers a contrast from previous spatial models of seagrasses which have largely focused on monospecific temperate meadows.
Fine-scale drivers were considerably more difficult to identify because of the wide range in distances. However, the type of variogram models used is informative about patch characteristics. The exponential model in the along-shore (Table 3) indicates that patches have an irregular extent usually attributed to stochastic processes . Irregular gap formation at this scale could have been caused by the grazing of mega fauna, sediment erosion and deposition both natural and caused by boat movement and anchoring, and surface runoff outlets from land which cause changes in salinity and nutrient input. In the across-shore direction, the spherical model provided the best fit. Thus, drivers in this direction resulted in species patches that were fairly regular.
In the across-shore direction, the depth gradient (light gradient) is a possible broad-scale driver. At the landward meadow edge where water depth is around 3 m, photosynthetically active radiation (PAR) averages 37% of surface irradiance. The meadow slopes down gradually to around 10 m depth where PAR averages 15% of surface irradiance, beyond which no seagrasses occur . Because Halophila spp and H. uninervis possess small rhizomes, they have small respiratory demands  and they do not integrate resources as well as larger species such as S. isoetifolium and C. serrulata , . These are size-specific traits which result in small species having greater sensitivity to environmental changes that occur over the broad spatial scale, such as a reduction in light along a gradient of water depth. Light and seasonal environmental variability have previously been shown to affect resource availability for small species .
Bibliography A. Basic concepts and definitions B. ET equations C. ET and weather measurement D. Parameters in ET equations E. Crop parameters in PM equation F. Analysis of weather and ET data G. Crop evapotranspiration H. Crop coefficients I. Lengths of crop growth stages J. Effects of soil mulches K. Non-growing season evapotranspiration L. Soil water holding characteristics M. Rooting depths N. Salinity impacts on evapotranspiration O. Soil evaporation P. Factors affecting ETc Q. Soil water balance and irrigation scheduling R. General A. Basic concepts and definitionsAllen, R. G., Smith, M., Perrier, A., and Pereira, L. S. 1994a. An update for the definition of reference evapotranspiration. ICID Bulletin. 43(2). 1-34.Jensen, M. E., Burman, R. D., and Allen, R. G. (ed). 1990. Evapotranspiration and Irrigation Water Requirements. ASCE Manuals and Reports on Engineering Practices No. 70., Am. Soc. Civil Engrs., New York, NY, 360 p.Monteith, J. L., 1965. Evaporation and Environment. 19th Symposia of the Society for Experimental Biology, University Press, Cambridge, 19:205-234.Monteith, J. L. 1973. Principles of Environmental Physics, Edward Arnold, London.Monteith, J. L. and Unsworth, M. H. 1990. Principles of Environmental Physics, 2nd ed., Edward Arnold, London.Penman, H. L. 1948. "Natural evaporation from open water, bare soil and grass." Proc. Roy. Soc. London, A193, 120-146.Penman, H. L. 1963. Vegetation and hydrology. Tech. Comm. No. 53, Commonwealth Bureau of Soils, Harpenden, England. 125 p.Pereira, L. S., Perrier, A., Allen, R. G. and Alves, I. 1996. Evapotranspiration: Review of concepts and future trends. J. Irrig. And Drain. Engrg., ASCE 25. (in press).Perrier, A. 1978. Importance des définitions de l'évapotranspiration dans le domaine pratique de la mesure, de l'estimation of de la notion de coefficients culturaux. XV' Journal of Hydraulics, Société Hydrotechnique de France, Question IV, Rapport 1:1-7 (in French).Perrier, A. 1982. Land surface processes: vegetation. pp. 395-448 in P. S. Eagleson (Editor), Land Surface Processes in Atmospheric General Circulation Models. Cambridge Univ. Press, Cambridge, Mass.Perrier, A. 1985. Updated evapotranspiration and crop water requirement definitions. In: Perrier, A. and Riou, C. (eds) Crop Water Requirements (ICID Int. Conf., Paris, Sept. 1984). INRA, Paris: 885-887.Rijtema, P. E., (1965). "Analysis of actual evapotranspiration." Agric. Res. Rep. No. 69, Centre for Agric. Publ. and Doc., Wageningen.Slatyer, R. O. and McIlroy, I. C. 1961. Evaporation and the principle of its measurement. In: Practical Meteorology, CSIRO (Australia) and UNESCO, Paris.Smith, M., Allen, R. G., Monteith, J. L., Perrier, A., Pereira, L., and Segeren, A. 1992. Report of the expert consultation on procedures for revision of FAO guidelines for prediction of crop water requirements. UN-FAO, Rome, Italy, 54 p.B. ET equationsAllen, R. G. 1986. A Penman for all seasons. J. Irrig. and Drain. Engrg. 112(4): 348-368.Allen, R. G. 1992. Evaluation of a temperature difference method for computing grass reference evapotranspiration. Report submitted to UN-FAO Water Resources Development and Management Service, Land and Water Dev. Div., Rome. 50 p.Allen, R. G., 1995b. Evaluation of procedures for estimating grass reference evapotranspiration using air temperature data only. Report prepared for FAO, Water Resources Development and Management Service, FAO, Rome.Allen, R. G. and Pruitt, W. O. 1986. Rational use of the FAO Blaney-Criddle formula. J. Irrig. and Drain. Engrg., ASCE 112(IR2): 139-155.Allen, R. G. and Pruitt, W. O. 1991. FAO-24 reference evapotranspiration factors. J. Irrig. and Drain. Engrg., ASCE 117(5): 758-773.Allen, R. G., Pruitt, W. O., Businger, J. A., Fritschen, L. J., Jensen, M. E., and Quinn, F. H. 1996. Chapter 4 "Evaporation and Transpiration" m ASCE Handbook of Hydrology. New York, NY. p. 125-252.Batchelor, C. H. 1984. The accuracy of evapotranspiration functions estimated with the FAO modified Penman equation. Irrig. Science 5(4): 223-234.Blaney, H.F. and Criddle, W. D. 1950. Determining water requirements in irrigated areas from climatological and irrigation data. USDA Soil Conserv. Serv. SCS-TP96. 44 pp.Brutsaert, W. H., 1982. Evaporation into the Atmosphere. R. Deidel Publishing Company, Dordrecht, Holland.Burman, R. and Pochop, L. O. 1994. Evaporation, Evapotranspiration and Climatic Data. Elsevier Science B. V., Amsterdam.Businger, J. A. 1956. Some remarks on Penman's equations for the evapotranspiration. Netherlands J. Agric. Sci. 4: 77.Castrignanò, A., de Caro, A., and Tarantino, E. 1985. Verifica sulla validità di alcuni metodi empirici di stima dell'evapotraspirazione potenziale nel Metapontino. (Verification of validity of several empirical methods of estimating potential evapotranspiration in southern Italy). L'Irrigazione XXXII (4): 23-28 (in Italian).Chiew, F. H. S., N. N. Kamadalasa, H. M. Malano and McMahon, T. A. 1995. Penman-Monteith, FAO-24 reference crop evapotranspiration and class-A pan data in Australia. Agric. Water Management 28: 9-21.Choisnel, E., de Villele, O., and Lacroze, F. 1992. Une approche uniformisée du calcul de l'évapotranspiration potentielle pour l'ensemble des pays de la Communauté Européenne, Com. Commun. Européennes, EUR 14223 FR, Luxembourg, 176 p.Christiansen, J. E. 1968. Pan evaporation and evapotranspiration from climatic data. J. Irrig. and Drain. Div., ASCE 94: 243-265.Cuenca, R. H. and Nicholson, M. T. 1982. Application of the Penman equation wind function. J. Irrig. and Drn. Engrg. Div., ASCE 108(IR1): 13-23.Doorenbos, J. and Kassam, A. H. 1979. Yield response to water. FAO Irrig. and Drain. Paper No. 33, FAO, Rome, Italy. 193 pp.Doorenbos, J. and Pruitt, W. O. 1975. Guidelines for predicting crop water requirements, Irrigation and Drainage Paper 24, Food and Agriculture Organization of the United Nations, Rome, 179 p.Feddes, R. A. 1987. Crop factors in relation to Makkink reference crop evapotranspiration. Tech. Bull. Inst. for Land and Water Management Research. No. 67, pp. 33-45.Frére, M. and Popov, G. F. 1979. Agrometeorological crop monitoring and forecasting. FAO Plant Production and Protection Paper 17. FAO, Rome, Italy., pp 38-43,Frevert, D. K., Hill, R. W., and Braaten, B. C. 1983. Estimation of FAO evapotranspiration coefficients. J. Irrig. and Drain Engrg., ASCE 109(IR2): 265-270.Gunston, H. and Batchelor, C. H. 1983. A comparison of the Priestley-Taylor and Penman methods for estimating reference crop evapotranspiration in tropical countries. Agric. Water Man. 6:65-77.George, W., Pruitt, W. O., and Dong, A. 1985. Evapotranspiration modeling. In: California Irrigation Management Information System, Final Report, by R. Snyder, D. W. Henderson, Pruitt, W. O., and Dong, A. Calif. Dept. Water Resour. Contract. No. B53812. Land, Air and Water Resources Pap. 10013-A, Univ. Calif., Davis, III-36 to III-59.Gosse, G., Perrier, A., and Itier, B. 1977. Etude de l'évapotranspiration réelle d'une culture de blé dans le bassin parisien. Ann. Agron. 28(5): 521-541. (in French).Hargreaves, G. H. 1983. Discussion of 'Application of Penman wind function' by Cuenca, R. H. and Nicholson, M. J. J. Irrig. and Drain. Engrg., ASCE 109(2): 277-278.Hargreaves, G. L., Hargreaves, G. H., and Riley, J. P. 1985. Agricultural benefits for Senegal River Basin. J. Irrigation and Drainage Engr., ASCE 111: 113-124.Hashemi, F. and Habibian, M. T. 1979. Limitations of temperature based methods in estimating crop evapotranspiration in arid-zone agricultural development project. Agric. Meteorol. 20: 237-247.Hatfield, J. L. and Fuchs, M. 1990. Evapotranspiration models. Chapter 3, pp 33-59 in Management of Farm Irrigation Systems (G. J. Hoffman, T. A. Howell, and K. H. Solomon (ed)), ASAE, St. Joseph, Michigan.Howell, T. A., Schneider, A. D., and Jensen, M. E. 1991. History of lysimeter design and use for evapotranspiration measurements. In Allen, R. G., Howell, T. A., Pruitt, W. O., Walter, LA., and Jensen, M. E. (Editors), Lysimeters for Evapotranspiration and Environmental Measurements, ASCE, New York, NY p. 1-9.Itier, B. and Perrier, A. 1976a. Présentation d'une étude analytique de l'advection: I. Advection liée aux variations horizontales de concentration et de température. Ann. Agron. 27(2): 111-140.Itier, B., Brunet, Y., Mcaneney, K. J., and Lagouarde, J. P. 1994. Downwind evolution of scalar fluxes and surface resistance under conditions of local adection. Part I: A reappraisal of boundary conditions. Agric. and For. Meteorol. 71: 211-255.Itier, B. 1996. Measurement and estimation of evapotranspiration. In: Pereira, L. S., Feddes, R. A., Gilley, J. R., Leseffre, B. (eds) Sustainability of Irrigated Agriculture. Kluwer Acad. Publ., Dordrecht, pp. 171-191.Jensen, M. E. and Haise, H. R. 1963. Estimating evapotranspiration from solar radiation J. Irrig. and Drain. Div., ASCE, 89:15-41.Jensen, M. E. 1974. (ed.) Consumptive use of water and irrigation water requirements. Rep. Tech. Com. on Irrig. Water Requirements, Irrig. and Drain. Div., ASCE, 227 pp.Jensen, M. E., Burman, R. D., and Allen, R. G. (ed). 1990. Evapotranspiration and Irrigation Water Requirements. ASCE Manuals and Reports on Engineering Practices No. 70., Am. Soc. Civil Engrs., New York, NY, 360 p.Katerji, N. and Perrier, A. 1983. Modélization de l'évapotranspiration réelle ETR d'une parcelle de luzerne: rôle d'un coefficient cultural. Agronomie 3(6): 513-521 (in French).Makkink, G. F. 1957. Testing the Penman formula by means of lysimeters. J. Inst. Water Engng. 11 (3): 277-288.McNaughton, K. G. and Jarvis, P. G. 1984. Using fee Penman-Monteith equation predictively. Agricultural Water Management 8: 263-278.Monteith, J. L. 1973. Principles of Environmental Physics, Edward Arnold, London.Monteith, J. L. 1981. Evaporation and surface temperature. Quart. J. Roy. Meteorol. Soc. 107: 1-27.Monteith, J. L. 1985. Evaporation from land surfaces: progress in analysis and prediction since 1948. pp. 4-12 m Advances in Evapotranspiration, Proceedings of the ASAE Conference on Evapotranspiration, Chicago, Ill. ASAE, St. Joseph, Michigan.Pelton, W. L., King, K. M. and Tanner, C.B. 1960. An evaluation of the Thornthwaite and mean temperature methods for determining potential evapotranspiration. Agron. J. 52: 387-395.Penman, H. L. 1948. "Natural evaporation from open water, bare soil and grass." Proc. Roy. Soc. London, A193, 120-146.Penman, H. L. 1963. Vegetation and hydrology. Tech. Comm. No. 53, Commonwealth Bureau of Soils, Harpenden, England. 125 pp.Pereira, L. S. and Smith, M. 1989. Proposed procedures for revision of guidelines for predicting crop water requirements. Land and Water Use Div., FAO Rome, 36 p.Phene, C. J., dark, D. A. and Cardon, G. E. 1996. Real time calculation of crop evapotranspiration using an automated pan evaporation system. In: Camp, C. R., Sadler, E. J. and Yoder, R. E. (eds.). Evaporation and Irrigation Scheduling, ASCE: 189-194.Piper, B. S. 1989. Sensitivity of Penman estimates of evaporation to errors in input data. Ag. Water Man. 15:279-300.Priestley, C.H.B. and Taylor, R. J. 1972. On the assessment of surface heat flux and evaporation using large scale parameters. Mon. Weath. Rev., 100: 81-92. Pruitt, W. O. (1996). "Empirical method of estimating evapotranspiration using primarily evaporation pans." Proc. Conf. on Evapotranspiration and its Role in Water Resources Management. Chicago. Dec. pp. 57-61. Stewart, J. B. 1983. A discussion of the relationships between the principal forms of the combination equation for estimating evapotranspiration. Ag. Meteorol. 30:111-127.Rosenberg, N. J., Blad, B. L. and Verma, S. B. 1983. Microclimate. The Biological Environment (2nd edition). J. Wiley, New York.Seemann, J., Chirkov, Y. I., Lomas, J. and Primault, B., 1979. Agrometeorology. Springer Verlag, Berlin, Heidelberg.Seguin, B., Brunet, Y., and Perrier, A. 1982. Estimation of evaporation: a review of existing methods and recent developments in European Geologic Society Symposium on Evaporation. Leeds, U.K., August, 1982, 21 p.Sharma, M. L. 1985. Estimating evapotranspiration. p. 213-281 in Adv. in Irrigation, Vol III, D. Hillel (Editor)., Academic Press, New York.Stewart, J. B. 1983. A discussion of the relationships between the principal forms of the combination equation for estimating evaportranspirations. Ag. Meteorol. 30:111-127.Tanner, C.B. and Pelton, W. L. 1960. Potential evapotranspiration estimates by the approximate energy balance of Penman. J. Geophysical Res. 65 (10): 3391-3413.Tanner, C.B. and Fuchs, M. 1968. Evaporation from unsaturated surfaces: a generalized combination equation. J. Geophysical Res. 73(4): 1299-1304.Thompson, N., Barrie, LA., and Ayles, M. 1981. The Meteorological Office rainfall and evaporation calculation system: MORECS. Hydrological Memorandum 45, Hydrometeorological Services, London, 66 p.Thornthwaite, C. W. 1948. An approach toward a rational classification of climate. Geograph. Rev., 38, 55.Turc, L. 1961. Evaluation des besoins en eau d'irrigation, évapotranspiration potentielle, formule climatique simplifiée et mise a jour. (in French). Ann. Agron. 12:13-49.Watts, P. J. and Hancock, N. H. 1985. Evaporation and potential evaporation - a practical approach for agricultural engineers. Mech. Engrg. Trans. 10(4): 231-240 plus discussions during 1986.Wright, J. L. 1982. New evapotranspiration crop coefficients. J. irrig. and Drain. Div., ASCE, 108 (IR2): 57-74.Wright, J. L. 1988. Daily and seasonal evapotranspiration and yield of irrigated alfalfa in southern Idaho. Agron. J. 80: 662-669.C. ET and weather measurementAllen, R. G. 1996. Assessing integrity of weather data for use in reference evapotranspiration estimation. J. Irrig. and Drain. Engng. Div., ASCE 122(2): 97-106.Allen, R. G., Pruitt, W. O., and Jensen, M. E. 1991. Environmental requirements for lysimeters. pp. 170-181 in Allen, R. G., Howell, T. A., Pruitt, W. O., Walter, LA., and Jensen, M. E. (Editors). Lysimeters for Evapotranspiration and Environmental Measurements. Proc. of the ASCE Int. Symp. on Lysimetry, Honolulu, HA, ASCE, New York, NY.Bastiaanssen, W.G.M. 1995. Regionalization of surface flux densities and moisture indicators in composite terrain. Doctoral thesis, Wageningen Agricultural University; Wageningen, 273 pp.Beard, J. R. 1985. An assessment of water use by turfgrass. p. 45-60 in Gibeault, V. A. and Cockerham, S. T. (Editors). Turfgrass Water Conservation. Publ. 21405, Univ. Calif, Div. of Agrie and Nat. Resour., Berkley, Calif.Biran, I., Bravdo, B., Bushkin-Harav, I., and Rawitz, E. 1981. Water consumption and growth rate of 11 turfgrasses as affected by mowing height, irrigation frequency and soil moisture. Agron. J. 73:85-90.Blad, B. L. and Rosenberg, N. J. 1974. Lysimetric calibration of the Bowen-ratio energy balance method for evapotranspiration estimation in the Central Great plains. J. App. Meteorol. 13(2): 227-236.Brutsaert, W. H., 1982. Evaporation into the Atmosphere. R. Deidel Publishing Company, Dordrecht, Holland.Businger, J. A. 1988. "A note on the Businger-Dyer profiles." Boundary-Layer Meteorol. 42: 145-151.Businger, J. A. and Yaglom, A. M. 1971. "Introduction to Obukhov's paper on 'Turbulence in an atmosphere with a non-uniform température'," Boundary-Layer Meteorol. 2: 3-6.Campbell, G. S. 1977. An Introduction to Environmental Biophysics. Springer Verlag, N.Y. 159 p.Carrijo, O. A. and Cuenca R. H., 1992. Precision of evapotranspiration estimates using neutron probe. J. Irrig. and Drain. Engrg., ASCE 118 (6): 943-953.Dolman, A. J. and Stewart, J. B. 1987. Modelling forest transpiration from climatological data. In: R. H. Swanson, P. Y. Bernier and P. D. Woodard (eds) Forest Hydrology and Watershed Management, IAHS Publ. 167: 319-327.Fritschen, L. J. and Fritschen, C. L. 1991. Design and evaluation of net radiometers. Paper presented at the 7th Symp. on Meteorol. Observations and Instrumentation, Jan. 13-18, 1991., New Orleans, La., U.S.A. 5 p.Gash, J. H. C., Shuttleworth, W. J., Lloyd, C. R., André, J. C., Goutorbe, J. P., and Gelpe, J. 1989. Micrometeorological measurements in Les Landes forest during HAPEX-MOBILHY. Ag. and For. Meteorol. 46:131-147.Grant, D. R. 1975. Comparison of evaporation from barley with Penman estimates. Agric. Meteorol. 15: 49-60.Grebet, P. and Cuenca, R. H. 1991. History of lysimeter design and effects of environmental disturbances. in Allen, R. G., Howell, T. A., Pruitt, W. O., Walter, LA., and Jensen, M. E. (Editors), Lysimeters for Evapotranspiration and Environmental Measurements, ASCE, New York, NY p. 10-18.Itier, B. and Perrier, A. 1976a. Présentation d'une étude analytique de l'advection: I. Advection liée aux variations horizontales de concentration et de température. Ann. Agron. 27(2): 111-140.Itier, B., Brunet, Y., Mcaneney, K. J., and Lagouarde, J. P. 1994. Downwind evolution of scalar fluxes and surface resistance under conditions of local adection. Part I: A reappraisal of bound