OPTICAL PROPERTIES OF LAKE VENDYURSKOE

We conducted a field study on light conditions in a small boreal Karelian Lake Vendyurskoe over two years. Albedo of ice-covered lake varied from 0.9 to 0.1, and the euphotic zone depth exceeded 3.5 m during the melting stage. The Secchi disc depth changed from 2.5 m after ice-break to 3.7 m at the...

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Published in:	GEOGRAPHY, ENVIRONMENT, SUSTAINABILITY
Main Authors:	Roman Zdorovennov G., Galina Gavrilenko G., Galina Zdorovennova E., Nikolay Palshin I., Tatyana Efremova V., Sergey Golosov D., Arkady Terzhevik Yu.
Format:	Article in Journal/Newspaper
Language:	English
Published:	Russian Geographical Society 2016
Subjects:	ice-covered lake;albedo;photosynthetically active radiation;under-ice irradiance;PAR attenuation coefficient Annals of Glaciology Arctic karelian
Online Access:	https://ges.rgo.ru/jour/article/view/108 https://doi.org/10.15356/2071-9388_03v09_2016_05

id	ftjges:oai:oai.gesj.elpub.ru:article/108
record_format	openpolar
institution	Open Polar
collection	Geography, Environment, Sustainability (E-Journal)
op_collection_id	ftjges
language	English
topic	ice-covered lake;albedo;photosynthetically active radiation;under-ice irradiance;PAR attenuation coefficient
spellingShingle	ice-covered lake;albedo;photosynthetically active radiation;under-ice irradiance;PAR attenuation coefficient Roman Zdorovennov G. Galina Gavrilenko G. Galina Zdorovennova E. Nikolay Palshin I. Tatyana Efremova V. Sergey Golosov D. Arkady Terzhevik Yu. OPTICAL PROPERTIES OF LAKE VENDYURSKOE
topic_facet	ice-covered lake;albedo;photosynthetically active radiation;under-ice irradiance;PAR attenuation coefficient
description	We conducted a field study on light conditions in a small boreal Karelian Lake Vendyurskoe over two years. Albedo of ice-covered lake varied from 0.9 to 0.1, and the euphotic zone depth exceeded 3.5 m during the melting stage. The Secchi disc depth changed from 2.5 m after ice-break to 3.7 m at the stage of early summer. The vertical distribution of the photosynthetically active solar radiation (PAR) attenuation coefficient for water Kw was characterized by high spatial (vertical) and temporal (seasonal and interannual) variabilitywhich can be connected with the dynamics of plankton cells. The highest values of Kw eached 2–2.8 m–1 in the upper 0.5 m layer of a water column, and decreased to 0.5–1.5 m–1 with increasing depth. The highest values of Kw were marked in the end of ice-covered period.
format	Article in Journal/Newspaper
author	Roman Zdorovennov G. Galina Gavrilenko G. Galina Zdorovennova E. Nikolay Palshin I. Tatyana Efremova V. Sergey Golosov D. Arkady Terzhevik Yu.
author_facet	Roman Zdorovennov G. Galina Gavrilenko G. Galina Zdorovennova E. Nikolay Palshin I. Tatyana Efremova V. Sergey Golosov D. Arkady Terzhevik Yu.
author_sort	Roman Zdorovennov G.
title	OPTICAL PROPERTIES OF LAKE VENDYURSKOE
title_short	OPTICAL PROPERTIES OF LAKE VENDYURSKOE
title_full	OPTICAL PROPERTIES OF LAKE VENDYURSKOE
title_fullStr	OPTICAL PROPERTIES OF LAKE VENDYURSKOE
title_full_unstemmed	OPTICAL PROPERTIES OF LAKE VENDYURSKOE
title_sort	optical properties of lake vendyurskoe
publisher	Russian Geographical Society
publishDate	2016
url	https://ges.rgo.ru/jour/article/view/108 https://doi.org/10.15356/2071-9388_03v09_2016_05
genre	Annals of Glaciology Arctic karelian
genre_facet	Annals of Glaciology Arctic karelian
op_source	GEOGRAPHY, ENVIRONMENT, SUSTAINABILITY; Vol 9, No 3 (2016); 74-87 2542-1565 2071-9388
op_relation	https://ges.rgo.ru/jour/article/view/108/108 Arst H., Erm A., Leppäranta M. & Reinart A. (2006) Radiative characteristics of ice-covered fresh- and brackish-water bodies. Proc. of the Estonian Academy of Sciences, Geology. 55 (1): 3–23. Arst H., Erm A., Herlevi A., Kutser T., Leppäranta M., Reinart A. & Virta J. (2008) Optical properties of boreal lake water in Finland and Estonia. Boreal Env. Res.13: 133–158. Belzile C., Vincent W.F., Gibson J.A.E. & Van Hove P. (2001) Bio-optical characteristics of the snow, ice, and water column of a perennially ice-covered lake in the High Arctic. Can. J. Fish. Aquat. Sci. 58: 2405–2418. Bolsenga S.J. &Vanderploeg H.A. (1992) Estimating photosynthetically available radiation into open and ice-covered freshwater lakes from surface characteristics; a high transmittance case study. Hydrobiologia. 243/244: 95–104. Chekhin L.P. (1987) Svetovoi rezhim vodoemov [Light Regime of Water Bodies]. Petrozavodsk: Karel’skii filial AN SSSR. 130 p. [in Russian]. Fritsen C.H. & Priscu J.C. (1999) Seasonal change in the optical properties of the permanent ice cover on Lake Bonney, Antarctica: consequences for lake productivity and phytoplankton dynamics. Limnol. Oceanogr. 44: 447–454. Henderson-Sellers B. (1984) Engineering Limnology. Boston: Pitman Advanced Publishing Program. Jakkila J., Leppäranta M., Kawamura T., Shirasawa K. & Salonen K. (2009) Radiation transfer and heat budget during the melting season in Lake Pääjärvi. Aquatic Ecology. 43 (3): 681–692. Jerlov N.G. (1976) Marine optic. Elsevier Oceanography Series 5, Elsevier, Amsterdam–Oxford– New-York. Jewson D.H., Granin N.G., Zhdanov A.A. & Gnatovsky R.Yu. (2009) Effect of snow depth on under-ice irradiance and growth of Aulacoseira baicalensis in Lake Baikal. Aquatic Ecology. 43(3): 673–679. Kirillin G., Leppäranta M., Terzhevik A., Granin N., Bernhardt J., Engelhardt C., Efremova T., Palshin N., Sherstyankin P., Zdorovennova G. & Zdorovennov R. (2012) Physics of seasonally ice-covered lakes: a review. Aquatic Sciences. 74 (4): 659–682. Zdorovennov R.G., Gavrilenko G.G. et al. OPTICAL PROPERTIES OF LAKE VENDYURSKOE Lei R., Leppäranta M., Erm A., Jaatinen E. & Pärn O. (2011) Field investigations of apparent optical properties of ice cover in Finnish and Estonian lakes in winter 2009. Estonian Journal of Earth Science. 60 (1): 50–64. Leppäranta M., Reinart A., Erm A., Arst H., Hussainov M. & Sipelgas L. (2003) Investigation of Ice and Water Properties and Under-ice Light Fields in Fresh and Brackish Water Bodies. Nordic Hydrology. 34 (3): 245–266. Leppäranta M., Terzhevik A. & Shirasawa K. (2010) Solar radiation and ice melting in Lake Vendyurskoe, Russian Karelia. Hydrology Research. 41 (1): 50–62. Malm J., Terzhevik A., Bengtsson L., Boyarinov P., Glinsky A., Palshin N. & Petrov M. (1997) Temperature and Hydrodynamics in Lake Vendurskoe during Winter 1995/1996. Department of Water Resources Engineering, Institute of Technology. University of Lund, № .3213. 203 p. Matthews P.C. & Heaney S.A. (1987) Solar heating and its influence on mixing in icecovered lakes. Freshwater Biology. 18: 135–149. Mironov D.V. & Terzhevik A.Y. (2000) Spring convection in ice-covered freshwater lakes. Izvestiya Atmospheric and Oceanic Physics. 36 (5): 627–634. Mironov D., Terzhevik A., Kirillin G., Jonas T., Malm J. & Farmer D. (2002) Radiatively-driven convection in ice-covered lakes: observations, scaling and a mixed-layer model. J. Geophys. Res. 107 (C4): 7-1-7-16. Mironov D., Heise E., Kourzeneva E., Ritter B., Schneider N. & Terzhevik A. (2010) Implementation of the lake parameterization scheme FLake into the numerical weather prediction model COSMO. Boreal Env. Res. 15: 218–230. Petrov M.P., Terzhevik A.Y., Palshin N.I., Zdorovennov R.E. & Zdorovennova G.E. (2005) Absorption of Solar Radiation by Snow-and-Ice Cover of Lakes. Water Resources. 32 (5): 496–504. Reynolds C.S. (2006) The Ecology of Phytoplankton. Cambridge University Press. Tulonen T., Kankaala P., Ojala A. & Arvola L. (1994) Factors controlling production of phytoplankton and bacteria under ice in a humic, boreal lake. J. of Plankton Res. 16 (10):1411–1432. Twiss M.R., Smith D.E., Cafferty E.M. & Carrick H.J. (2012) Diatoms abound in ice-covered Lake Erie: An investigation of offshore winter limnology in Lake Erie over the period 2007 to 2010. J. Great Lakes Res. 38: 18–30. Vanderploeg H.A., Bolsenga S.J., Fahnenstiel G.L., Liebig J.R. & Gardner W.S. (1992) Plankton ecology in an ice-covered bay of Lake Michigan: utilization of a winter phytoplankton bloom by reproducing copepods. Hydrobiologia. 243–244 (1): 175–183. Williams D.T., Drummond G.R., Ford D.E. & Robey D.L. (1981) Determination of light extinction coefficients in lakes and reservoirs. Proc. ASCE Symp. On Surface Water Impoundements. Minneapolis, Minnesota. 2: 1329–1335. Zaneveld J.R.V., Kitchen J.C. & Pak H. (1981) The influence of optical water type on the heating rate of a constant depth mixed layer. Journal of Geophysical Research. 86 (C7): 6426–6428. Zdorovennov R., Palshin N., Zdorovennova G., Efremova T. & Terzhevik A. (2013) Interannual variability of ice and snow cover of a small shallow lake. Estonian Journal of Earth Science. 61 (1): 26–32. Zdorovennova G., Zdorovennov R., Palshin N. & Terzhevik A. (2013) Optical properties of the ice cover on Vendyurskoe lake, Russian Karelia (1995–2012). Annals of Glaciology. 54 (62): 121–124. https://ges.rgo.ru/jour/article/view/108 doi:10.15356/2071-9388_03v09_2016_05
op_rights	Authors who publish with this journal agree to the following terms:Authors retain copyright and grant the journal the right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.Authors can enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgment of its initial publication in this journal.Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work (See The Effect of Open Access).The information and opinions presented in the Journal reflect the views of the authors and not of the Journal or its Editorial Board or the Publisher. The GES Journal has used its best endeavors to ensure that the information is correct and current at the time of publication but takes no responsibility for any error, omission, or defect therein. Авторы, публикующие в данном журнале, соглашаются со следующим:Авторы сохраняют за собой авторские права на работу и предоставляют журналу право первой публикации работы на условиях лицензии Creative Commons Attribution License, которая позволяет другим распространять данную работу с обязательным сохранением ссылок на авторов оригинальной работы и оригинальную публикацию в этом журнале.Авторы сохраняют право заключать отдельные контрактные договорённости, касающиеся не-эксклюзивного распространения версии работы в опубликованном здесь виде (например, размещение ее в институтском хранилище, публикацию в книге), со ссылкой на ее оригинальную публикацию в этом журнале.Авторы имеют право размещать их работу
op_rightsnorm	CC-BY
op_doi	https://doi.org/10.15356/2071-9388_03v09_2016_05
container_title	GEOGRAPHY, ENVIRONMENT, SUSTAINABILITY
container_volume	9
container_issue	3
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spelling	ftjges:oai:oai.gesj.elpub.ru:article/108 2023-05-15T13:29:51+02:00 OPTICAL PROPERTIES OF LAKE VENDYURSKOE Roman Zdorovennov G. Galina Gavrilenko G. Galina Zdorovennova E. Nikolay Palshin I. Tatyana Efremova V. Sergey Golosov D. Arkady Terzhevik Yu. 2016-09-01 application/pdf https://ges.rgo.ru/jour/article/view/108 https://doi.org/10.15356/2071-9388_03v09_2016_05 eng eng Russian Geographical Society https://ges.rgo.ru/jour/article/view/108/108 Arst H., Erm A., Leppäranta M. & Reinart A. (2006) Radiative characteristics of ice-covered fresh- and brackish-water bodies. Proc. of the Estonian Academy of Sciences, Geology. 55 (1): 3–23. Arst H., Erm A., Herlevi A., Kutser T., Leppäranta M., Reinart A. & Virta J. (2008) Optical properties of boreal lake water in Finland and Estonia. Boreal Env. Res.13: 133–158. Belzile C., Vincent W.F., Gibson J.A.E. & Van Hove P. (2001) Bio-optical characteristics of the snow, ice, and water column of a perennially ice-covered lake in the High Arctic. Can. J. Fish. Aquat. Sci. 58: 2405–2418. Bolsenga S.J. &Vanderploeg H.A. (1992) Estimating photosynthetically available radiation into open and ice-covered freshwater lakes from surface characteristics; a high transmittance case study. Hydrobiologia. 243/244: 95–104. Chekhin L.P. (1987) Svetovoi rezhim vodoemov [Light Regime of Water Bodies]. Petrozavodsk: Karel’skii filial AN SSSR. 130 p. [in Russian]. Fritsen C.H. & Priscu J.C. (1999) Seasonal change in the optical properties of the permanent ice cover on Lake Bonney, Antarctica: consequences for lake productivity and phytoplankton dynamics. Limnol. Oceanogr. 44: 447–454. Henderson-Sellers B. (1984) Engineering Limnology. Boston: Pitman Advanced Publishing Program. Jakkila J., Leppäranta M., Kawamura T., Shirasawa K. & Salonen K. (2009) Radiation transfer and heat budget during the melting season in Lake Pääjärvi. Aquatic Ecology. 43 (3): 681–692. Jerlov N.G. (1976) Marine optic. Elsevier Oceanography Series 5, Elsevier, Amsterdam–Oxford– New-York. Jewson D.H., Granin N.G., Zhdanov A.A. & Gnatovsky R.Yu. (2009) Effect of snow depth on under-ice irradiance and growth of Aulacoseira baicalensis in Lake Baikal. Aquatic Ecology. 43(3): 673–679. Kirillin G., Leppäranta M., Terzhevik A., Granin N., Bernhardt J., Engelhardt C., Efremova T., Palshin N., Sherstyankin P., Zdorovennova G. & Zdorovennov R. (2012) Physics of seasonally ice-covered lakes: a review. Aquatic Sciences. 74 (4): 659–682. Zdorovennov R.G., Gavrilenko G.G. et al. OPTICAL PROPERTIES OF LAKE VENDYURSKOE Lei R., Leppäranta M., Erm A., Jaatinen E. & Pärn O. (2011) Field investigations of apparent optical properties of ice cover in Finnish and Estonian lakes in winter 2009. Estonian Journal of Earth Science. 60 (1): 50–64. Leppäranta M., Reinart A., Erm A., Arst H., Hussainov M. & Sipelgas L. (2003) Investigation of Ice and Water Properties and Under-ice Light Fields in Fresh and Brackish Water Bodies. Nordic Hydrology. 34 (3): 245–266. Leppäranta M., Terzhevik A. & Shirasawa K. (2010) Solar radiation and ice melting in Lake Vendyurskoe, Russian Karelia. Hydrology Research. 41 (1): 50–62. Malm J., Terzhevik A., Bengtsson L., Boyarinov P., Glinsky A., Palshin N. & Petrov M. (1997) Temperature and Hydrodynamics in Lake Vendurskoe during Winter 1995/1996. Department of Water Resources Engineering, Institute of Technology. University of Lund, № .3213. 203 p. Matthews P.C. & Heaney S.A. (1987) Solar heating and its influence on mixing in icecovered lakes. Freshwater Biology. 18: 135–149. Mironov D.V. & Terzhevik A.Y. (2000) Spring convection in ice-covered freshwater lakes. Izvestiya Atmospheric and Oceanic Physics. 36 (5): 627–634. Mironov D., Terzhevik A., Kirillin G., Jonas T., Malm J. & Farmer D. (2002) Radiatively-driven convection in ice-covered lakes: observations, scaling and a mixed-layer model. J. Geophys. Res. 107 (C4): 7-1-7-16. Mironov D., Heise E., Kourzeneva E., Ritter B., Schneider N. & Terzhevik A. (2010) Implementation of the lake parameterization scheme FLake into the numerical weather prediction model COSMO. Boreal Env. Res. 15: 218–230. Petrov M.P., Terzhevik A.Y., Palshin N.I., Zdorovennov R.E. & Zdorovennova G.E. (2005) Absorption of Solar Radiation by Snow-and-Ice Cover of Lakes. Water Resources. 32 (5): 496–504. Reynolds C.S. (2006) The Ecology of Phytoplankton. Cambridge University Press. Tulonen T., Kankaala P., Ojala A. & Arvola L. (1994) Factors controlling production of phytoplankton and bacteria under ice in a humic, boreal lake. J. of Plankton Res. 16 (10):1411–1432. Twiss M.R., Smith D.E., Cafferty E.M. & Carrick H.J. (2012) Diatoms abound in ice-covered Lake Erie: An investigation of offshore winter limnology in Lake Erie over the period 2007 to 2010. J. Great Lakes Res. 38: 18–30. Vanderploeg H.A., Bolsenga S.J., Fahnenstiel G.L., Liebig J.R. & Gardner W.S. (1992) Plankton ecology in an ice-covered bay of Lake Michigan: utilization of a winter phytoplankton bloom by reproducing copepods. Hydrobiologia. 243–244 (1): 175–183. Williams D.T., Drummond G.R., Ford D.E. & Robey D.L. (1981) Determination of light extinction coefficients in lakes and reservoirs. Proc. ASCE Symp. On Surface Water Impoundements. Minneapolis, Minnesota. 2: 1329–1335. Zaneveld J.R.V., Kitchen J.C. & Pak H. (1981) The influence of optical water type on the heating rate of a constant depth mixed layer. Journal of Geophysical Research. 86 (C7): 6426–6428. Zdorovennov R., Palshin N., Zdorovennova G., Efremova T. & Terzhevik A. (2013) Interannual variability of ice and snow cover of a small shallow lake. Estonian Journal of Earth Science. 61 (1): 26–32. Zdorovennova G., Zdorovennov R., Palshin N. & Terzhevik A. (2013) Optical properties of the ice cover on Vendyurskoe lake, Russian Karelia (1995–2012). Annals of Glaciology. 54 (62): 121–124. https://ges.rgo.ru/jour/article/view/108 doi:10.15356/2071-9388_03v09_2016_05 Authors who publish with this journal agree to the following terms:Authors retain copyright and grant the journal the right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.Authors can enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgment of its initial publication in this journal.Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work (See The Effect of Open Access).The information and opinions presented in the Journal reflect the views of the authors and not of the Journal or its Editorial Board or the Publisher. The GES Journal has used its best endeavors to ensure that the information is correct and current at the time of publication but takes no responsibility for any error, omission, or defect therein. Авторы, публикующие в данном журнале, соглашаются со следующим:Авторы сохраняют за собой авторские права на работу и предоставляют журналу право первой публикации работы на условиях лицензии Creative Commons Attribution License, которая позволяет другим распространять данную работу с обязательным сохранением ссылок на авторов оригинальной работы и оригинальную публикацию в этом журнале.Авторы сохраняют право заключать отдельные контрактные договорённости, касающиеся не-эксклюзивного распространения версии работы в опубликованном здесь виде (например, размещение ее в институтском хранилище, публикацию в книге), со ссылкой на ее оригинальную публикацию в этом журнале.Авторы имеют право размещать их работу CC-BY GEOGRAPHY, ENVIRONMENT, SUSTAINABILITY; Vol 9, No 3 (2016); 74-87 2542-1565 2071-9388 ice-covered lake;albedo;photosynthetically active radiation;under-ice irradiance;PAR attenuation coefficient info:eu-repo/semantics/article info:eu-repo/semantics/publishedVersion 2016 ftjges https://doi.org/10.15356/2071-9388_03v09_2016_05 2021-05-21T07:34:00Z We conducted a field study on light conditions in a small boreal Karelian Lake Vendyurskoe over two years. Albedo of ice-covered lake varied from 0.9 to 0.1, and the euphotic zone depth exceeded 3.5 m during the melting stage. The Secchi disc depth changed from 2.5 m after ice-break to 3.7 m at the stage of early summer. The vertical distribution of the photosynthetically active solar radiation (PAR) attenuation coefficient for water Kw was characterized by high spatial (vertical) and temporal (seasonal and interannual) variabilitywhich can be connected with the dynamics of plankton cells. The highest values of Kw eached 2–2.8 m–1 in the upper 0.5 m layer of a water column, and decreased to 0.5–1.5 m–1 with increasing depth. The highest values of Kw were marked in the end of ice-covered period. Article in Journal/Newspaper Annals of Glaciology Arctic karelian Geography, Environment, Sustainability (E-Journal) GEOGRAPHY, ENVIRONMENT, SUSTAINABILITY 9 3 74 87

OPTICAL PROPERTIES OF LAKE VENDYURSKOE

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