金属氧耗竭:有机碳通量和采石场中甲壳类浮游动物的分布

M. Schramm, G. Marzolf
{"title":"金属氧耗竭:有机碳通量和采石场中甲壳类浮游动物的分布","authors":"M. Schramm, G. Marzolf","doi":"10.2307/3226639","DOIUrl":null,"url":null,"abstract":"Particulate organic carbon (POC) flux and the distribution and abundance of crustacean zooplankton and bacteria associated with formation of a metalimnetic oxygen minimum were examined in a deep embayment of Kentucky Lake, Kentucky. POC measurements from sediment traps placed above and below the metalimnion yielded an estimate of the organic material that was metabolized in the metalimnion. This estimate was the molar equivalent of the oxygen that was depleted from the metalimnion. Calculated zooplankton respiration accounted for 26-31% of the observed oxygen loss, except in midsummer when it accounted for 15%. Estimated bacterial respiration accounted for >44% of the observed oxygen loss. The comparison of calculated oxygen demand with observed oxygen loss emphasizes the importance of in situ processes as the cause of the minimum and suggests that metalimnetic deficits may be useful to estimate productivity. The vertical distribution of three species of Daphnia changed as the oxygen minimum formed. Daphnia pulex became entirely hypolimnetic. Thus, changes in chemical structure influence spatial distribution of zooplankton species. Disappearance of oxygen from deep, dark layers of productive thermally stratified lakes is one of the classical dogmata of limnological knowledge (Birge & Juday, 1911). Under homothermal conditions, wind mixing keeps all depths oxygenated through photosynthetic oxygen production in the euphotic zone and atmospheric invasion at the surface. Organic matter, synthesized in the upper lighted layers, is decomposed by bacteria as it sinks, using dissolved oxygen (Henrici, 1939). When mixing is prevented by the thermal/density This study was supported by the Center for Reservoir Research and conducted at the Hancock Biological Station, Murray State University, Murray, Kentucky, U.S.A. We gratefully acknowledge the efforts of Gary Rice for field assistance and Jennifer Burch for zooplankton enumeration. Reviews of the manuscript by Drs. Alan W. Groeger, Michael L. Mathis, and David S. White are appreciated. Contribution no. 18 of the Center for Reservoir Research. TRANS. AM. MICROSC. Soc., 113(2): 105-116. 1994. ? Copyright, 1994, by the American Microscopical Society, Inc. This content downloaded from 207.46.13.193 on Thu, 08 Sep 2016 04:38:24 UTC All use subject to http://about.jstor.org/terms TRANS. AM. MICROSC. SOC. barrier that defines stratification, deep waters are no longer oxygenated, and the net respiratory losses result in oxygen depletion. Disappearance of oxygen from only the metalimnion is one of several variants of this phenomenon. The metalimnetic oxygen minimum, or negative heterograde oxygen profile (Hutchinson, 1957), is characteristic of productive lakes with steep-walled basins and voluminous hypolimnia. These conditions seem to be met often in river impoundments (Cole & Hannan, 1990). In the situation described here, dense metalimnetic populations of crustacean zooplankton were observed, suggesting that animal respiration might contribute significantly to the metalimnetic oxygen loss (Baker et al., 1977; Mindler, 1923; Patalas, 1963; Shapiro, 1960). We felt that if the sinking rate of particulate organic carbon slowed as it reached the density barrier of the upper metalimnion, then either POC would accumulate, or the particulate organic resources for bacteria and for crustacean filter feeders (consuming both POC and bacteria) would be enriched, defining a metabolically active layer that might favor this spatially dramatic oxygen depletion. Thus, our objectives were (1) to measure the flux of particulate organic carbon through the metalimnion in order to compare the POC loss with oxygen loss, (2) to estimate the relative contribution of bacteria and zooplankton to the metalimnetic oxygen depletion, and (3) to document the movements of crustacean zooplankton before and after the formation of the metalimnetic oxygen minimum. DESCRIPTION OF STUDY AREA Pisgah Quarry is a rectangular (ca. 4.3 ha), 33-m deep embayment of Kentucky Lake located approximately 21 km upstream from Kentucky Dam. A metalimnetic oxygen minimum has been observed here annually since 1977 (J. Sickel, personal communication). The basin was quarried during the construction of Kentucky Dam and inundated in 1944 when the reservoir filled. The embayment is isolated from the main portion of Kentucky Lake by a narrow, shallow (2 m) inlet. The quarry walls are vertical on three sides and steep on the fourth. MATERIALS AND METHODS The sampling schedule was designed to extend from before the onset of thermal stratification in the spring (mid-March) until after the fall mixing (late October) in 1989. Sampling intervals were approximately three weeks during this period. The intervals used for calculation of oxygen depletion and POC flux were 7 April-i May (I), 1 May-23 May (II), 23 May-15 June (III), and 15 June-12 July (IV). All samples were taken from a site near the center of the quarry. Temperature and oxygen profiles were measured electrochemically at 1-m intervals (Hydrolab Surveyor II). Light was measured at 1-m intervals (Li-Cor, model LI-185B). Sediment traps, a cluster of four PVC pipes (70 x 7.5 cm) closed at the bottom and open at the top (Hakanson & Jansson, 1983), were suspended with open ends at the top (6 m) and bottom (12 m) of the metalimnetic layer to 106 This content downloaded from 207.46.13.193 on Thu, 08 Sep 2016 04:38:24 UTC All use subject to http://about.jstor.org/terms VOL. 113, NO. 2, APRIL 1994 collect POC settling into and out of the metalimnion. A dense layer of 100 ml of 10% formalin in 50% NaCl was added to the bottom of each trap to arrest decomposition. When the traps were retrieved after each interval, the water in the traps was decanted and the sediment in the preserving layer removed. The sediment sample volume was brought to 1 L with distilled water. The POC content (carbohydrate) was measured by filtering 50-ml subsamples on glass-fiber filters (Whatman GF/F) and oxidizing the POC with dichromate (Strickland & Parsons, 1968). The difference between POC in upper and lower traps represents the amount of POC lost to decomposition in the 6-m layer between the traps. Results are expressed as ALtg POC/cm2/d. The molar equivalent of oxygen represented by the POC then was compared with the change in oxygen concentration during the same period. Bacterial enumeration was performed on water collected at 3-m depth intervals in a 2.2 L van Dorn-style water bottle. A single 25-ml subsample was taken from each sample depth and preserved in the field with 4% filtered, CaCO3 buffered formalin. One one-ml subsample was filtered (0.2 ,m), stained with 4'6-diamidino-2-phenylindole (DAPI), and counted with UV epifluorescence microscopy (Porter & Feig, 1980). One 500-ml subsample was filtered for chlorophyll-A analysis by extraction in 90% acetone (Clesceri et al., 1989). Three replicate zooplankton samples were collected at 3-m intervals on each sampling day with a 15-L Schindler plankton trap fitted with a 63-,im Nitex? sieve bucket (Schindler, 1969). Vertical series were collected at 4-h intervals from noon to 0800 h on 1-2 May and 12-13 July to determine diurnal distribution patterns of zooplankton in relation to the metalimnion before and after the formation of the oxygen minimum. Zooplankters were stored in 70-ml polystyrene tissue-culture flasks and preserved in 3% formalin. Crustacean zooplankters were enumerated without subsampling at magnifications of 50100 x. Respiratory oxygen consumption during each interval was estimated by calculations from published respiration rates of various zooplankton groups (Chaston, 1969; Comita, 1968; Ivanova, 1970; Kibby, 1971; Moshiri et al., 1969; Richman, 1958). The bacterial respiration rate was estimated from data of Kusnetzow & Karsinkin (1931). Respiration rates expressed as carbon were converted to oxygen consumed by applying the mean oxy-caloric coefficient of Winberg et al. (1934) (1 ml O2/mg carbon) and the energy to carbon relation for aquatic invertebrates (10.98 cal/mg carbon) derived by Salonen et al. (1976). Oxygen consumption estimates were converted to mg of oxygen per sampling interval for each of the four intervals. When specific respiration rates were not available, calculations were made using values for the closest allied taxon. RESULTS Analyses presented here are based on the period from 7 April, after stratification was well established, to 12 July, when dissolved oxygen in the metalimnion reached a minimal concentration (Fig. 1). Temperature and oxygen. Thermal stratification was first observed between depths of 7 and 10 m on 24 March. The vertical dimension of the metalimnion 107 This content downloaded from 207.46.13.193 on Thu, 08 Sep 2016 04:38:24 UTC All use subject to http://about.jstor.org/terms TRANS. AM. MICROSC. SOC.","PeriodicalId":23957,"journal":{"name":"Transactions of the American Microscopical Society","volume":"57 1","pages":"105-116"},"PeriodicalIF":0.0000,"publicationDate":"1994-04-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"12","resultStr":"{\"title\":\"Metalimnetic Oxygen Depletion: Organic Carbon Flux and Crustacean Zooplankton Distribution in a Quarry Embayment\",\"authors\":\"M. Schramm, G. Marzolf\",\"doi\":\"10.2307/3226639\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Particulate organic carbon (POC) flux and the distribution and abundance of crustacean zooplankton and bacteria associated with formation of a metalimnetic oxygen minimum were examined in a deep embayment of Kentucky Lake, Kentucky. POC measurements from sediment traps placed above and below the metalimnion yielded an estimate of the organic material that was metabolized in the metalimnion. This estimate was the molar equivalent of the oxygen that was depleted from the metalimnion. Calculated zooplankton respiration accounted for 26-31% of the observed oxygen loss, except in midsummer when it accounted for 15%. Estimated bacterial respiration accounted for >44% of the observed oxygen loss. The comparison of calculated oxygen demand with observed oxygen loss emphasizes the importance of in situ processes as the cause of the minimum and suggests that metalimnetic deficits may be useful to estimate productivity. The vertical distribution of three species of Daphnia changed as the oxygen minimum formed. Daphnia pulex became entirely hypolimnetic. Thus, changes in chemical structure influence spatial distribution of zooplankton species. Disappearance of oxygen from deep, dark layers of productive thermally stratified lakes is one of the classical dogmata of limnological knowledge (Birge & Juday, 1911). Under homothermal conditions, wind mixing keeps all depths oxygenated through photosynthetic oxygen production in the euphotic zone and atmospheric invasion at the surface. Organic matter, synthesized in the upper lighted layers, is decomposed by bacteria as it sinks, using dissolved oxygen (Henrici, 1939). When mixing is prevented by the thermal/density This study was supported by the Center for Reservoir Research and conducted at the Hancock Biological Station, Murray State University, Murray, Kentucky, U.S.A. We gratefully acknowledge the efforts of Gary Rice for field assistance and Jennifer Burch for zooplankton enumeration. Reviews of the manuscript by Drs. Alan W. Groeger, Michael L. Mathis, and David S. White are appreciated. Contribution no. 18 of the Center for Reservoir Research. TRANS. AM. MICROSC. Soc., 113(2): 105-116. 1994. ? Copyright, 1994, by the American Microscopical Society, Inc. This content downloaded from 207.46.13.193 on Thu, 08 Sep 2016 04:38:24 UTC All use subject to http://about.jstor.org/terms TRANS. AM. MICROSC. SOC. barrier that defines stratification, deep waters are no longer oxygenated, and the net respiratory losses result in oxygen depletion. Disappearance of oxygen from only the metalimnion is one of several variants of this phenomenon. The metalimnetic oxygen minimum, or negative heterograde oxygen profile (Hutchinson, 1957), is characteristic of productive lakes with steep-walled basins and voluminous hypolimnia. These conditions seem to be met often in river impoundments (Cole & Hannan, 1990). In the situation described here, dense metalimnetic populations of crustacean zooplankton were observed, suggesting that animal respiration might contribute significantly to the metalimnetic oxygen loss (Baker et al., 1977; Mindler, 1923; Patalas, 1963; Shapiro, 1960). We felt that if the sinking rate of particulate organic carbon slowed as it reached the density barrier of the upper metalimnion, then either POC would accumulate, or the particulate organic resources for bacteria and for crustacean filter feeders (consuming both POC and bacteria) would be enriched, defining a metabolically active layer that might favor this spatially dramatic oxygen depletion. Thus, our objectives were (1) to measure the flux of particulate organic carbon through the metalimnion in order to compare the POC loss with oxygen loss, (2) to estimate the relative contribution of bacteria and zooplankton to the metalimnetic oxygen depletion, and (3) to document the movements of crustacean zooplankton before and after the formation of the metalimnetic oxygen minimum. DESCRIPTION OF STUDY AREA Pisgah Quarry is a rectangular (ca. 4.3 ha), 33-m deep embayment of Kentucky Lake located approximately 21 km upstream from Kentucky Dam. A metalimnetic oxygen minimum has been observed here annually since 1977 (J. Sickel, personal communication). The basin was quarried during the construction of Kentucky Dam and inundated in 1944 when the reservoir filled. The embayment is isolated from the main portion of Kentucky Lake by a narrow, shallow (2 m) inlet. The quarry walls are vertical on three sides and steep on the fourth. MATERIALS AND METHODS The sampling schedule was designed to extend from before the onset of thermal stratification in the spring (mid-March) until after the fall mixing (late October) in 1989. Sampling intervals were approximately three weeks during this period. The intervals used for calculation of oxygen depletion and POC flux were 7 April-i May (I), 1 May-23 May (II), 23 May-15 June (III), and 15 June-12 July (IV). All samples were taken from a site near the center of the quarry. Temperature and oxygen profiles were measured electrochemically at 1-m intervals (Hydrolab Surveyor II). Light was measured at 1-m intervals (Li-Cor, model LI-185B). Sediment traps, a cluster of four PVC pipes (70 x 7.5 cm) closed at the bottom and open at the top (Hakanson & Jansson, 1983), were suspended with open ends at the top (6 m) and bottom (12 m) of the metalimnetic layer to 106 This content downloaded from 207.46.13.193 on Thu, 08 Sep 2016 04:38:24 UTC All use subject to http://about.jstor.org/terms VOL. 113, NO. 2, APRIL 1994 collect POC settling into and out of the metalimnion. A dense layer of 100 ml of 10% formalin in 50% NaCl was added to the bottom of each trap to arrest decomposition. When the traps were retrieved after each interval, the water in the traps was decanted and the sediment in the preserving layer removed. The sediment sample volume was brought to 1 L with distilled water. The POC content (carbohydrate) was measured by filtering 50-ml subsamples on glass-fiber filters (Whatman GF/F) and oxidizing the POC with dichromate (Strickland & Parsons, 1968). The difference between POC in upper and lower traps represents the amount of POC lost to decomposition in the 6-m layer between the traps. Results are expressed as ALtg POC/cm2/d. The molar equivalent of oxygen represented by the POC then was compared with the change in oxygen concentration during the same period. Bacterial enumeration was performed on water collected at 3-m depth intervals in a 2.2 L van Dorn-style water bottle. A single 25-ml subsample was taken from each sample depth and preserved in the field with 4% filtered, CaCO3 buffered formalin. One one-ml subsample was filtered (0.2 ,m), stained with 4'6-diamidino-2-phenylindole (DAPI), and counted with UV epifluorescence microscopy (Porter & Feig, 1980). One 500-ml subsample was filtered for chlorophyll-A analysis by extraction in 90% acetone (Clesceri et al., 1989). Three replicate zooplankton samples were collected at 3-m intervals on each sampling day with a 15-L Schindler plankton trap fitted with a 63-,im Nitex? sieve bucket (Schindler, 1969). Vertical series were collected at 4-h intervals from noon to 0800 h on 1-2 May and 12-13 July to determine diurnal distribution patterns of zooplankton in relation to the metalimnion before and after the formation of the oxygen minimum. Zooplankters were stored in 70-ml polystyrene tissue-culture flasks and preserved in 3% formalin. Crustacean zooplankters were enumerated without subsampling at magnifications of 50100 x. Respiratory oxygen consumption during each interval was estimated by calculations from published respiration rates of various zooplankton groups (Chaston, 1969; Comita, 1968; Ivanova, 1970; Kibby, 1971; Moshiri et al., 1969; Richman, 1958). The bacterial respiration rate was estimated from data of Kusnetzow & Karsinkin (1931). Respiration rates expressed as carbon were converted to oxygen consumed by applying the mean oxy-caloric coefficient of Winberg et al. (1934) (1 ml O2/mg carbon) and the energy to carbon relation for aquatic invertebrates (10.98 cal/mg carbon) derived by Salonen et al. (1976). Oxygen consumption estimates were converted to mg of oxygen per sampling interval for each of the four intervals. When specific respiration rates were not available, calculations were made using values for the closest allied taxon. RESULTS Analyses presented here are based on the period from 7 April, after stratification was well established, to 12 July, when dissolved oxygen in the metalimnion reached a minimal concentration (Fig. 1). Temperature and oxygen. Thermal stratification was first observed between depths of 7 and 10 m on 24 March. The vertical dimension of the metalimnion 107 This content downloaded from 207.46.13.193 on Thu, 08 Sep 2016 04:38:24 UTC All use subject to http://about.jstor.org/terms TRANS. AM. MICROSC. 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引用次数: 12

摘要

温度和氧气分布以1米间隔进行电化学测量(Hydrolab Surveyor II)。光以1米间隔进行测量(Li-Cor,型号LI-185B)。沉积物捕集器是一组四根PVC管(70 x 7.5 cm),底部关闭,顶部打开(Hakanson & Jansson, 1983),在金属层的顶部(6米)和底部(12米)两端开放,悬挂到106。1994年4月2日收集进入和离开金属离子的POC。在每个捕集器的底部加入100 ml 10%福尔马林和50% NaCl的致密层,以阻止分解。当每次间隔后回收捕集器时,将捕集器中的水倒掉,并去除保存层中的沉积物。用蒸馏水将沉积物样品体积调至1l。POC含量(碳水化合物)是通过在玻璃纤维过滤器(Whatman GF/F)上过滤50毫升亚样品并用重铬酸盐氧化POC来测量的(Strickland & Parsons, 1968)。上下圈闭中POC的差值代表了两个圈闭之间6 m层中POC因分解而损失的量。结果用ALtg POC/cm2/d表示。然后将POC所代表的氧的摩尔当量与同期氧浓度的变化进行比较。在2.2 L van dorn型水瓶中,每隔3 m深度采集水进行细菌计数。每个取样深度取一个25ml的子样本,用4%过滤、CaCO3缓冲的福尔马林在田间保存。过滤1 ml亚样品(0.2,m),用4'6-二氨基-2-苯基吲哚(DAPI)染色,用紫外荧光显微镜计数(Porter & Feig, 1980)。一个500毫升的亚样本通过90%丙酮萃取过滤后进行叶绿素- a分析(Clesceri et al, 1989)。在每个采样日每隔3米收集3个重复的浮游动物样本,使用15-L Schindler浮游生物捕集器,安装63- im Nitex?筛子桶(辛德勒,1969)。在5月1日至2日和7月12日至13日中午至0800 h,每隔4 h采集垂直序列,测定浮游动物在氧最小值形成前后的金属离子分布规律。浮游动物储存在70毫升聚苯乙烯组织培养瓶中,并保存在3%福尔马林中。以50100倍的倍率对甲壳类浮游动物进行了不抽样的枚举。每个间隔期间的呼吸耗氧量是根据已发表的各种浮游动物类群的呼吸速率计算得出的(Chaston, 1969;Comita, 1968;伊万诺娃,1970;Kibby, 1971;Moshiri et al., 1969;里奇曼,1958)。细菌呼吸速率是根据Kusnetzow & Karsinkin(1931)的数据估计的。通过应用Winberg et al.(1934)的平均氧热系数(1 ml O2/mg碳)和Salonen et al.(1976)得出的水生无脊椎动物的能量碳关系(10.98 cal/mg碳),将以碳表示的呼吸速率转换为消耗的氧气。对四个间隔中的每一个采样间隔,将耗氧量估算值转换为毫克氧。当不能得到特定的呼吸速率时,使用最接近的类群的值进行计算。结果:本文的分析基于4月7日分层建立后至7月12日期间,此时金属离子中的溶解氧达到最低浓度(图1)。3月24日,在7 ~ 10 m深度间首次观测到热分层。这个内容从207.46.13.193下载于2016年9月8日星期四04:38:24 UTC所有内容以http://about.jstor.org/terms TRANS为准。点。MICROSC。SOC。
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Metalimnetic Oxygen Depletion: Organic Carbon Flux and Crustacean Zooplankton Distribution in a Quarry Embayment
Particulate organic carbon (POC) flux and the distribution and abundance of crustacean zooplankton and bacteria associated with formation of a metalimnetic oxygen minimum were examined in a deep embayment of Kentucky Lake, Kentucky. POC measurements from sediment traps placed above and below the metalimnion yielded an estimate of the organic material that was metabolized in the metalimnion. This estimate was the molar equivalent of the oxygen that was depleted from the metalimnion. Calculated zooplankton respiration accounted for 26-31% of the observed oxygen loss, except in midsummer when it accounted for 15%. Estimated bacterial respiration accounted for >44% of the observed oxygen loss. The comparison of calculated oxygen demand with observed oxygen loss emphasizes the importance of in situ processes as the cause of the minimum and suggests that metalimnetic deficits may be useful to estimate productivity. The vertical distribution of three species of Daphnia changed as the oxygen minimum formed. Daphnia pulex became entirely hypolimnetic. Thus, changes in chemical structure influence spatial distribution of zooplankton species. Disappearance of oxygen from deep, dark layers of productive thermally stratified lakes is one of the classical dogmata of limnological knowledge (Birge & Juday, 1911). Under homothermal conditions, wind mixing keeps all depths oxygenated through photosynthetic oxygen production in the euphotic zone and atmospheric invasion at the surface. Organic matter, synthesized in the upper lighted layers, is decomposed by bacteria as it sinks, using dissolved oxygen (Henrici, 1939). When mixing is prevented by the thermal/density This study was supported by the Center for Reservoir Research and conducted at the Hancock Biological Station, Murray State University, Murray, Kentucky, U.S.A. We gratefully acknowledge the efforts of Gary Rice for field assistance and Jennifer Burch for zooplankton enumeration. Reviews of the manuscript by Drs. Alan W. Groeger, Michael L. Mathis, and David S. White are appreciated. Contribution no. 18 of the Center for Reservoir Research. TRANS. AM. MICROSC. Soc., 113(2): 105-116. 1994. ? Copyright, 1994, by the American Microscopical Society, Inc. This content downloaded from 207.46.13.193 on Thu, 08 Sep 2016 04:38:24 UTC All use subject to http://about.jstor.org/terms TRANS. AM. MICROSC. SOC. barrier that defines stratification, deep waters are no longer oxygenated, and the net respiratory losses result in oxygen depletion. Disappearance of oxygen from only the metalimnion is one of several variants of this phenomenon. The metalimnetic oxygen minimum, or negative heterograde oxygen profile (Hutchinson, 1957), is characteristic of productive lakes with steep-walled basins and voluminous hypolimnia. These conditions seem to be met often in river impoundments (Cole & Hannan, 1990). In the situation described here, dense metalimnetic populations of crustacean zooplankton were observed, suggesting that animal respiration might contribute significantly to the metalimnetic oxygen loss (Baker et al., 1977; Mindler, 1923; Patalas, 1963; Shapiro, 1960). We felt that if the sinking rate of particulate organic carbon slowed as it reached the density barrier of the upper metalimnion, then either POC would accumulate, or the particulate organic resources for bacteria and for crustacean filter feeders (consuming both POC and bacteria) would be enriched, defining a metabolically active layer that might favor this spatially dramatic oxygen depletion. Thus, our objectives were (1) to measure the flux of particulate organic carbon through the metalimnion in order to compare the POC loss with oxygen loss, (2) to estimate the relative contribution of bacteria and zooplankton to the metalimnetic oxygen depletion, and (3) to document the movements of crustacean zooplankton before and after the formation of the metalimnetic oxygen minimum. DESCRIPTION OF STUDY AREA Pisgah Quarry is a rectangular (ca. 4.3 ha), 33-m deep embayment of Kentucky Lake located approximately 21 km upstream from Kentucky Dam. A metalimnetic oxygen minimum has been observed here annually since 1977 (J. Sickel, personal communication). The basin was quarried during the construction of Kentucky Dam and inundated in 1944 when the reservoir filled. The embayment is isolated from the main portion of Kentucky Lake by a narrow, shallow (2 m) inlet. The quarry walls are vertical on three sides and steep on the fourth. MATERIALS AND METHODS The sampling schedule was designed to extend from before the onset of thermal stratification in the spring (mid-March) until after the fall mixing (late October) in 1989. Sampling intervals were approximately three weeks during this period. The intervals used for calculation of oxygen depletion and POC flux were 7 April-i May (I), 1 May-23 May (II), 23 May-15 June (III), and 15 June-12 July (IV). All samples were taken from a site near the center of the quarry. Temperature and oxygen profiles were measured electrochemically at 1-m intervals (Hydrolab Surveyor II). Light was measured at 1-m intervals (Li-Cor, model LI-185B). Sediment traps, a cluster of four PVC pipes (70 x 7.5 cm) closed at the bottom and open at the top (Hakanson & Jansson, 1983), were suspended with open ends at the top (6 m) and bottom (12 m) of the metalimnetic layer to 106 This content downloaded from 207.46.13.193 on Thu, 08 Sep 2016 04:38:24 UTC All use subject to http://about.jstor.org/terms VOL. 113, NO. 2, APRIL 1994 collect POC settling into and out of the metalimnion. A dense layer of 100 ml of 10% formalin in 50% NaCl was added to the bottom of each trap to arrest decomposition. When the traps were retrieved after each interval, the water in the traps was decanted and the sediment in the preserving layer removed. The sediment sample volume was brought to 1 L with distilled water. The POC content (carbohydrate) was measured by filtering 50-ml subsamples on glass-fiber filters (Whatman GF/F) and oxidizing the POC with dichromate (Strickland & Parsons, 1968). The difference between POC in upper and lower traps represents the amount of POC lost to decomposition in the 6-m layer between the traps. Results are expressed as ALtg POC/cm2/d. The molar equivalent of oxygen represented by the POC then was compared with the change in oxygen concentration during the same period. Bacterial enumeration was performed on water collected at 3-m depth intervals in a 2.2 L van Dorn-style water bottle. A single 25-ml subsample was taken from each sample depth and preserved in the field with 4% filtered, CaCO3 buffered formalin. One one-ml subsample was filtered (0.2 ,m), stained with 4'6-diamidino-2-phenylindole (DAPI), and counted with UV epifluorescence microscopy (Porter & Feig, 1980). One 500-ml subsample was filtered for chlorophyll-A analysis by extraction in 90% acetone (Clesceri et al., 1989). Three replicate zooplankton samples were collected at 3-m intervals on each sampling day with a 15-L Schindler plankton trap fitted with a 63-,im Nitex? sieve bucket (Schindler, 1969). Vertical series were collected at 4-h intervals from noon to 0800 h on 1-2 May and 12-13 July to determine diurnal distribution patterns of zooplankton in relation to the metalimnion before and after the formation of the oxygen minimum. Zooplankters were stored in 70-ml polystyrene tissue-culture flasks and preserved in 3% formalin. Crustacean zooplankters were enumerated without subsampling at magnifications of 50100 x. Respiratory oxygen consumption during each interval was estimated by calculations from published respiration rates of various zooplankton groups (Chaston, 1969; Comita, 1968; Ivanova, 1970; Kibby, 1971; Moshiri et al., 1969; Richman, 1958). The bacterial respiration rate was estimated from data of Kusnetzow & Karsinkin (1931). Respiration rates expressed as carbon were converted to oxygen consumed by applying the mean oxy-caloric coefficient of Winberg et al. (1934) (1 ml O2/mg carbon) and the energy to carbon relation for aquatic invertebrates (10.98 cal/mg carbon) derived by Salonen et al. (1976). Oxygen consumption estimates were converted to mg of oxygen per sampling interval for each of the four intervals. When specific respiration rates were not available, calculations were made using values for the closest allied taxon. RESULTS Analyses presented here are based on the period from 7 April, after stratification was well established, to 12 July, when dissolved oxygen in the metalimnion reached a minimal concentration (Fig. 1). Temperature and oxygen. Thermal stratification was first observed between depths of 7 and 10 m on 24 March. The vertical dimension of the metalimnion 107 This content downloaded from 207.46.13.193 on Thu, 08 Sep 2016 04:38:24 UTC All use subject to http://about.jstor.org/terms TRANS. AM. MICROSC. SOC.
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