• 환경생물
• /
• 제26권3호
• /
• pp.252-263
• /
• 2008

본 연구는 연구의 목적은 총질소(TN), 총인(TP), 엽록소(Chl), 투명도(SD)의 변수를 이용하여 호수의 영양상태(Trophic state)를 평가하였고, 전기전도도에 따르면 부유물질(SS)의 역동성을 비교 평가하여 총질소-엽록소(TN-Chl), 총인-엽록소(TP-Chl), 엽록소-투명도(Chl-SD)의 경험적 모델을 분석하였다. 호소의 영양상태 분석에 따르면, 36개 인공호 중 절반이상이 부영양-과영양화 상태 (Eutrophy-Hypertrophy)로 나타났다. 총인의 월 변이(% Variation)가 최고 500%까지 상회하였으며 특히 8월에는 연중 최고치를 보였다. 한편 총질소의 월 변이는 90% 이하로 나타났으며, 모든 호수에서 평균 총질소 농도는 1.2 mg L$^{-1}$ 이상을 상회하여, 배경 농도가 높은 것으로 나타났다(부영양-과명양화상태). 경험적 모델 분석에 따르면 투명도의 변이는 총인(R$^2$=0.15, p<0.001) 및 총질소 (R$^2$=0.20, p<0.001)보다 주로 엽록소 (R$^2$=0.31, p<0.001)에 의해 설명되는 것으로 나타났다 총인, 총 질소의 비 (TN : TP ratio)의 분석에 따르면, 대부부의 인공호는 조류 생장에 있어 잠재적인 인(P)의 영향을 시사하였다. 따라서 식물성 플랑크톤 성장은 질소보다 인에 의하여 조절 되는 것으로 나타났다. 수질 변수의 연 평균값에 로그-전환(Log$_{10}$ transformation)한 후 실시한 선형 회귀분석에 따르면 엽록소는 총인 및 총질소에 의해 각각 30%, 15% 설명되어, 연관성이 극히 낮은 것으로 나타났다. 그러나 개별 호소에 대한 선형 회귀분석 일부 총인-엽록소가 강한 정 상관관계 (R$^2$=0.62, p=0.002, n=12)를 총질소-엽록소에서는 유의성이 없는 것으로 나타났다(p=0.892, n=12). 상기 연구를 종합해보면 경험적 모델 분석 시 자료의 평균효과(Averaging effect)는 모델의 변이성을 설명하는 데 중요한 것으로 나타났다.

• 생태와환경
• /
• 제41권spc호
• /
• pp.35-41
• /
• 2008

본 연구는 2006년 6월 22일부터 28일까지 식물성 플랑크톤의 1차 생산력을 알아보기 위하여 영양염 첨가 실험을 실시하였다. 평가를 위한 샘플은 저수지 중앙부에서 총 10L를 채수하였으며, Cubitainer에 각각 2.5L씩 분배하였다. 대조군은 원수를 그대로 사용하였으며, 처리군 1에는 $KH_2PO_4$을 첨가하였고, 처리군 2에는 2배 더 많은 $KH_2PO_4$을 첨가하여 각각 P, 2P가 되도록 하였다. 또한 처리군 3에는 $KNO_3$를 첨가하여 $NO_3-N$가 되도록 하였으며, 처리군 4에는 $KH_2PO_4$와 $KNO_3$을 첨가하여 $P+NO_3-N$가 되도록 하여 7일 동안 변화를 관찰하였다. P(T1)와 2P(T2)가 처리된 Cubitainer의 엽록소-${\alpha}$ 농도는 실험기간 동안 점점 감소하였고, 초기의 농도에 비하여 훨씬 낮은 수치를 보였다. 그러나, $NO_3$(T3)와 $P+NO_3$(T4)가 처리된 Cubitainer의 경우, 초기의 엽록소-${\alpha}$ 농도에 비하여 뚜렷하게 증가하는 것으로 나타났다. 단기 실험의 경우 질소가 일차적인 제한요인으로 작용한 것으로 사료되었다. 장기간에 걸친 TP, TN, TN: P mass ratios의 자료에 따르면, 인이 식물 플랑크톤의 성장에 제한요인으로 작용하였고, 채집된 시기와 장소에 따라 제한염류가 변하는 것으로 연구되어 졌다. 본 연구에서 질소는 1차 제한영양염류로 작용하였고 계절적인 영향에 의한 것으로 사료되었다.

• Journal of Chest Surgery
• /
• 제2권1호
• /
• pp.85-104
• /
• 1969

This experiment was carried out to study the effect of rapid hemorrhage on cardiopulmonary hemodynamics of the cooled dogs. Hypothermia was induced by means of body surface cooling with ice water. Lowest esophageal temperatures ranged from 24 to 26 degree. Dogs were bled via the femoral artery into a reservoir in amount of the equivalent blood volume of 3% of body weight of the dogs. Some dogs were reinfused with the same amount of blood which they lost and others infused with 5% dextrose solution. Fourty adult mongrel dogs were divided into three groups: group I[15 dogs]; dogs were bled in normothermic state. Five dogs had no further treatment, but five dogs were reinfused with blood and five infused with 5% dextrose solution 30 minutes after bleeding. GroupII[10 dogs]; dogs were bled as group I after having been cooled. Five dogs were reinfused with blood as group I. Group III[15 dogs]; dogs were first bled and then cooled. Reinfusion procedures were the same as in group l Results were as follow: 1. The heart rate showed a slight decrease after bleeding in group I and then increased over the control level after 60 minutes. After reinfusion and infusion, the heart rate was also increased gradually and after three hours almost returned to the control level. In group II and groupIll, the heart rate decreased remarkably and after reinfusion showed a light increase but after infusion tended to decrease cotinually. 2. The stroke volume showed remarkable decrease after bleeding in group I., and recovered to control level after reinfusion and infusion,and then gradually decreased again. In group III, the stroke volume showed no remarkable change after hypothermia, and tended to decrease after reinfusion. In group III, the stroke volume decreased remarkably after bleeding and hypothermia,and clearly increased after reinfusion and infusion and then returned to control level. 3. Femoral mean pressure declined very rapidly and significantly right after bleeding and showed a remarkable prompt rise after reinfusion and infusion in group I [67% recovery]. On the other hand, it declined remarkably after hypothermia and bleeding and showed a slight rise after reinfusion and infusion in group II[46% recovery] and III [41% recovery]. 4. Venous pressure declined slightly after bleeding and tended to return to the control level after reinfusion and infusion,in group I. In group II, it did not change significantly during hypothermia but showed a slight decline after bleeding and returned toward control level after reinfusion. In group III, it declined slightly after bleeding and showed no significant change after hypothermia and rose over the control level after reinfusion and infusion. 5. Right ventricular systolic pressure decreased markedly after bleeding and then increased progressively after 30 minutes. It increased after reinfusion and infusion as well, approaching the control level in group I. In group II, it showed no significant change during hypothermia, but decreased remarkably after bleeding and then returned to near control level after reinfusion. In group III, it was decreased markedly after bleeding but did not change significantly during hypothermia and showed a slight increase after reinfusion. 6. The respiratory rate increased gradually after bleeding and decreased gradually after reinfusion but did not return to the control level, whereas it decreased near to the control level after infusion,and tended to increase in group I. In group II, it decreased significantly after hypothermia and bleeding but returned near to the control level after reinfusion. In group III, it showed a remarkable decrease after hypothermia and increased slightly after reinfusion and infusion but did not returned to the control level. In group I, the tidal volume decreased slightly after hemorrhage, and increased gradually to near the control level after 3 hours following reinfusion.