초록
거제${\cdot}$한산만 양식굴 Crassostrea gigas의 에너지 전환 효율을 추정하기 위하여 한 양성 기간인 1979년 7월부터 1980년 4일까지 성장도, 생식 물질 방출량, 패자 형성량, 호흡량, 집단 감모율에 대한 현지 생체 실측 조사를 행하였으며, 연체부의 물질 조성 및 에너지 함량, 패각의 유기 물질 및 생식 물질의 에너지 함량을 각각 측정하고, 호흡량에서 호흡 열량 계수를 사용하여 이화 에너지양을 계산하였다. 이상의 자료에서 동화 에너지양에 대한 연체부 에너지양의 비율로 순 에너지 전환 효율을 계산하고 동화 효율을 측정하여 섭취 에너지양에 대한 연체부 에너지양의 비율로 총 에너지 전환 효율을 계산하였으며, 그 결과는 다음과 같다. 1. 각고(SH) 및 연체부 건조 중량 (DW)의 반월령(t)에 따른 성장도; $$SH=6.33(1-e^{-0.2421(t+0.54)}),\;(0<\leqq10)$$ $$SH=4.44+0.14t,\;(10{\leqq}t{\leqq}20)$$ $$DW=0.608(1-e^{-0.2421(t+0.54)2.589}),\;(0 $$DW=1.53\times10^{-6}\times(4.44+0.14t)^{7.2},(10{\leqq}t{\leqq}20)$$ 2. 생식물질 방출량(G): $$G=0.0145+(3.95\times10^{-3}{\times}SH^{2.9861}$$ 3. 패각 형성량(SO); $$SO=0.000648{\times}SH^{2.527}$$ 4. 호흡량(R); $$log\;R=(0.0386T-0.5381)+(0.6409-0.0083T){\cdot}log\;DW$$ 5. 연체부 에너지 함량; 3.93(7월)-4.54(4월) Kcal/g, DW(질소 보정에 의한 계산값) 6. 생식 물질의 에너지 함량$(E_G)$: $$E_G,\;Kcal=\frac{1}{4}[0.0149SH^{2.961}+0.0547]$$ 7. 패각 유기물의 에너지 함량$(E_{so})$; $$E_{so},\;Kcal=0.00184SH^{2.527}$$ 8. 호흡 에너지 계수: 3.18(8월)-3.31(4월) cal/mg $O_2$ 9. 집단 총 감모율 : $36\%$ 10. 동화 효율 : $55.5\%(40\~70\%)$ 11. 순 에너지 전환 효율 : $28\%$ 12. 총 에너지 전환효율 : $15.28\%(11\~20\%)$.
The efficiency of energy transfer by a population of the farmed pacific oyster, Crassostrea gigas was studied during culture period of 10 months July 1979-April 1980, in Geoje-Hansan Bay near Chungmu City. Energy use by the farmed oyster population was calculated from estimates of half-a-month unit age specific natural mortality rate and data on growth, gonad output, shell organic matter production and respiration. Total mortality during the culture period was estimated approximate $36\%$ from data on survivor individual number per cluster. Growth may be dual consisted of a curved line during the first half culture period (July-November) and a linear line in the later half period (December-April). The first half growth was approximated by the von Bertalanffy growth model; shell height, $SH=6.33\;(1-e^{0.2421(t+0.54)})$, where t is age in half-a-month unit. In the later half growth period shell height was related to t by SH=4.44+0.14t. Dry meat weight (DW) was related to shell height by log $DW=-2.2907+2.589{\cdot}log\;SH,\;(2, and/or log $DW=-5.8153+7.208{\cdot}log\;SH,\;(5. Size specific gonad output (G) as calculated by condition index of before and after the spawning season, was related to shell height by $G=0.0145+(3.95\times10^{-3}{\times}SH^{2.9861})$. Shell organic matter production (SO) was related to shell height by log $SO=-3.1884+2.527{\cdot}1og\;SH$. Size and temperature specific respiration rate (R) as determined in biotron system with controlled temperature, was related to dry meat weight and temperature (T) by log $R=(0.386T-0.5381)+(0.6409-0.0083T){\cdot}log\;DW$. The energy used in metabolism was calculated from size, temperature specific respiration and data on body composition. The calorie contents of oyster meat were estimated by bomb calorimetry based on nitrogen correction. The assimilation efficiency of the oyster estimated directly by a insoluble crude silicate method gave $55.5\%$. From the information presently available by other workers, the assimilation efficiency ranges between $40\%\;and\;70\%$. Twenty seven point four percent of the filtered food material expressed by energy value for oyster population was estimated to have been rejected as pseudofaeces : $17.2\%$ was passed as faeces; $35.04\%$ was respired and lost as heat; $0.38\%$ was bounded up in shell organics; $2.74\%$ was released as gonad output, $2.06\%$ was fell as meat reducing by mortality. The remaining $15.28\%$ was used as meat production. The net efficiency of energy transfer from assimilation to meat production (yield/assimilation) of a farm population of the oyster was estimated to be $28\%$ during culture period July 1979-April 1980. The gross efficiency of energy transfer from ingestion to meat production (yield/food filtered) is probably between $11\%\;and\;20\%$.