The integrated culture of seaweed, abalone, fish and clams in modular intensive land-based systems: II. Performance and nitrogen partitioning within an abalone (Haliotis tuberculata) and macroalgae culture system

Amir Neori, Norman L.c. Ragg, Muki Shpigel

Research output: Contribution to journalArticlepeer-review

Abstract

A pilot-scale system for the intensive land-based culture of abalone was established using an integrated design aimed at eliminating the dependence on external food sources, whilst reducing water requirements and nutrient discharge levels. The system was the first and simplest trial in a series of progressive complexity of the concept of integrated culture of seaweed, abalone, fish and clams in modular and intensive land-based facilities. Relative sizes of the modules, their stocking densities and the rate of nutrient supply were determined based on earlier results to be optimal. Effluents from two abalone (Haliotis tuberculata) culture tanks drained into macroalgae (Ulva lactuca or Gracilaria conferta culture and biofilter tanks, where nitrogenous waste products contributed to the nutrition of the algae; net algal production from each algal tank was harvested and used to provide a mixed diet for the abalone. Excess algal yield was used elsewhere. The system was monitored to assess productivity and nitrogen partitioning over a year, while improvements were made based on the accumulating results. Total annual N-budgets were combined with mean production figures to determine a suitable ratio of abalone biomass to algal culture vessel productivity, towards commercial application of the concept. The abalone grew on average 0.26% and 0.25% body weight/d in the two culture tanks; reduced growth and increased food conversion ratios (food eaten/biomass gain; w/w) were associated with high summer water temperatures (max. 26.9°C). U. lactuca showed reliable growth and filtration performance (mean production of 230 g fresh weight/m2/d, removing on average 58% of nitrogen supplied). Conversely, G. conferta growth was highly erratic and was deemed unsuitable for the current application. It is estimated that 1 kg of abalone biomass would require food supplied by 0.3 m2 of U. lactuca culture, reducing N inputs required by 20% and N in effluent by 34% when compared to the two organisms grown in monoculture.

Original languageEnglish
Pages (from-to)215-239
Number of pages25
JournalAquacultural Engineering
Volume17
Issue number4
DOIs
StatePublished - Jun 1998
Externally publishedYes

Bibliographical note

Funding Information:
The authors would like to offer special thanks to A. Marshall for valuable observations as system manager; our gratitude also to D. Ben-Ezra, R. Fridman and B. Simpson for their expert technical advice and assistance, to O. Dvir and I. Lupatsch who performed the chemical analyses, and to A. Colorni and R. Goldberg for critical reviews of the manuscript. The project was supported by the Israeli Ministry for Energy and Infrastructure and by a joint program of the EC and the Israeli Ministry for Science (Grant No. 4564192 to M.S. and A.N.).

ASJC Scopus subject areas

  • Aquatic Science

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