Digital library

  • Kelp farming in Alaska traces roots to hatcheries

    Alaska’s burgeoning kelp farming industry has its success tied to two hatcheries and a law. Blue Evolution is working under a collaborative research and development agreement with NOAA to use the Kodiak Fisheries Research Center hatchery to grow the kelp seed that the company will supply to growers on partner farms.

    “NOAA provides a space (no lease), and we capitalize the equipment,” says CEO Beau Perry. “And we work with them on various research threads.” Much of the east coast oyster industry technology was developed under this type of agreement with the NOAA facility in Connecticut in the early 1970s, Perry points out.

    “Currently, there are many nascent aquaculture business across the country working with NOAA in this way,” he adds. The hatchery uses a recirculating system, and is able to utilize unused cold rooms at the facility, as opposed to water chillers. Perry estimates it has nearly 100 tanks, with capacity for several thousand spools and hundreds of thousands of feet of seeded string.

    “We will certainly be pushing up against capacity as we are lowering the density of spools and tanks per cold room this season,” he explains. “But we can expand further using auxiliary space in the future.”

    Author(s): Tom Walker

  • Kelp Farming Good harvesting

    PDF of pictures that shows good harvesting on a kelp farm.

    Author(s): Jiaxin Chen

  • Kelp farming gains traction in Alaska

    The recent expansion of kelp farming in Alaska has Julie Decker, chair of the Alaska Mariculture Task Force, excited.

     

    “The 2018 Alaska Mariculture Development Plan aims to grow the mariculture industry in Alaska by $100 million in the next 20 years,” Decker explains. “The new applications we have seen from kelp farmers over the last two years are pretty exciting.”

     

    Wild fish capture is still king in Alaska, where growing finfish is illegal. That leaves mariculture, the farming of all other aquatic species, to balance the highly seasonal work of ocean fishing. Oysters are the top cultured species in the state. But the industry for sugar kelp (saccharina) and ribbon kelp (alaria) is expanding.

    Author(s): Tom Walker

  • Kelp cultivation effectively improves water quality and regulates phytoplankton community in a turbid, highly eutrophic bay

    Coastal eutrophication and its associated harmful algal blooms have emerged as one of the most severe environmental problems worldwide. Seaweed cultivation has been widely encouraged to control eutrophication and algal blooms. Among them, cultivated kelp (Saccharina japonica) dominates primarily by production and area. However, the responses of water quality and phytoplankton community to kelp farming remain unclear. Here, thirteen cruises were conducted in the kelp farms and control areas in the turbid, highly eutrophic Xiangshan Bay of the East China Sea from 2008 to 2015. Results indicated that kelp cultivation slightly increased dissolved oxygen and pH, but reduced dissolved inorganic nitrogen and phosphorus. We estimated that kelp harvesting would remove 297 t of nitrogen and 42 t of phosphorus from this bay annually. Because of decreased flow velocity, turbulence, and sediment resuspension, kelp farming greatly reduced suspended solids and increased transparency, resulting in increases in phytoplankton chlorophyll a and abundance. Additionally, kelp farming appreciably increased phytoplankton species number, Marglef richness, and Shannon–Wiener diversity indices by 51.6%, 40.1%, and 13.1%, respectively. Analysis of similarity and similarity percentages demonstrated that phytoplankton community composition differed significantly between the farm and control area, which was mostly attributed to long-chained diatoms and single-celled dinoflagellates. However, after the kelp harvesting, all measurements of water quality and phytoplankton biomass, diversity, and community composition exhibited no significant difference. Our study highlights that kelp cultivation alleviates eutrophication and acidification and enhances phytoplankton diversity, thus providing guidance for macroalgal aquaculture and remediation in eutrophic waters.

    Author(s): Zhibing Jiang, Jingjing Liu, Shanglu Li, Yue Chen, Ping Du, Yuanli Zhu, Yibo Liao, Quanzhen Chen, Lu Shou, Xiaojun Yan, Jiangning Zeng, Jianfang Chen

  • Kelp Biomass Production Yield, Genetics and Planting Technology - Annual Report 1985

    Progress has been made toward the long-term goal of growing macroalgae in the sea as a future source of substitute natural gas. This annual report discusses progress made to: 1) measure macroalgal yield, 2) enhance yield by row planting and selective harvesting, 3) genetically breed high-producing plants, 4) devise methods for planting kelps and 5) maintain and extend collaborative research efforts and communication with scientists working on macroalgal biomass production in Japan, China and elsewhere. The report discusses kelp biology and macroalgal mariculture in general terms, the theories that have been proposed and the existing data base in the scientific literature. Particular attention is given to new techniques used to make in-the-sea hydrodynamic and light-climate measurements and rnicrospectrophotometric measurements of DNA levels in kelp sporophytes and gametophytes. New and effective tank, dish and in-the-sea planting and culture methods have been successfully employed in a co-funded program to establish a new kelp bed. Other co-funded work in genetics and marine farm engineering is mentioned in the report. A list of ten publications resulting from this work is included. The report suggests that in the distant future, the 1,000 acre natural kelp forest, recently leased to NMI by the State of California, could be used along with on-shore facilities provided by Southern California Gas Company, for pilot-scale demonstration project. 

    Author(s): B. W. W. Harger, M. Neushul

  • Kelp associated floral epiphytes - Productivity and community structure in relation to wave exposure and season

    This study was conducted as part of a kelp forest project which aim is to acquire knowledge about biodiversity and productivity in kelp forest areas. The epiphytic algae associated with the stipe of Laminaria hyperborea (Gunnerus) Foslie are important as habitat and food source for numerous faunal species along the Norwegian coastline. My investigations were performed on samples taken from kelp stipes in the area of Finnøy, Norway, in April, June, September and November 2005. I address questions of how the epiphytic community structure and primary production relates to a gradient of wave exposure, and the seasonal aspects of these relationships were also brought into the analyses. Both univariate and multivariate statistical methods were used in this approach. The amount of biomass found on a stipe was first of all related to the length of the stipe, and stipe lengths increased with increasing levels of wave exposure. A definite peak in total biomass was found in September. The species composition of epiphytes on the kelp stipes showed variation with increasing exposure. However, the variation within sites with the same index of exposure was also very high, suggesting that differences on a smaller scale may be of great importance. Differences in the species composition between sampling periods were also found. I conclude that both epiphyte species composition and productivity in kelp forest areas are affected by wave exposure, or some factors related to wave exposure, and that the structures of these epiphytic communities change through the season.

    Author(s): Guri Sogn Andersen

  • KELP AND CARBON SEQUESTRATION: EXPORTING TERRESTRIAL GHG ACCOUNTING TO THE DEEP SEA

    Recent breakthroughs have elevated algae as a promising biological solution to environmental challenges. Particular species of algae can provide low-impact, non-fossil substitutes for liquid fuel and plastics and can decrease enteric fermentation emissions from cattle. Now, a recent Nature Geoscience paper quantifies the role of kelp and other macroalgae in the global carbon cycle. The peculiarities of seaweed carbon cycling may skirt “permanence” issues that have plagued other biological carbon sinks, such as terrestrial forests. Future research may enable business and government to recruit kelp forest rehabilitation as an additional approach to climate change mitigation.

    Author(s): PATRICK CAGE

  • Karyology and sex determination in Aglaothamnion oosumiense Itono (Ceramiaceae, Rhodophyta)

    A cytogenetic investigation on male and female reproductive cells of Aglaothamnion oosumiense Itono indicates that the sexuality of this species might be determined by a sex chromosome. Chromosome counts in female and male gametophytes gave 37 and 36, respectively. Sex ratio of gametophytes was 1:1. Both male-derived and female-derived bisexual plants were observed. Bisexual plants were different in gross morphology and position of carpogonial branches from normal unisexual gametophytes. The chromosome number of female-derived bisexual plants was N=37 and male-derived bisexual plants was N=36. Some male plants developed parasporangia in addition. The paraspore germlings showed the same chromosome number as the male plants. The fertilized carpogonium and gonimoblast cells had 2N = ca. 70 chromosomes.

    Author(s): Gwang Roon Kim, In Kyu Lee, Ok-Kyong Chah

  • Kappaphycus Seaweed in the Pacific: Review of introductions and field testing proposed quarantine protocols

    The secretariat of the Pacific Community (SPC) commissioned the Institute of Marine Resources (IMR) of The University of the South Pacific to: 1) conduct a literature review of the introductions of the seaweed Kappaphycus alvarezii to Pacific Islands Countries and the current state of seaweed farming in these countries and 2) to field-test their proposed quarantine protocol for introducing K. alvarezii to new locations. 

    Author(s): Reuben Sulu, Lynette Kumar, Cameron Hay, Timothy Pickering

  • Kappaphycus alvarezii macroalgae: An unexplored and valuable biomass for green biorefinery conversion

    Background: Kappaphycus alvarezii is the 5th worlds most cultivated macroalgae, since it is an essential source of carrageenan, widely used in food industry. However, K. alvarezii is an unexplored biomass for green biorefinery conversion, since its composition includes valuable proteins, lipids, phenolic compounds, among others. Although there are reviews on K. Alvarezii cultivation and pharmacological properties, no information is available regarding extraction techniques applied to this algae biomass. Therefore, this review covers the lack of information on biorefinery concept applied to K. alvarezii and suggest sequential extractions to recover carra- geenan and high-added value molecules by using non-conventional methods.

    Scope and approach: This critical review presents the most recent data on K. alvarezii, including its scientific trends, production and potential. It also deals with non-traditional methods for sequential extractions applied to K. alvarezii. The search for available data was extended to the group of red algae to consider the concept of biorefinery.

    Key findings and conclusions: K. alvarezii biomass can be used to obtain chlorophyll, β-carotene, essential amino acids (aspartic acid, glutamic acid and phenylalanine) and phytohormones (indole acetic acid, zeatin, kinetin and gibberellic acid). Therefore, we provide several sustainable insights to sequentially recovery carrageenan and other bioactive compounds from K. alvarezii.

    Author(s): Adenilson Renato Rudke, Cristiano Jose de Andrade, Sandra Regina Salvador Ferreira

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