Presentation on theme: "ECOSOC 2010 Substantive Session Opportunities for Small Island Developing States Tuesday 20 th 2010 Professor Anthony Clayton University of the West Indies."— Presentation transcript:
ECOSOC 2010 Substantive Session Opportunities for Small Island Developing States Tuesday 20 th 2010 Professor Anthony Clayton University of the West Indies
The usual SIDS presentation: start with a list of depressing problems: û Physically small and/or small population. û Small domestic markets, no economies of scale. û Remoteness, high transport costs. û Resource constraints (water, fuel, waste disposal sites, food security). û Relatively little influence in world affairs. û Exposed to extreme natural events; hurricanes, earthquakes, volcanoes etc. û Population and infrastructure mostly on the coast; vulnerable to sea level rise. û Difficult to build and retain human capital (technical and managerial skills). Step 1: Stop looking in the wrong place Then conclude with the usual request for failed solutions: More aid Continuing Special and Differential Treatment
Jamaica was the worlds largest sugar producer in the period 17 th - early 19 th centuries. Today, Jamaicas share of world production is just 0.1%, the tonnage of sugar slumped from 514,450 tonnes in 1965 to 124,206 in 2005, the contribution to export earnings has fallen from 49% in 1952 to 1.8% in 2006, the contribution to GDP has fallen from 9% in 1953 to 0.8% in 2006. It became uncompetitive, in part because it was protected from competition by EU trade preferences, so was profoundly threatened by phasing-out of trade preferences. The industry still occupies 53,294ha (of which 46,000ha producing, for quota) = 30% of agricultural land in Jamaica; 41% of permanent crop land. We had to develop alternatives. Case study: land use in Jamaica
Including: Intensive, high-value agriculture, including high- value plant extracts such as oleoresins and flavonoids for export to nutraceuticals and functional foods markets. 3 rd generation biofuels. Recommendation: optimize land-use
Nutraceuticals and functional foods Nutraceuticals/functional foods: actives and micro-nutrients, mostly plant extracts, used to reduce the impact of age- related degenerative disease. The actives concerned can be given in medical formats (nutraceuticals) or used as food additives in standard food products (functional foods) as a cost-effective way of raising the health status and average life expectancy of a population. This is not the same as traditional herbalism; the new industry uses measured doses of the desired actives, traditional herbalism uses materials with little processing which contain unknown quantities of both desirable and undesirable actives. Requires ability to extract, maintain high purity. Later stages involve e.g. microencapsulation.
The functional foods market Sales of functional foods in western Europe grew by 10.2% a year between 2004 and 2007. In America, sales of functional foods grew by 15.8% a year between 2002 and 2007, compared with overall food-sales growth of 2.9% a year. PricewaterhouseCoopers predicts that the global market for functional foods will grow in value from $78 billion in 2007 to $128 billion in 2013. Oct 29th 2009
Possible high-value extracts Ginger contains flavonoids that have anti-inflammatory, vascular stabilizing and anti-platelet effects. They can be used in the treatment of rheumatoid and osteo-arthritis, and they are likely to be cardio- and stroke protective. Turmeric contains flavonoids that are anti-inflammatory, and also block tumor necrosis factor alpha. They are likely to find a use in the treatment of arthritis, asthma and ulcerative colitis, and their properties also indicate that they will be cardio- and stroke protective. Jamaica has 348 plants with actives in Jamaica, 45 of which are endemic.
Biofuels G 1: cane/corn derived ethanol. Energy balance ratio for corn = 1.3/1, sugar = 8/1. G 2: cellulosic ethanol. EBR for cellulose = 12/1 to 16/1 But – G1 and G2 biofuels cannot solve our energy problems; if the US converted all its available biomass into ethanol, it could only displace 30% of its current gasoline demand. G 3: Algae can produce 10-20,000 gallons of fuel per acre per year, so 85 billion gallons (sufficient for all US transport) could be produced on 15,000 square miles (4.5 million acres), about the size of the State of Maryland. The US farms 938 million acres; fuel would take 0.47%. G 4: Synthetic biology/genomics: turn organisms into bioreactors to make fuel.
Recent projections Trials suggest that GM algae can produce long-chain hydrocarbons which can be refined into synthetic high- octane gasoline. This is compatible with refineries, filling stations and cars, does not have contaminants such as sulphur, nitrogen and benzene, will have higher energy density and offer more complete combustion than gasoline and diesel. Process uses non-arable land, non-potable water, delivers 10-100 times more energy per acre than cropland biofuels. GM algae may grow faster (* 2 mass in 1 hour), fix nitrogen and CO² from air. Production costs are still high; cost-effective algae-based biofuels by 2012-2015, replacing gasoline by 2020.
UK announces world's largest algal biofuel project The UK wants algal biofuels to make a significant contribution by 2020, and has made an initial investment of £26m to allow scientists to develop better strains. At present, it is possible to make algae with a high oil content, or algae that grows quickly. The goal is to combine these qualities. Research will also develop the optimal designs for culture and production. Plants will then be scaled up. Most of the UKs investment will be located in countries with year- round sunshine to maximize production. Thursday October 23 2008
Industrial biotechnology Biological feedstock used to manufacture chemicals, plastics and fuels, displacing petrochemicals. Current research includes replacing petrochemical-based polyester, epoxy and vinyl ester resins and composites with resins and composites manufactured from soya or corn oil; these give equivalent strength for about 25% of the weight. Current research includes replacing petrochemical-based polyester, epoxy and vinyl ester resins and composites with resins and composites manufactured from soya or corn oil; these give equivalent strength for about 25% of the weight. It may eventually be possible to produce aircraft, cars etc from eco- composites; carbon or natural fibres in a matrix derived from plant starches or resins. It may eventually be possible to produce aircraft, cars etc from eco- composites; carbon or natural fibres in a matrix derived from plant starches or resins. These eco-composites offer completely new prospects for agriculture, especially in tropical regions, as fibres, oils and resins become next- generation industrial crops. These eco-composites offer completely new prospects for agriculture, especially in tropical regions, as fibres, oils and resins become next- generation industrial crops. Current projections are that global biotechnology industry revenues will grow from $170bn in 2008 to $660bn by 2020. Developing countries (e.g. Brazil, China) emerging as major sources and markets. e.g. Brazil experimenting with producing polypropylene from sugar cane. SIDS could transform their cost structure and development prospects by reducing dependence on imported fuel, chemicals etc.
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