NEW METHOD in the field of Miscanthus propagation for ethanol and power production „low-cost bio-ethanol production”
Global challenges Economic: Decreasing energy and hydrocarbon resources Energy sources become more and more expensive Environmental: Speed-up of global warming and influences of it Political: Demand of decreasing the dependence of import energy resources Declaration of „Green-revolution”
Change of approach and construction in the energy industry Obligation of using renewable resources (EU, USA) Obligation of decreasing the emission (Kyoto) Support of CO 2 binding technologies New global business possibilities are opening Hydrocarbon age will be replaced by alcohol age (G. Olah, 1994 Nobel Laureate in Chemistry)
One of the most important range of producing renewable energy is growing and usage of biomass plants Among the biomass plants in temperate climates the Miscanthus giganteus plant seems to be the most efficient energy-binding one
Why Miscanthus ? High volume of biomass yields – t/ha/y ear (DM) Growth during years after planting Low annual growing costs – No soil cultivation after 2 years – After producing N 2 -fixing plants, low/no N-fertilizer cost Cheap, large volume of grown biomass resource Suitable for energetic purposes in wide range €/ha support in the EU For ethanol production is three times more efficient than corn
Energetic usage of Miscanthus 1. Supplying the energy demands of heating (90-95%) and electric (25-35%) power stations with direct burning. „Boiler-friendly”, low mineral-content, melting point of ashes is high: No usage problem, high heating value Demand of a 50 MW power station is : t ha Miscanthus 2. Cheap biomass fit – cheap ethanol raw material 6 t ethanol can be produced from 1 ha - with 20 t/ha yield 2-3 t ethanol can be produced from corn, grown on one ha (only to compare) 3. Great volume of raw material of gas production Usable for communal (domestic, waste water treatment) and industrial (cement production) end-users as well
Miscanthus It is usable – efficient biomass production Annual 1 m 3 gas-equivalent is grown on 1 m 2 area (means m 3 /ha/year), for the price of 1/5 - 1/8 gas price Production technology is well known, can be grown widely (EU, USA) 1 ha plantation binds 700 t CO 2 within 20 years One of the biggest global end-user of Miscanthus biomass will be the fuel industry, probably with plants supplying public traffic
Bioethanol - Miscanthus Bioethanol market – global E85 = fuel with 85 % !! ethanol content Cellulose – ethanol technologies are already cheaper than that of based on corn (under 0,3 $ / l) Price of the raw material is 1/5-1/10 of that of corn On the same area 2-4-times more ethanol can be produced from Miscanthus, than from corn The electric and heat demand of production can be supplied cheapest from Miscanthus as energy source Who drops out, drops behind !! 2006 Shell-Volkswagen Miscanthus- ethanol project 2007 B.P. – 500 M $ - Miscanthus – ethanol project
For 300 Million tons/year ethanol production 50 Million ha Miscanthus plantation is needed /50 M ha = 35 Md t CO 2 reduced emission !!!!/ The main limits of planting are the following (EU,USA): 1.High price of planting material – high plantation cost State support: England 930£/ha, Hungary 1000 €/ha Support demand of 50 M ha - 50 Md. € (have no so much) There is not enough propagules (planting material) For 50 M. ha: 500 Md. propagules are needed! Development of propagule-production is required!!! The solution of the problem is the development of the propagation methods as following:
Well known technologies and new method. Miscanthus giganteus is to be propagated only with clonal multiplication 1.Using Rhizomes (under-ground propagation part) 3 years (1 ha) plant can produce 20 ha There are ha given all over the world, that is a limitation of development !! 2.Micropropogation – biotechnological method Theoretical unlimited propagation is possible, but with incredible high investment, energy and salery costs, it results high set price.
3.New technology: with activated stems and cuttings Propagules production utilizing plants of existing ( ha) plantations with activation of buds From 1 ha in every year ha new plantation can be produced, with plants are able to fix nitrogen. 4. Set / propagule prices by technologies: Taking pcs/ha into consideration, plantation costs of 50 Million ha by technologies: Technology price plantation cost 1.Rhizome: ≈ 0,3 $/pc150 Md $ / 50 M ha 2.Micropropagation: ≈0,4 $/pc 200 Md $/ 50 M ha 3.New method (prod. cost) ≈0,07 $/pc 35 Md $/ 50 M ha (Md =10E9 /Billion/, M=10E6, $= USD)
5. Next let us investigate, what kind of influences and results can be provided by the production of raw material technologies in event of a presumed replacement of mineral oil by ethanol, and what kind of development directions can be signed for the users: When will be given enough raw material for 300 Million t ethanol production? with Rhizome propagation: from with Micropropogation: from2014 with new method: from2012 N-fertilizer demand of 50 M. ha plantation for 20 years : with Rhizome propagation: M t with micropropagation: M t New (nitrogen-fixing plants) M t
Summary: Further to the analyses, the plantation and financing of Miscanthus farms can be provided with more advantages and economic conditions by the new method, than with the known other technologies, which can be supported by the favourable influence on the environment of the nitrogen-fixing plants.
Pictures Activated the stems of Miscanthus Treatment in January 2008 Treatments in Plant growth promoting effect of nitrogen fixing bacteria living within the plants
Activation Non - Activated stems Activated stems
Activation Non - Activated Cuttings (2008) Activated Cuttings (2008)
Symbioses with nitrogen-fixing and plant growth-promoting bacteria Non-treated and treated plants and the bacteria within the plant
Miscanthus yields In Europe In Illinois t/ha/year t/ha/year Illinois farm management budgets suggest much higher net margins from Miscanthus than from corn and soya bean rotations.
Presentation Developed and made by Szilard Sandor VARGA, PhD