Sawah Technology (4PPt)Practices : Irrigated sawah system development and sawah based rice farming by farmers' self- support efforts June 99, JICA Sawah project Aug 00 Aug 2009 Farmers sawah technology will prepare the platform for the green revolution technologies Sokwae, Ghana. The center is a leading farmer and his both sides are Sawah staffs at Crops research Institute, Ghana. 3ha of irrigated sawah was developed within 3 months. Total sawah became 6ha by November 2011 Upper: May 1999, Biemso No1, Ghana, Lower: August 2000, the same site above. During the year in 1999-20, 2 ha sawah development claimed 2seasons in 2 years. The irrigated sawah area expanded to 10 ha by 2009 Jan 2010
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Sawah Technology (4PPt)Practices : Irrigated sawah system development and sawah based rice farming by farmers' self-
support effortsJune 99, JICA Sawah project
Aug 00
Aug 2009
Farmers sawah technology will prepare the platform for the green revolution technologies
Sokwae, Ghana. The center is a leading farmer and his both sides are Sawah staffs at Crops research Institute, Ghana. 3ha of irrigated sawah was developed within 3 months. Total sawah became 6ha by November 2011
Upper: May 1999, Biemso No1, Ghana, Lower: August 2000, the same site above. During the year in 1999-20, 2 ha sawah development claimed 2seasons in 2 years. The irrigated sawah area expanded to 10 ha by 2009
Jan 2010
ClassificationArea
(million ha)Area for potential irrigated
sawah developmentCoastal swamps 17 4-9 million ha (25-50%)Inland basins(deltas) 108 5-20 million ha ( 5-20%)Flood plains 30 8-23 million ha (25-75%)Inland valleys 85 9-21 million ha (10-25%)
Note 1. Although initial priority was small inland valleys because of easier watercontrol, flood plains and inland basins (delta) in Sudan and Guinea Savanna zones should be given priority, such as Kebbi, Jigawa, and Borno in Nigeria and Chad, where wide distribution of shallow ground water (Gleeson et al. 2012, Fan et al. 2013) makes small pump irrigated sawah efficient and soil fertility is high.
Note 2. Estimated potential sawah area and paddy production are 0.5-1 million ha and 2-4 million tons of paddy in Ghana, 3-5 million ha and 12-20 million tons in Nigeria, and 26-73 million ha and 104-292 million tons in SSA. Estimations in Table 1 can be supported by following data, i.e. Asia has 140million ha of potential (94 million ha of sawah rice harvest in 2013) with 9485 km3 of available water, whereas SSA has 3617 km3 of water availability (40% of Asia) gives 56 million ha potential harvest area (only 2 million ha sawah rice harvest in 2013) (Oki et al 2009, AQUASTAT 2016, FAOSTAT 2016)
Table 1. Distribution of wetlands and potential irrigated sawah area in Sub Saharan Africa (SSA) (Andriesse 1985, Windmeijer &Andriesse 1993, Potential Sawah area estimate by Wakatsuki 2002 and 2015)
Fig.1 Area Equipped for Irrigation and Potntal of SSA(Aquastat 2016) Million ha
Having with 9485 km3 of annual available water, Asia has 216 million ha equipped for irrigation, 94 million ha for irrigated rice harvest in 2013. Its potential area is 322 and 140million ha respectively. Since SSA has 3617 km-3, 40% of Asia (Oki et al 2009), its potential irrigated area and potential irrigated rice harvest will be 129 million ha and 56million ha respectively. Sawah based rice harvest was only 2million ha in 2013
If SSA can irrigate rice similar to Asia, total potential irrigated rice harveset area will be 56million ha annually
Chad basin, the largest wetland in Africa (35 million ha,
290m altitude)
Although only large scale wetlands, such as flood plains and inland as well as coastal basins (deltas) are appeared in this map, there are numerous small inland swamps and valleys in all agro-ecological zones of Sub Saharan Africa.
Inland delta at Mali (8 million ha,
270m altitude)
Nile Delta in desert climate (3 million ha)
Highland Africa
LowerAfrica
Various wetlands
in Nigeria
Fig. 2.
Sudd basin of South Sudan (15 million ha,
450m altitude)
Congo basin(25 million ha,
400m altitude)Okavango and other deltas (25 million ha,
1000m altitude)
Fig. 2. Distribution of flat wetland soils in Africa (Van Dam and Van Diepen 1982)
SpringSurface/groundwater
Flood prone
lowlands
RiverRiver
Sawah
Floodplain 0~
1000m
Shallowground water
Coastal/Inlandswamp/delta
Sawah(ground water
re-charge)Upland
Waterharvestablelowland
Contour bund
Water table and
ground water
[W]
Spring irrigablesloped lowland
[S]Lowland
but upland ecology
[U]
Typical irrigable lowland
[L]
[F]
Flood plain and inland/coastal basins(deltas) are available during non-flooding period
Diverse irrigation options: Rainfed sawah, sawah to sawah/contour bund water harvesting, spring, dyke, river, pump and shallow tube well, peripheral canal,
*Even large flood plain and deltas, farmers can practice sawah based rice farming using small water pump and shallow tube wells, except for 2-3 months flood period. Since
flood water power of majority of African big rivers are not so destructive, sawah systems developed by farmers can survive under flooded water. Bunded sawah systems
can not only recharge ground water, but also contribute to trap eroded fertile topsoil particles in flood water to sustain fertility.
Flood prone
lowlands[F]
(ground water re-charge)
Sea/lake
[F]
[D]
Fig.3. Diverse wetlands/lowlands and targeted sites of sawah technology along topsequence of inland valley, flood plain, and costal/inland delta in SSA.
Fig. 4. Distribution of World Precipitation (The Times Comprehensive Atlas of the World, 12th edition 2007)
2000mm/year
2000mm/year
1500mm/year1000mm/year3000mm/year 4000mm/year
500mm/year
500mm/year
2000mm/year3000mm
Fig.5. Rate of soil erosion in the world (Walling1983)
Can watersheds of SSA sustain sawah system? High rate of soil erosion and lowland soil formation can be compensated by high rate of soil formation in Asia. However soil formation, soil erosion and hence lowland soil formation are appeared to low in comparison with Asian watersheds. This is because of many huge inland basins/deltas are trapping sediments, such as Mali, Chad, Sudd, Congo and Okavango (see Fig. 2)
Table 4. Extension of Sawah Rice Production Technology in Kebbi State during March 2011 to April 2014
2. Sawah Technology extension, April 2012-October 2013
Fig. 6. Sawah technology demonstration and dissemination sites during 2011-2015. ( Map by Zwart & Hamady, AfricaRice, http://ricetoday.irri.org/wp-content/uploads/2016/03/flood-prone-rice-areas-in-West-Africa_legend_big.jpg)
Sokoto and Rima river
ArugunguBirinin Kebbi
Jega
BagudoSuru Niger
river
Gandu (MGD) 20ha Sawah Farm
First Sawah demonstration site in 2011-2012. Powertiller training site on 10 July 2015 below
AR2
AR1
AR4
AR3
Soil and Landusesurvey points in
14th-16th December 1987(Oyediran
1990)
Kebbi Powertiller and sawah technology training on 10th of July 2015 at AR1 site
AR1 site in 1987
Fig. 7. Arugung in 1987 and 2015. Starting site of Kebbi rice revolution through sawah system evolution through sawah technology
AR1 site area in 1987 AR3 site area in 1987. Photo is young Dr. Oyediran
Fig. 8. Arugung in 1987. Starting site of Kebbi rice revolution through sawahsystem evolution through sawah etchnology. Position of AR1, AR2, and AR3 are
shown in Fig.8 of Google earth in 19th of October 2013Deep water rice in Rima river at Birinin Kebbi on 11th of December 1987, 30 years ago!
AR2 site area in 1987
Fig. 9. Micro Irrigated micro sawah rice and vegetable fields. Poor water use efficiency and weedy rice field before Sawah technology applied at Kebbi, Nigeria
AR3 site area in 2011
AR3 site area in 2011
Jega flood plain in 2011, before sawah ecotchnology
Sokoto flood plain in 2011, before sawah ecotchnology
Fig. 10. Demonstration & training of sawah technology(upper two are Jega on April,2011, lower left is AR1 in Fig. 7 at Arugungu, right is at Birinin Kebbi, on Sep 2011)
15 ha of sawah developed by Mr. AbdullahiMaigandu Arugungu
35 ha of sawah developed by Alh. Bello Baidu at Bagudo, Niger river floodplain
June2014
Fig. 11. Sawah development and evolution at Arugungu and Bagudo in Kebbirice revolution sites (Photographed locations are shown Fig. 6,7, 12 and 13)
10 Oct2013)
20m square (Maiduguri )
Before sawah improvement, paddy yield was 2-3 t/ha in micro sawah plots, at MaiGandu farm. Google earth 5Nov2009
20x20m square
Fig. 12a. Sawah evolution at MaiGando farm, Arugungu, Google Earth19Oct2013. Expanded sawah with improved bunding and leveling with powertiller puddling gave paddy yield 5-7 t/ha at the same sitebefore micro sawah plots, which also increase waste land area as shown below, thus lower yield, by higher unplanted bund area
Size of Sawah plotand of bund area
100x100m: 2% 50x50m 4%,25x25m 8%,
12.5x12.5m16% 6.3x6.3m 32%
3x3m 64%
Micro sawah plots on Jega flood plain, 22January2014, Google earth
Fig 12b. Further Sawah evolution and improvement (area expansion, bunding and leveling) is on-going since 2011. Tube well, shallower than 8m, and pump irrigation gave paddy yield, double to 6-7t/ha after sawahimprovement using power tillers
MaiganduFarm27June2016
Gandu(MGD) >20ha Sawah Farm
AR1
First Sawah demonstration site in 2011-2012. Powertiller training site on 10 July 2015 below
Gandu(MGD) >20ha Sawah Farm
AR1
First Sawahdemonstration site in 2011-2012. Powertillertraining site on 10 July 2015
Fig. 12c. Sawahdevelopment and evolution at AR1 site of Fig 7 on 27 June 2016
AR1
Fig. 13. Sawahdevelopment and evolution by Alh Bello Baidu farm at Bagudo are in progress
Annual rainfall
2000mm
Lower Africa
Higher Africa
500mm
2000mm
500mm1000mm
1000mm500mm
1000mm
AB
CD
ED
D
Fan, Y et al. 2013. Global patterns of groundwater table depth. Science, vol. 339, p. 940-943
Araki S. 2008. Data base for the world edition, Research group for Virtual Planet Earth (2008 )http://virtual-earth.asafas.kyoto-u.ac.jp/ve-world/datac.cgi
Fig.14. Distribution of inland basins in various altitudes with shallow groundwater for possible future application of sawah technology in Sub Saharan Africa
New sawahproject sites, 2015-16, for
returnees /refugees, Tissi& Haraze, Chad
350
250
150Altit
ude(
m) Mali inland basin, delta area (150-350m)
Shallow ground water <10m
270m
Transect A
850km
Estimated wetlands, 8 million ha
Altit
ude(
m)
Chad Inland basin, delta area (150-450m)
Shallow ground water <10m
Transect B
1550km
800700600500400300200100
0
Moderate ground
water 10~50m
Deep ground water >50m
Estimated wetlands, 35 million ha
290m
Fig 15. Topographical cross section of the transect lines of A and B in Fig. 14. The two basins have shallow groundwater good for pump irrigated sawah system
Altit
ude(
m)
Congo Inland basin, delta
Shallow ground water <10m1350km
700600500400300200100
0
400m
Estimated wetlands, 25 million ha
Altit
ude(
m) Sudd, inland delta
Shallow ground water <10m950km
1300120011001000900800700600500400300
White Nile450m
Estimated wetlands, 15 million haTotal wetlands of all Nile system, 30 million ha
Altit
ude(
m)
Okavango basins, deltas
Shallow ground water <10m
1000m
1000km
1300120011001000900800
Estimated wetlands,25 million ha
Transect C
Transect D
Transect E
Fig 16. Topographical cross section of the transect lines of C, D and E in Fig. 14. Congo and Sudd basins have shallow groundwater good for pump irrigated sawah
system. However, Okavango basins need careful environmental examinations
African Continent 3.04 billion ha
Asian Continent(4.46 billion ha)
Fig. 17. Frequency distribution of area in each altitude in African and Asian continent by Araki (2008). Africa is stable continent, thus has about 10 steps of flat peneplains of various altitudes between 200-1000m, such as C, D, E, F, and G, which have vast inland basins/wetlands/deltas, except for F (plateau) as see in Fig. 14. Whereas Asia has vast lowlands, mainly coastal areas, lower than 200m, A, which are major wetlands for sawah based rice cultivation in Asia.
B
AC
D
E A
F
G
Green areas show
potential irrigable
lowlands by USAID&IFP
RI, 2010500-2000mm
Annual Precipitation:1000mm
Annual precipitation: 500mm
Fig.13. Major lowlands distribution in Nigeria (USAID and IFPRI, 2010)
Nigerian side of Lake Chad area in May 2011. Rice and onion by Shallow tube well
Lake Maga 50,000 ha
Irrigated sawah 10,000ha
MagaDam lake
Lost of huge lowland
Increase evaporation water loss
Fig. 14 UplandStrategy forImprove waterCycling by
Lowland Sawah System Strategy for Water Cyclingenhance ground water recharge
Numerous Sawah plots developed and managed by farmers can enhance water dam function(Figure cited from Advance paddy field engineering, JSIDRE, 1999)
Rockström & Falkenmark(Nature 2015), which was cited from Molden (ed.) Water for Food, Water for Life (IWMI, 2007)
Left: Large scale irrigated sawah system at Mwea, Kenya, 5860ha potential 8000ha). Right: Small scale irrigated sawah at Tema, Accra, Ghana, 50ha (potential 100ha). Both sites have been received continuous huge ODA support since 1960. Both have problems in terms of cost-effectiveness, sustainable management, and endogenous development, Google earth, 2009 and 2010
Large scale irrigated sawahusing ODA, Mwea, Kenya
5860ha
Small scale irrigatedSawah using ODA
50ha, Ghana
Large-scale development
Small-scale development
Sawah technology Traditional system
Development cost ($/ha) 10000–30000 10000–30000 1000-3000 30–60
Project ownership Government Government Farmer FarmerAdaptation of
technology
Technology transfer
Long
Difficult
Medium to short
Difficult
Medium to short, needs intensive demonstration and on-the-job
training (OJT) programEasy
Short
Few technology transfer
Sustainable development
Management
Low(heavy machinery used by contractors in development)
Difficult
Low to medium
Difficult
High (farmer-based and small power-tiller used in development and
management)Easy
Medium
EasyAdverse
environmental effect
High Medium Low Medium
† Assuming 1 ton paddy is worth US$ 500; one power-tiller costs US $ 3000-4000 in West Africa depending on the brand quality and accessories (2015 values). Selling prices are $1500-$3000 for farmers in Asian countries.
Table 2: Comparison of farmers’ site-specific personal irrigated sawah system development and sawah based rice farming(Sawah technology) with large- and small-scale contractor (ODA) style developments, and traditional rice cultivation system in various lowlands of Nigeria and Ghana (2014).
15-15-15 15-15-1590-60-60 90-60-60
Padd
y Y
ield
(t h
a-1 )
Fertilizer (kg ha-1 N-P-K)
Poor Water Control Good Water Control
109876543210
Low Input High Input + Good Agronomic Practices
Investment,Management,Rehabilitation,Traininig, Corruption, andTime loss Cost
LaborCost
0
A type strategy: Upland NERICA technology B type strategy: Asian Green Revolution technology
C type strategy: System Rice Intensification D type strategy: Contractor based ODA irrigation/drainage development
E type strategy: Irrigation by private big business enterprisesS type strategy: Sawah technology with sustainable mechanization
Figure. Six Strategies to Increase Paddy Yield and Production in SSA
Irrigation Drainage Technology by Government
Sawah Technologyby farmers
Improved
Traditional
<Variety>
AB
C
D
S
S
Irrigated Farm Development by Big Business EnterprisesE
(1) To train qualified sawah farmers and or groups who could develop sawah >5ha and get annual paddy production >20ton using one powertiller within three years after the initiation of sawah development.
(2) To train the leading Sawah farmers is the key for sustainable and endogenous sawahdevelopment. The leading farmers can train farmers and farmers groups to achieve the target as qualified Sawah farmers.
(3) If site selection is suitable, sawah can be developed in Africa easier than Asia.
The successful example of Sawahecotechnology innovations:(1) Oasis type pump irrigation in floodplain (Sudan savanna zone, Kebbi state)(2) Spring based irrigation system (all climatic zones)(3) Overflow dykes on small rivers (Guinea savanna zone, forest transition zone, forest zone)
Sawahdevelopment:
at least 10ha by one Power-tiller
Sawah technology can reform ODA and contractor based development : Endogenous development will be, farmers to farmers > > extension officers > researchers >> ODA style technology transfer
Table 3. Four Skills of Sawah Technology for Farmers Personnel Irrigated SawahSystems Development and Rice Farming to Realize Green Revolution in SSA
New Sawah development in Biemso No.1 byFarmer to farmer with SRI backstopping
Sokwae Sawah development by CRI sawah team, June 2008
SMART
Sawah ecotechnology training of SMART-Africa Rice staffs as well as Togo and Benin extension officers at Kumasi,November 2011
ADEMILUYI, YINKA SEGUN
Bunding and coating operation to stop water leaking by traditional Japanese style and by wetland tractor(Yanmer Co.Ltd., Google, http://blogs.yahoo.co.jp/shouji108jp/4267187.html )
Sawah ecotechnology training of SMART-Africa Rice staffs as well as Togo and Benin extension officers at Kumasi,November 2011
Manual Leveling needs hard-works forSawah system construction
Kumasi site in 2002, Ghana. Wet season Puddling, soil moving and leveling. Power tiller and wooden plank.
Cost $2000-4000, 10 ha per 6 months. Leveling quality within 5cm in a sawah plot,
Paddy Yield 3-7 t/ha (Sawah Technology)
Plowing, puddling, and leveling by water powertiller, Northeastern Thailand 2000
Indonesian G1000 Boxer can move soil 25m for leveling(10th Dec 2015)
Powertiller leveler can move soil >25m. Plow can help strong bunding & wider and deeper canal digging even at the flood plain. Lower right is puddler.
Sawah plot size expansion and improvement of leveling quality 2.5cm in dry season,
Cost $70,000, 100ha per six months.Paddy Yield: 7-14 t/ha,
Water use saving, Efficient Weed controlJapan in 2013
Sokwae Sawah transplanting, surface leveling and smoothing (CRI. Dr. Bam)
Sawah is ecotechnology based Multi-Functional constructed Wetland: Production, Environment, and Cultural landscape (JICA sawah project, 2001)
Inland valley, Ashanti, Ghana, 2001
Termitemound
Traditional, BidaSawah, Sep10
Nupe village of Sheshi Bikum: 3 ha of sawah was developed in three months in 2010 using one powertiller of sawah project. Paddy production was about 13 ton, which is equivalent to $5000. Sawah farmers group bought additional powertiller
of $3000. Sawah area expanded to 40ha by January 2012.
Canal Construction by Participating Farmers
Canal construction by participating farmers
20-30 m depth Tube well digger Cost(1) $300 for Tube well digging
& 4 inch pipe installation (2) $250 for pump, 3inch, 600liter/min
and $180 for 12m suction & 70m extension horse in case groundwater depth is shallower than 8m.
(3) $400 for submerged pump with 2.2inch pipes lifting water 500liter/mine from 20m depth of groundwater using generator of $1000, which can drive two to three submerged pumps
(4) 1ha sawah needs 100ton of water per day(5) Tubewell digger machine cost $2500-5000
Powertiller plow can help for bunding
Canal digging calso be helped bPowertiller plow
Leveler atatchmenthelpFor surface leveling
4inch casing pipe with 30m depthcan supply dry season irrigationWater
Canal construction by power tiller plow
Training on topo-survey NCAM Bida, Shabamaliki
Bida, ShabamalikiPowertiller sinking
On the job training
JICA/CRI Sawah project
ADEMILUYI, YINKA SEGUN
Restoration measure to connect spring water and sawah by irrigation canal and syphon pipes at Adugyama, Mr. Tawiah’s site, August 2011
International workshop on sustainable sawah development by farmers’ self-support efforts was organized at Kumasi, Ghana in collaboration with Agric. ministries of Ghana & Nigeria, JIRCAS-Japan, AfricaRice and our Sawah project. Now leading farmers can develop 5-10ha of new sawahfields within 1-2 years and produce 20-50 ton of paddy per year (Nov. 2011)
On the job training has expanded to the staffs of AfricaRice, Togo and Benin on various skills of sawah eco-technology (Afari, Ghana, Nov.2011)
Small pump based Oasis type sawah
development at savanna floodplainperformed paddy yield
7t/ha at Jega, Kebbi state, Nigeria(May
2011)
AfricaRice’s Sawah Project : SMART(Sawah, Market Access and Rice Technology) program for Africa’s inland-valley rice farmers, Mar 2, 2016(IRRI, rice today). Sawah and sawah technology quality seems to yet have reached to standard (Comment by T.Wakatsuki)
Sawah technology training and demonstration at Haraze, border town of Central Africa Republic, and Tissi, border of Sudan, during December 2015 to April 2016
Sawah technology training and demonstration at Haraze, border town of Central Africa Republic, and Tissi, border of Sudan, during January to May 2016
Table 5. Cost and income (US$) of new sawah development (Nigeria and Ghana, 2013).
Activity
Cos/income elements,
performance or durability of Agric.
Machineries
Spring-based ( slope 1.5%)
Floodplain-like
(mean slope 1%)
Stream dike-
based ( slope 1%)
Pond-based (mean slope 1%)
Pump-based (mean slope 1%)
Non-sawah(mean slope 2%)
A. Sawah development activities (first year only, per ha)Clearing, Bunding 30–50 work-days† 200 150 150 150 150 75Plow, Puddling,
leveling14-21 days powertiller
operation 300 250 250 250 250 NA
Pumping cost Minimum 3 ha/year‡ NA 150 NA 100 250 NA
Canal $1000 for 100 m per ha 100 50 200 200 100 NA
Dike/weir $450 for 20 m 5 m 3 m per 3 ha NA NA 150 NA NA NA
Flood control $700 for 150 m 2 m 2 m per 3 ha NA 300 100 NA NA NA
Pond construction $1500 for 20 m 20 m 2 m per 3 ha NA NA NA 500 NA NA
Personnel cost for on the Job training ($/ha) Scientists/engineer ($1000/ha) , Extension officer ($500/ha), Leading farmers($250/ha)
Cost including training cost
2300-1550 2500-1750 2450-
16752800-
20502350-
1600 75
† 1 work-day costs $3.5.‡ Pumping machine: $500-1000 of two sets for 1ha irrigation, 30% $150-300 for spare parts, 3-5 years of life
Power-tiller cost: $5000 for 3–7-year life, 20% depreciation, 20% spare parts; initial sawah development claims heavy load on power-tiller, which comprises 50% of cost of development.
Table 6. Cost and income (US$) of sawah-based rice farming in the first development year and total cost (Ghana and Nigeria, 2013).
Activity
Cost/income elements,
performance or durability of
Agric. Machinery
Spring-based (slope 1.5%)
Floodplain-like
(mean slope 0.5%)
Stream dike-based (slope 1%)
Pond-based (slope 1%)
Pump-based(mean slope 1%)
Non-sawah(slope 2%)
B. Sawah-based rice farming cost (first year only, per ha)Nursery, seed 3 work-day, 60-90kg 90 90 90 90 90 130*Water
OJTCB training 915 915 915 915 1015 450Total cost in the first year except for
training cost 2215 2415 2365 2715 2365 525Yield 4–5 t/ha 4.0 4.5 4.5 4.5 5.0 1.5Gross income $500/t of paddy 2000 2250 2250 2250 2500 750Net income -215 -165 -115 -465 135 225† 1 work-day costs $1.5-3.5, *direct sowing and/ or dibblingAlthough sawah approach gives sustainable low-cost personal irrigated sawah system
development, which costs about 10% of ODA-based irrigated sawah development, there mayneed to be special subsidization to encourage sawah development by farmers in the first year.
Table 7. Cost and income (US$) of sawah based rice farming ( Nigeria and Ghana, 2013).
Activity Cost/income, work days, performance machinery
Spring-based
Floodplain-like
Stream dyke
Pond-based
Pump-based Non-sawah
C. Sawah-based rice farming cost (subsequent year, per ha)Pump 2–10days ($15/day) NA 75 NA 50 200 NAPower-tiller,Plow, Puddling
10 days per powertiller10 ha/year, life 5–7 years 150 150 150 150 150 NA
Maintenance,canal,dyke,pond 15% of new construction 50 100 100 150 50 NAWatermanagement
† 1 work-day costs $1.5-3.5. In case of Non-Sawah, threshing day is less than half, because of lower yield* Including annual land clearing. direct sowing and/ or dibbling need 3-6 times higher seed rate than transplanting** if harvester available we can save $100 if quality sawah area is available larger than 25ha
UN village
NCAM
IITA
NCRI
: Long term basic action research site during 1986-2008: New demonstration site conducted during 2009 -2011,
5000 ha of New Sawah development at100 sites, each site 50ha of sawahdevelopment and minimum 200 ton ofannual paddy production, in 24 statesusing 500 sets of power tillers and 200sets of small harvesters. Total estimatedcost is $12.5 million (2 billion Naira). Ifthis extension project is successful, thepath for green revolution will be clearin Nigeria and SSA.
Summary data on past irrigation projects in Subsaharan Africa funded by ODA through JICA and possible dramatic reform by Sawah Ecotechnology
1. Lower Anambra, Nigeria Total 22 billion Yen, $100million, 17 billion was Yen loan. Huge pump irrigation of 3850ha developed by Japanese companies, full mechanization during 1981-1989. JICA grant for technical cooperation, 1989-1993. High development cost $30,000/ha, Malfunction of both irrigation & mechanization since 1993. Bothmanagement and endogenous development are difficult.
2.Mwea, Kenya: 3000ha of new irrigation and 5860ha of rehabilitation during 2011-2016, 14 billion Yen loan, including planning consultant cost 0.7billion Yen in 1993-1996.Technical cooperation in 1989-1998 with 4billion Yen grant for rehabilitation of 5860ha.
High development cost >$20,000/ha and management. Difficult endogenous development.
3. JICA/MoFA Sustainable Development of Rain-fed Lowland Rice Production Project. Even though results from this project look encouraging with yields of over 5t/ha recorded, it is on a micro-scale where demonstration sites are only micro-plots (0.1ha) with high cost. Net returns will therefore be very low and its economic impact negligible. Scaling up using sawah ecotechnology and effective collaboration in technology transfer is necessary to achieve the desired results
4. Proposal JICA 1billion Yen, $15million, loan for 5000 ha of irrigation development within 5 years by Sawah Ecotechnology : 100-500 core sites, each 50-10ha sawah development. Total 5,000ha, 20,000ton of annual paddy production, which is equivalent to $10million/year, within 5 years. 700 sets of powertillers $ 3 million, 170 sets of small harvesters $ 2 million, Development logistics $ 2.5 million, Farmers training $ 2.5 million, Youth training $2.5 million, Vehicle $ 1.5 million, Project management & consultancy $ 1 million. Development cost <$3000/ha. Since the core sites attract 3-5 new sites, then new sites expand to 1500- 2500 sites. Thus endogenous development expand with acceleration.
6. >100,000ha of Sawah development during 2017-2026: Africa wide dissemination. 7. >Millions ha of Sawah development during 2027-2050: African wide rapid expansion
and Realization of African Rice Green Revolution
The target of improvement of ODA projects by the application of Sawah Technology