Understanding potential conflicts among sectors due spatial and seasonal water use and availability in Bali, Indonesia

UNESCO-JASTIP Joint Symposium on Intra-Regional Water Security and Disaster Management 15-16 November 2017, Quezon City, Philippines Understanding potential conflicts among sectors due spatial and seasonal water use and availability in Bali, Indonesia Eva Mia Siska Supervisors: Prof. Dr. Kaoru Takara Assoc. Prof. Takahiro Sayama 1

Contents of presentation Problem Statement Study context Methodology Results o Water demand o Water supply Conclusions 2

Economic growth and water reallocation Population Growth Urbanization Industrialization Economic diversification Hydrological variation have less impact during dry season Hydrological variation have bigger impact during dry season More people, water consumptive lifestyle Different water users with higher economic value (more cash per drop) Less population, modest lifestyle (less water per capita) Clean water competition between tourism and locals Modern water supply More farmers, Higher lifestyle, more crops per year Less water user, simpler water management, less conflict 6,000 4,000 2,000 0 1900 1940 1950 1960 1970 1975 1980 1990* 2000* Agriculture Industry Municipal Reservoirs Larger area same water amount Water withdrawal in the world (km 3 /year) (Shiklomanov, 1993) *) Estimation 3

Economic growth and water reallocation Industrialization and urbanization are currently taking place in most of developing countries in the world. Inevitably, water transfers to the growing urban centers and inter-sectorial water allocation are likely to happen (Komakech, Van Der Zaag, & Van Koppen, 2012; Wang, Fang, & Hipel, 2003); Water is too often devoted to economically inefficient, low return (usually agricultural) uses and that reallocation to more efficient, high return (usually urban) uses would increase total economic welfare. (Molle, 2006); Water reallocation due to limited amount of resources has been known as source of conflicts among sectors; Water scarcity condition creates higher vulnerability for conflict due to water transfer which may escalates to destruction and fights among water users

Study Context : Bali, Indonesia Suara Pembaruan Newspaper (September 2015) 1. Area : 5,634.40 km 2 1) 2. Population (2014): 4,104,900 2) 3. 8 regencies and 1 city Merdeka.com (September 2014) Gross Domestic Product (GDP) of Bali Province 2013 16.82% 29.89% 15.56% 2003 21% 30% 14% 1993 22% 30% 14% 1987 47% 19% 10% 0% 10% 20% 30% 40% 50% 60% 70% 80% 90% 100% Agriculture, Livestock, Forestry and Fishery Mining&Quarrying Manufacturing Industry Electricity, Gas and Water Supply Construction Trade, Hotel&Restaurant Transport&Communication Financial,Ownership and Business Services Services Sources: 1) Bali Provincial Government; 2) Bali Statistical Agency 5

Jan-82 Sep-84 May-87 Jan-90 Sep-92 May-95 Jan-98 Sep-00 May-03 Jan-06 Sep-08 May-11 Millions Study Context : Bali, Indonesia 350,000 300,000 250,000 200,000 150,000 100,000 50,000 - Number of tourists visiting Bali Island 4.5 4.0 3.5 3.0 2.5 2.0 1.5 1.0 0.5 Population (1979-2013) Population Growth Rate (2000-2010): 2.14 0.0 1979 1987 1994 1999 2004 2009 0 1982 1988 1995 2000 2005 2010 This study takes an example of rapid development in Bali as one of the world s tourist destinations The shifting water distribution from agriculture which is mostly owned by the locals to tourism industries about 85% of which is owned by non-balinese (MacRae, 2010) is one of the examples of a conflict ridden process; Research on water conflicts in Bali were mostly discussed through social and political perspectives (Cole, 2012; Tarigan, Dharmawan, Tjondronegoro, & Suradisastra, 2014; Trisnawati, 2012); Very little research were published about the scientific reasons behind these conflicts; The objective of this study is to understand conflicts between sectors in Bali by comparing the spatial and seasonal variabilities of water uses and availability. 200 150 100 50 Paddy fields (Harvested Area) in Th. Ha (1982-2013)

Water Resources and infrastructure P (mm/y) 1,250 1500 1,750 2,000 1,750 2,250 2,500 Rainfall Station Ngurah Rai Mean monthly rainfall period 1990-2014 Rainfall 2,250 3,000 2,000 2,750 2,500 2,750 3,000 1,750 2,000 1,500 1,750 2,250 3,250 3,000 Dams : (total storage 14.37 million m 3 ) Palasari Dam (Jembrana Regency) - 8 million m 3 Telaga Tunjung Dam (Tabanan Regency) - 1 million m 3, Gerokgak Dam (Buleleng Regency) -3.75 million m3 and Benel Dam (Jembrana Regency) -1.62 million m 3 (Ministry of Agriculture, 2017). 500 428 450 400 331 350 288 300 226 250 200 144 143 150 Rainfall (in mm) 72 77 100 45 33 50 13 31 0 1500 Month, Clean water is supplied by Regional Drinking Water Companies (PDAM), which are managed by each regency/city. Alternative water supply Shallow wells (less than 12 m) Deep wells (max. 60 m with less than 100 m 3 /month) Rivers, Data source: Isohyet Map: JICA Rainfall Data: BMKG Location map of PDAM JICA., 7

Water Crisis and Conflicts Info-graphic in local newspaper (Bali Post) about Bali Water Deficit Water crisis has been the media headline for the past decade in Bali. J F M A M J J A S O N D Water crisis because of damage in infrastructure due to floods/landslides Water crisis because of lack of water source 8

Social Science Complains from community: I have to walk more than 2 km to find water during season (Bali Post, 2015) The water in this cubang (water storage) is still enough before the peak of dry season, but after the peak, discharge decreased and we have to buy clean water (from water tank). This situation happened since a long time ago (Bali Post, 2016c) Complains from farmers: Drought happened because volume of water in irrigation channel is small (Bali Post, 2017), I cannot do farming anymore. There is no water. I lost my source of income. (Bali Post, 2016b). Some conflicts of water has been escalated from the crisis (Strauß, 2011; Tarigan et al., 2014) and some even lead to destruction of public property such as road and pipes (Bali Post, 2011b, 2011c). Conflicts happened between farmers and PDAM and fights among local population over clean water. 9

Water Balance Calculation Period of calculation: 1994 to 2013 (20 years monthly for every regency) Water Use: 1) Agriculture 2) Domestic 3) Tourism vs. Water Availability: 1) Rivers 2) Springs 3) Groundwater Water use Data Standard Domestic Tourism Agriculture Population data (National population census) Number of hotel rooms Monthly occupancy rate (only occupied room were counted) (Bali Province Statistical Agency) Harvested Area (Bali Province Statistical Agency) Rainfall data (Ministry of Public Work rain gauges) Climatic data (BMKG climatic stations) 1 person = 100 l/d (Indonesian National Standard/SNI) (unit in m 3 /room/year) 4-5 star = 1,424 1-3 star = 949 Non-classified = 548 *) next slide

Agriculture water use JAN FEB MAR APR MAY JUN 1 15 1 15 1 15 1 15 1 15 1 15 k c 1.1 1.1 1.08 1.05 1 0.95 - - 1.1 1.1 1.08 1.05 I 2 2 2 2 2 1 1 2 2 2 2 2 LP - - - - 3.33 6.67 3.33 - - - - - WLR 1.67 1.67 1.67 1.67 - - 1.67 1.67 1.67 1.67 1.67 JUL AUG SEP OCT NOV DEC 1 15 1 15 1 15 1 15 1 15 1 15 k c 1 0.95 - - 1.1 1.1 1.08 1.05 1 0.95 - - I 2 1 1 2 2 2 2 2 2 1 1 2 LP 3.33 6.67 3.33 - - - - - 3.33 6.67 3.33 - WLR - - 1.67 1.67 1.67 1.67 1.67 - - 1.67 Units: k c (-), I (mm/d), LP (mm/d), WLR (mm/d), DR (mm/d), E (-) All constants were based on JICA et al. (2006) IW = ET c + I + LP + WLR + 0.7DR E Formula obtained from JICA et al. (2006) IW = Irrigation Water ET o = Potential Evapotranspiration obtained by Penmann-Monteith equation for <=23.33 mm, = 0.6 3.33 for >23.33 mm, = 0.8 6.00 0.5

Water Availability Rivers Estimated from daily river discharge of major 31 river catchments; Estimation method provided by Ministry of Public Works of Indonesia. (based on a water balance equation using daily rainfall and evapotranspiration) including related coefficients suitable for Bali s settings. Springs Based on data inventory of springs yield from Ministry of Public Works data. The spring water availability is calculated with the following equation: SW ( m, r) j n j 1 Q ( j, m) SW = spring water ; Q s is max. yield, n= is number of springs in one regency. s Groundwater Estimated groundwater availability of a regency/city used based from JICA s revision on the calculation from the Integrated Urban Infrastructure Development Program-Bali (IUIDP-Bali) Project. The recharge volume of each regency is calculated based on the proportion of each geological formation in the respective regency and the rainfall in the area and the exploitable limit is 10% of the recharge.

Total and agriculture Domestic and tourism Annual Water Use (Bali) Water use in Bali (1994-2013) (in million m3) 1994 2013 1,700 1,600 TOTAL 300 250 AGR 92% DOM 7% AGR 89% 1,500 1,400 1,300 1,200 1,100 Agriculture Domestic Tourism 200 150 100 50 TOU 1% TOU 2% DOM 9% Total water use increased by 0.01 billion m 3 (0.54%) in 20 years; Domestic Water Use increased by 0.04 billion m 3 Tourism Water Use increased by 0.01 billion m 3 Agriculture Water use decreased by 0.04 billion m 3 1,000 1994 1999 2004 2009 0 Water transfer: Agriculture to Domestic (82%) and Tourism (18%) 13

Spatial Water Use (9 Regencies/City) Domestic 1994 2013 In million m 3 1994 Total <7 7-14 Domestic water use increased in most part of Bali and the highest in in Badung and Denpasar 1994 Tourism 2013 14-21 21-28 >28 In million m 3 Legend adm_bali_kab In T1994 million m 3 Badung <4 4-8 8-12 12-16 >16 <100 100-200 200-300 300-400 >400 Overall the highest water use is still in Tabanan area 2013 1994 Agriculture 2013 Gianyar Legend adm_bali_kab In million m 3 T2013 <80 80-160 160-240 240-320 >320 14

Millions 1994 Legend Tourism seasonal MAY Seasonal Tourism.csv.May water use Legend < 0.18 0.18-0.36 MAY In million m 3 Seasonal Tourism.csv.May 0.36-0.54 0.54-0.72 < 0.18 0.72-0.90 0.18-0.36 0.90-1.09 0.36-0.54 1.08-1.26 0.54-0.72 1.26-1.44 0.72-0.90 > 1.44 1.7 1.6 1.5 1.4 1.3 1.2 1.1 1.0 0.9 0.8 2013 1994 Badung Regency 0.90-1.09 2013 1.08-1.26 1.26-1.44 > 1.44 In the peak periods, water used 1.05 times higher than the average. This value is lower in 2013 than in 1994 15

Millions 1994 Agriculture seasonal water use Legend MAY In million m 3 Seasonal agri 13.csv.May < 20 20-40 40-60 60-80 > 80 100 90 80 70 60 50 40 30 20 10 0 Tabanan Regency 2013 1994 2013 In 1994, peak happened only in Tabanan and Buleleng but in 2013 it also happened in Gianyar 16

Seasonal Water Availability 1.6 1.4 1.2 in billion m 3 1.0 0.8 0.6 0.4 0.2 0.0 1994 2003 2013 Annual water availability in Bali is ranged between 3.5 billion m 3 to 7.1 billion m 3. Most of water resources (76%) comes from rivers, 18% from springs and 6% is from groundwater (exploitable limit) The comparison of seasonal water availability in 1994, 2003, and 2013 (above picture) shows yearly and monthly variation of water availability. The lowest water availability is from August to October. 17

Water use vs. water availability Water Use/Availability Stress Level <0.1 Low 0.1 0.2 Moderate 0.2-0.4 High >0.4 Extreme 18

Conclusions Most water crisis which were reported in the local newspapers during July to October were caused by lack of water resources while those which were reported during February to April were caused by damage in water infrastructures (due to landslides or floods). Some of the reported crisis were escalated to conflicts and destructions of public properties (Bali Post, 2011b, 2011c, 2016) happened in Badung (July 2011), Karangasem (July 2011), Gianyar (October 2017), Klungkung (November 2016), and Tabanan (October 2009). All of these conflicts happened when water stress level in extreme condition. This study suggested that even though the Bali s GRDP shows a change in regional income from agriculture to tourism, but agriculture water use was only slightly decreased (2.73%) from 1994 to 2013. It even shows increasing trend since 2003. As the original income for the Balinese, this may cause conflicts between farmers and other sectors. It should be therefore well regulated in terms of timing and location based on available water resources. Accurate information with scientific evidence on spatial and temporal availability of water as well as suggestion on planting schedule should be communicated through proper method such as through the traditional subak system. 19

Conclusions Urbanization and tourism development happened in Badung Regency and Denpasar City and water was reallocated from agriculture sector (decreased by 62.78 million m3) to tourism and domestic (increased by 33.83 million m3). Furthermore, these regencies have in nature smaller water availability compare to other regencies (9% of all Bali). This situation makes these regions prone to conflict due to hydrological variation especially in prolonged dry period. The use of relatively stable water sources such as springs and groundwater should be therefore regulated and monitored in a better way to avoid uncontrolled use during dry period. On the other hand, assessment on the sustainable limit of the use of these resources particularly for these regency and city should be done more carefully to allow access during dry period. 20

Acknowledgement 21

Thank you.. 22