Assessing water pollution at basin level is a challenging task. In this study, the environmental sustainability of grey water footprints (WFgrey) of Peshawar Basin in Pakistan was analysed. The release of nitrogen (N) and phosphorus (P) from point and non-point sources during the period 1986 to 2015 were studied. Water pollution level (WPL) for normal and 10%-50% future reduced runoff in Kabul River as a result of construction of dams was considered. Methodologies described in Water Footprint Assessment Manual and Grey Water Footprint Accounting Guidelines were followed. Results showed that 30-year annual average of N and P discharges were 24.5×103 t/a and 10.9×104 t/a respectively. The discharge of N and P from non-point sources contribute 97% and 99% respectively. N related WFgrey was 50108 m3/a and 50109 m3/a for P. WPL of N was within the sustainable limit for all reduced runoff scenarios while P-related WPL for normal runoff exceeded sustainable limits and was worse in each reduced runoff scenario. This study confirms the deteriorated water quality of Kabul River and the findings may be helpful for future planning and water resource management of the basin.
Keywords: sustainability, grey water footprint, nitrogen, phosphorus, water pollution, Kabul River, Pakistan
DOI: 10.25165/j.ijabe.20191204.4804

Citation: Khan T, Khan H. Environmental sustainability of grey water footprints in Peshawar Basin: Current and future reduced flow scenarios for Kabul River. Int J Agric & Biol Eng, 2019; 12(4): 162–168.

sustainability, grey water footprint, nitrogen, phosphorus, water pollution, Kabul River, Pakistan

Bangash F K, Alam S. Quality parameters and its impact on the drinking water of Peshawar division Pakistan. J. Chem. Soc. Pak, 2003; 25: 125–132.

Karn S K, Harada H. Surface water pollution in three urban territories of Nepal, India, and Bangladesh. Environ. Manage, 2001; 28(4): 483–496.

Helen P J, Neal C, Paul J A. Sewage effluent phosphorus: A greater risk to river eutrophication than agricultural phosphorus. Science of the Total Environment, 2006; 360(1-3): 246–253.

Liu C, Kroeze C, Hoekstra A Y, Gerbens Leenes W. Past and future trends in grey water footprints of anthropogenic nitrogen and phosphorus inputs to major world rivers. Ecol. Indic, 2012; 18: 42–49.

Yan Y, Jia J, Zhou K, Wu G. Study of regional water footprint of industrial sectors: the case of Chaoyang city, Liaoning Province, China. Int. J. Sustain. Dev. World Ecol, 2013; 20 (6): 542–548.

Manzardo A, Loss A, Fialkiewicz W, Rauch W, Scipioni A. Methodological proposal to assess the water footprint accounting of direct water use at an urban level: a case study of the municipality of Vicenza. Ecol. Indic, 2016: 69: 165–175.

Eva M M, Deakin J, Archbold M, Gill L, Daly D, Bruen M. Sources of nitrogen and phosphorus emissions to Irish rivers and coastal waters: Estimates from a nutrient load apportionment framework. Science of The Total Environment, 2017; 601–602: 326–339,

Serio F, Miglietta P P, Lamastra L, Ficocelli S, Intini F, De Leo F, et al. Groundwater nitrate contamination and agriculture land use: A grey water footprint perspective in South Apulia Region (Italy). Sciences of the Total Environment, 2018; 645: 1425–1431.

Van Drecht G, Bouwman A F, Harrison J, Knoop J M. Global nitrogen and phosphate in urban wastewater for the period 1970 to 2050. Global Biogeochem Cycles, 2009; 23(3): 1–19.

Ogbonna D N. The impact of untreated sewage wastes discharge on the Physico-chemical properties of rivers in Port Harcourt metropolis. E-World Journal of Scientific Research and Reviews, 2014; 2(2): 1–19.

Mekonnen M M, Hoekstra A Y. Global gray water footprint and water pollution levels related to anthropogenic nitrogen loads to fresh water. Environ. Sci. Technol, 2015; 49(21): 12860–12868.

Mekonnen M M, Hoekstra A Y. Global anthropogenic phosphorus loads to freshwater and associated grey water footprints and water pollution levels: a high-resolution global study. Water Resour. Res, 2018; 54(1): 345–358

Nafees M. Role of Kabul River in socio-economic activities and associated environmental problems. Central Asia Journal, 2012; 67: 1–6.

Ejaz N, Hashmi H N, Ghumman A R. Water quality assessment of effluent receiving streams in Pakistan: a case study of Ravi River. Mehran University Research Journal of Engineering & Technology, 2011; 30: 383–396.

Khan B, Khan H, Muhammad S, Khan T. Heavy metals concentration trends in three fish species from Shah Alam River (Khyber Pakhtunkhwa Province, Pakistan). J. Nat. Environ. Sci, 2012; 3(1): 1–8.

IUCN, Pollution and the Kabul River, An analysis and action planning, Department of Environmental Planning and Mangement, University of Peshawar, 1994. https://portals.iucn.org/library/node/8352

Zakir S N, Ali L, Khattak S A. Variation in major element oxide with time in the soils of Peshawar Basin: their comparison with the normal agricultural soil. J. Himal. Earth Sci, 2013; 46(2): 35–48.

Khan S, Shahnaz M, Jehan N, Rehman S, Shah M T, Din I. Drinking water quality and human health risk in Charsadda district Pakistan. J. Clean. Prod, 2013; 60: 93–101.

Ahmad H, Yousafzai A M, Siraj M, Ahmad R, Ahmad I, Nadeem M S, et al. Pollution problem in River abul: Accumulation estimates of heavy metals in native fish pecies. Biomed Res. Int, 2015; 537368: 1–7. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4538320/

World Bank. Scoping strategic options for development of the Kabul River basin, sustainable development department. South Asia Region, 2010. https://openknowledge.worldbank.org/handle/10986/18422

Government of Afghanistan. Afghanistan national peace and development framework (ANPDF) 2017 to 2021. http://extwprlegs1.fao.org/docs/pdf/ afg148215.pdf

Mustafa K. The News International: 5th June, 2016. https://www.thenews.com.pk/print/125490-India-out-to-damage-Pakistans-water-interests-on-Kabul-river. Accessed on [2017-09-10]

Shah M T, Tariq S. Environmental geochemistry of the soil of Peshawar Basin, NWFP, Pakistan, Journal of Chemical Society of Pakistan, 2007; 29(5): 438–445.

Ahmad N, Noor S, Saleem M, Fazalullah. Water pollution studies of the urban and industrial areas of NWFP Pakistan, National Centre of Excellence in Physical Chemistry, University of Peshawar, 1982; 2: 25–34.

Ahmad N, Khan F. Dissolved oxygen and biochemical oxygen demand of Kabul River and industrial wastewaters of Nowshera industrial area. National Centre of Excellence in Physical Chemistry, University of Peshawar, 1983; 3: 87–95.

Kamin K, Arif M, Khattak M A, Shah R A. Chemical characteristic of drinking water of NWFP Part-1, Pakistan Council Scientific and Industrial Reseach (PCSIR) Peshawar, Pakistan, 1985.

Sohail A. Bottom fauna and organic matter in bottom mud of kabul-indus drainge system. Master thesis, Department of Zoology, University of Peshawar, Pakistan, 1989.

Nafees M, Ghulam K. Environmental impact assessment of amangarh industrial estate, Nowshera. Mphil thesis, Department of environmental planning and management, University of Peshawar Pakistan, 1992.

Nawab B. Evaluation of sewage water pollution in peshawar city, Master thesis, Department of environmental planning and management, University of Peshawar, Pakistan; 1992.

Khattak R A, Rehman A. Effect of disposal on industrial waste on the quality of Kabul River water and soil at Pirsabaq. Master thesis, University of Agriculture Peshawar, Pakistan, 1992.

Wahid A, Muhammad G. Impact of industrial effluents on wheat and aquatic fauna (fishes) in River Kabul near Amangarh. Mater thesis, Department of environmental planning and management, University of Peshawar Pakistan, 1992.

Pervez S. The flood plain vegetation of Kabul River and its tributaries in duaba-daudzai area near Peshawar. Master thesis, area study center, University of Peshawar Pakistan; 1993.

Iqrar M. Survey of Khazana sugar mill, Peshawar a case study of nasir killy village program. Master thesis, Department of environmental planning and management, University of Peshawar Pakistan; 1994.

Khan T, Muhammad S, Khan B. Investigating the levels of selected heavy metals in surface water of Shah Alam River (A tributary of River Kabul, Khyber Pakhtunkhwa). Journal of Himalayan Earth Sciences, 2011; 44(2): 71–79.

Akif M, Khan A R, Sok K, Hussain Z. Textile effluents and their contribution towards aquatic pollution in the Kabul River (Pakistan). Jour. Chem. Soc. Pak, 2002; 24(2): 106–111.

Khan S A, Khan M. Water quality characteristics of the Kabul River in Pakistan under high flow conditions. Jour. Chem. Soc. Pak, 1997; 19(3): 201–209.

Khan A R, Akif M, Wadud S, Khan K. Pollution studies of kabul river and its tributaries for the assessment of organic strength and fecal coliform. Jour. Chem. Soc. Pak, 1999; 21(1): 41–47.

Khan A R, Kashif M, Riaz M. Impact of industrial discharge on the quality of Kabul River water at Amangarh, Nowshera, Pakistan. Jour. Chem. Soc. Pak, 1999; 21(2): 97–105.

Yousafzai A M, Khan A R, Shakoori A R. An assessment of chemical pollution in River Kabul and its possible impacts on fisheries. Pak. J. Zool, 2008; 40(3): 199–210.

Iqbal U, Qasim H, Khan A K, Rashid R, Nasreen S, Mahmood Q, et al. Surface and ground water quality risk assessment in district Attock Pakistan. World Appl. Sci. J, 2009; 7(8): 1029–1036.

Yousafzai A M, Khan A R, Shakoori A R. Pollution of large, subtropical rivers-river kabul, Khyber Pakhtunkhwa Povince, Pakistan: Physico-chemical indicators. Pak. J. Zool, 2010; 42(6): 795–808.

Nosheen G, Ullah M, Khan K A, Rehman A. Impacts of industrial effluent on River Kabul, Hydro Nepal. Journal of Water, Energy and Environment, 2011; 8: 44–47.

Ullah Z, Khan H, Waseem A, Mahmood Q, Farooq U. Water quality assessment of the river kabul at peshawar, pakistan: industrial and urban wastewater impacts. J. Water Chem. Technol, 2013; 35(4): 170–176.

Jan A N, Khan Q, Khan A, Raziq S, Muhammad A. Monitoring of water quality parameters to know the suitability of water for fish fauna at river Sardaryab, Khyber Pakhtunkhwa, Pakistan. The Journal of Zoology Studies, 2014; 1(3): 31–37.

Rauf M, Ullah S, Haseeb A, Shah H, Khan M. Physiochemical Investigation of River Kabul at Michini , Khyber Pakhtunkhwa, Pakistan. Journal of biodiversity and environmental sciences, 2015; 7(3): 280–291.

Akhtar S M, Iqbal J. Assessment of emerging hydrological, water quality issues and policy discussion on water sharing of transboundary Kabul River. Water Policy, 2017; 19(4): 650–672.

Ma D, Xian C, Zhang J, Zhang R, Ouyang Z. The Evaluation of water footprints and sustainable water utilization in Beijing. Sustain, 2015; 7(10): 13206–13221.

Fang K, Heijungs R, Duan Z, De Snoo G R. The environmental sustainability of nations: benchmarking the carbon, water and land footprints against allocated planetary boundaries. Sustain, 2015; 7(8): 11285–11305.

Chen H S. Using water footprints for examining the sustainable development of science parks. Sustain, 2015; 7(5): 5521–5541.

Pellicer-Martnez F, Martnez-Paz J M. The water footprint as an indicator of environmental sustainability in water use at the river basin level. Sci. Total Environ, 2016; 571: 561–574.

Miglietta P P, Toma P, Fanizzi F P, De Donno A, Coluccia B, Migoni D, et al. A grey water footprint assessment of groundwater chemical pollution: Case study in salento (Southern Italy). Sustain, 2017; 9(5). https://doi.org/10.3390/su9050799

Government of Pakistan, Bureau of Statistics, 2017. http://www.pbs.gov.pk/, Accessed on [2017-11-09].

Favre R, Kamal G M. Watershed atlas of Afghanistan, Ministry of Irrigation, Water Resource and Environment, Kabul, Afghanistan, 2004. http://dwms.fao.org/~draft/prod_watersheds_en.asp

Government of Pakistan, National Fertalizer Development Centrre, National Fertalizer Annual Report, Islamabad, 1986-2015. http://www.pbs.gov.pk/

Government of Pakistan, Agriculture Census Organization. Census of

livestock, NWFP Report, Lahore 1986-2015. http://www.pbs.gov.pk/

FAO, Livestock Sector Brief, Pakistan, Livestock Information Sector, Analysis and Policy Branch, 2003. http://www.fao.org/ag/againfo/ resources/en/publications/sector_briefs/lsb_PAK.pdf

Yousif O K, Babiker S A. The desert camel as a meat animal. Meat Sci. 1989; 26 (4): 245–254.

Sheldrick W, Keith Syers J, Lingard J. Contribution of livestock excreta to nutrient balances. Nutr. Cycl. Agroecosystems, 2003; 66 (2): 119–131.

Bouwman A F, Lee D S, Asman W A H, Dentener F J, Van Der Hoek K W, Olivier J G. Global high resolution emission inventory for ammonia. Global Biogeochemical Cycles, 1997; 561–587. https://doi.org/10.1029/ 97GB02266

FAO. FAOSTAT online database; Food and Agriculture Organization, 2012. http://www.fao.org/faostat/en/

Morée A L, Beusen A H W, Bouwman A F, Willems W J. Exploring global nitrogen and phosphorus flows in urban wastes during the twentieth century. Glob. Biogeochem. Cycle, 2013; 27(3): 836−846. https://doi.org/10.1002/gbc.20072

Food and Agriculture Organization (FAO), World Health Organization (WHO), and UNU. Energy and protein requirements, 1985; 724: Geneva. http://www.fao.org/3/a-y5686e.pdf

Calloway D H, Odell A C F, Margen S. Sweat and miscellaneous nitrogen losses in human balance studies. Journal of Nutrition, 1971; 101(6): 775−786.

Kimura S D, Liang L, Hatano R. Influence of long-term changes in nitrogen flows on the environment: a case study of a city in Hokkaido, Japan. Nutr. Cycling Agroecosyst, 2004; 70 (3): 271−282.

Qureshi Z, Water and sanitation in Khyber Pakhtunkhwa. South Asian cities confrence Karachi, Pakistan Urban Forum, January 10th -12th 2014.

Government of Pakistan, Water and Power Developent Authority (WAPDA), Tarbella, Pakistan, 1986-2015.

Hoekstra A Y, Chapagain A K, Aldaya M M, Mekonnen M M. The Water Footprint Assessment Manual, 2011. https://waterfootprint.org/ media/downloads/TheWaterFootprintAssessmentManual_2.pdf

Franke N A, Boyacioglu H, Hoekstra A Y. Grey water footprint accounting, Tier 1 supporting guidelines, UNESCO-IHE, Institute of Water Education, Delft, Netherlands, 2013. https://waterfootprint.org/ media/downloads/Report65-GreyWaterFootprint-Guidelines_1.pdf

Nafees M, Ahmad F, Butt M N, Khurshed M. Effects of water shortage in Kabul River network on the plain areas of Khyber Pakhtunkhwa, Pakistan. Environ. Monit. Assess. 2018, 190(6). https://link.springer.com/ article/10.1007/s10661-018-6730-3

Correll D L. The role of phosphorus in the eutrophication of receiving waters: A review. J. Environ. Qual, 1998; 27: 261–266.

Almadullah R, Dongshik K. Assessment of potential dam sites in the Kabul river basin using GIS. Inter. J. Adv. Comp. Sci. Appl, 2015; 6(2): 83–89.