Abstract
Urban and peri-urban agriculture (UPA) has often been accused of being nutrient inefficient and producing negative externalities. To investigate these problems for the West African capital Niamey (Niger), nutrient inputs through fertilizer and manure to 10 vegetable gardens and 9 millet fields and nutrient offtakes through harvests were quantified during 24 months, and contamination of irrigation water and selected vegetables with faecal pathogens and heavy metals was determined. Annual partial horizontal balances for carbon (C), nitrogen (N), phosphorus (P) and potassium (K) amounted to 9,936 kg C ha−1, 1,133 kg N ha−1, 223 kg P ha−1 and 312 kg K ha−1 in high input vegetable gardens as opposed to 9,580 kg C ha−1, 290 kg N ha−1, 125 kg P ha−1 and 351 kg K ha−1 in low input gardens. In high input millet fields, annual surpluses of 259 kg C ha−1, 126 kg N ha−1, 20 kg P ha−1 and 0.4 kg K ha−1 were recorded, whereas surpluses of 12 kg C ha−1, 17 kg N ha−1, and deficits of −3 kg P ha−1 and −3 kg K ha−1 were determined for low input fields. Counts of Salmonella spp. and Escherichia coli yielded above threshold contamination levels of 7.2 × 104 CFU 25 g−1 and 3.9 × 104 CFU g−1 in lettuce irrigated with river water and fertilized with animal manure. Salmonella counts averaged 9.8 × 104 CFU 25 g−1 and E. coli 0.6 × 104 CFU g−1 for lettuce irrigated with wastewater, while these pathogens were not detected on vegetables irrigated with pond water. These results underline the need for urban gardeners to better adjust the nutrients applied to crop requirements which might also reduce nutrient accumulations in the soil and further in the edibles parts of the vegetables. Appropriate pre-treatment of irrigation water would help improve the quality of the latter and enhance the food safety of vegetables determined for the urban markets.
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Introduction
During the last decade the use of open inner-city and peripheral spaces for urban and peri-urban agriculture (UPA) has become increasingly important in Africa to enhance the food supply to the population of the rapidly growing cities (Bryld 2003; Cofie et al. 2003). Intensively managed UPA systems can provide farmers with additional opportunities for employment, income and subsistence food (Rabinovitch and Schmetzer 1997; Lynch et al. 2001; Drechsel et al. 2006; Nguni and Mwila 2007; Thornton 2008). Moreover, UPA can contribute positively to poverty alleviation and social integration of disadvantaged and marginalized groups such as handicapped, sick or old people, female-headed families, children and jobless uneducated young people (van Veenhuizen and Danso 2007). Furthermore, these production systems allow consumers to purchase fresh vegetables and fruits as well as eggs, fresh meat and milk, poultry and fish (Cofie et al. 2001; Niang et al. 2002; Drechsel et al. 2007) on urban and local markets. To achieve these multiple objectives UPA makes use of typical urban resources such as, organic municipal waste, sewage and market refuse in crop production, which have often been found to cause microbial and heavy metal contamination of produce (Keraita and Drechsel 2002; Amoah et al. 2005; Akegbejo-Samsons 2008). Besides solid organic and liquid wastes, household wastes, contaminated livestock and poultry manures were reported to be sources of pathogen contaminations mainly of faecal origin (Guendel 2002; Sonou 2001; Drechsel et al. 2006). While manure application on UPA soils may reach up to 100 t ha−1 year−1, mineral fertilizers are often used as an additional nutrient source for vegetables such as cabbage (Brassica oleracea L.; Drechsel et al. 2005). In Lomé (Togo), for example, farmers used a combination of cotton (Gossypium hirsutum) grain, different manures and mineral fertilizers as soil amendments (Schreurs 2001). From the South of Benin high inputs of organic (>40 t ha−1) and mineral fertilisers (>600 kg ha−1) were reported as inputs for African eggplant (Solanum aethiopicum L.; Assogba-Komlan et al. 2007). In the Sahelian cities of Bamako (Mali), Ouagadougou (Burkina Faso) and Niamey (Niger), where large-scale poultry farming is constrained by heat, the combined application of cattle manure and mineral fertilizers in UPA systems is common (Drechsel et al. 2006; Graefe et al. 2008). In Niamey, the intensive fertilizer application to UPA gardens (Graefe et al. 2008) suggests strongly positive horizontal nutrient balances that may result in large gaseous and leaching losses of nutrients and environmental pollution. This is obviously in strong contrast to the negative nutrient balances reported for rural West African farming systems (Stoorvogel and Smaling 1990; Van den Bosch et al. 1998). However, detailed studies are lacking that quantify the nutrient flows and balances in the UPA systems of this region.
As such nutrient balances are of interest both from an economic and environmental point of view and have been used to evaluate the sustainability of farming systems at different scales (Nielsen and Kristensen 2005; He et al. 2007; Kyllingsbæk and Hansen 2007; Khai et al. 2007; Guo et al. 2008). The difference between the sum of nutrient inputs and the sum of nutrient outputs indicates a surplus or deficit for the system and depending on the objectives and scales of the research, different types of nutrient balances can be used. In this study we used the soil surface nutrient budget approach (Oenema et al. 2003; Bassanino et al. 2007) to quantify management-related horizontal nutrient fluxes and balances in UPA vegetable and millet farming systems of the Sahelian city of Niamey. More specifically, our objectives were (i) to quantify the management-based horizontal fluxes and balances of carbon (C), nitrogen (N), phosphorus (P) and potassium (K) at the level of gardens and fields, and (ii) to determine the concentrations of heavy metals and faecal pathogens in irrigation water used and the thus irrigated leafy vegetables.
Materials and methods
Study area and cropping systems
The study was carried out in Niamey (13.5° N, 2.2° E; 220 m asl), the capital city of the Republic of Niger, which currently has around 900,000 inhabitants who are estimated to increase to 2.5 Mio in 2025 (Maurice 2003). The region’s climate is semi-arid with a single rainy season from June to October and an 80-year average precipitation of 577 mm year−1 (L’Hôte et al. 2002). During the study period (January 2006–January 2008), annual rainfall recorded was substantially lower than this average and, equally typical for semi-arid climates, varied substantially between different experimental sites within the city (Table 1). During the cool dry season (November–February), average daily temperatures range from 16 to 32°C and are lowest in January (24°C); during the hot dry season (March–May) average daily temperatures range from 27 to 41°C and peak in April/May (34°C).
The city area under study covers 672 km2 with the major built-up part located north of the Niger River that separates Niamey at a length of about 15 km. This northern part is crossed from north to south by a major riverbed (wadi) through which water drains nearly year-round into the Niger River. Most of the UPA activities, especially gardening, are located along this wadi and the Niger River. Niamey’s UPA is mainly characterized by intensive urban and peri-urban vegetable gardening and some peri-urban millet farming associated with intensive sheep and goat husbandry in the city centre and extensive cattle keeping at the outskirts of the city (Graefe et al. 2008). The input-intensive, largely market-oriented vegetable gardening is dominated by exotic crop species (Table 1), whereby in contrast to popular judgement species richness was found to increase with market orientation and partly with garden size (Bernholt et al. 2009). At the city’s outskirts millet (Pennisetum glaucum L.) and sorghum (Sorghum bicolor L.) intercropped mainly with cowpea (Vigna unguiculata L.) and occasionally groundnut (Arachis hypogea L.) are cultivated as staple food.
For this study 10 vegetable gardens (Table 1) and 9 millet fields (Table 2) representing the diversity of UPA crop production systems were selected on the basis of a preceding study (Graefe et al. 2008) and were closely monitored, to quantify the management-related nutrient inputs (INs) and outputs (OUTs) (Fig. 1). Based on the management intensity, and especially the nutrient input to individual gardens and fields, respectively, these were categorized as high or low input systems. While in gardens high input systems were also strongly market-oriented, low input systems were mainly managed for home consumption. This differentiation could not be made for the millet fields which all served home-consumption.
Three and five sampling plots were installed in each garden and field, respectively. Their size varied from 1 to 10 m2 for small gardens and from 10 to 25 m2 for large ones, while in the fields, observed plot sizes were 100 m2. The total area of fields and gardens as well as the individual plot sizes were determined using a hand-held differential Global Positioning System (GPS; Trimble Pro XR, Sunnyvale, CA, USA). This data was imported into a detailed map produced from a 2005 Google Earth satellite image with 15 m resolution using ArcView 3.2. (Redlands, CA, USA).
Quantification of horizontal nutrient fluxes
Horizontal nutrient fluxes (inputs and outputs) related to farmers’ management were measured in the selected gardens and millet fields over a period of 24 month (January 2006–January 2008). All study sites were visited at least once a week and farmers were interviewed about all relevant resources inputs onto and removals from the selected plots. The main sources of nutrient inputs included fertilizers (animal manure, mineral fertilizers, ash, compost), and irrigation water; wet and dry deposition and biological N fixation were accounted for using transfer functions. Moreover, carbon influx from root exudates were accounted for as they constitute an input flux for the organic C pool of the soil through the process termed rhizodeposition (Nguyen 2003). However, as root exudation is very difficult to quantify under field conditions (Dilkes et al. 2004), we assumed that root C influx was equivalent to harvested shoot C.
In the gardens, fertilizer inputs were quantified throughout the cropping cycle by weighing the amounts applied. In the fields, the quantity of the predominantly used animal manure remaining on the soil after corralling of sheep, goats and/or cattle was determined before the onset of the rainy season using a sampling frame of 1 m2 with 10 repetitions per field. Representative samples of fertilizer and dung applied were taken at each application event (gardens) and sampling date (fields), respectively, and were kept for analysis of C, N, P and K.
Different sources of irrigation water were used, namely, wastewater, pond water, well water and river water collected upstream and downstream of the city, depending on the location of the garden. Inputs from irrigation water were quantified on a weekly basis in the garden plots by counting the number of watering cans (8–17 l; volume determined in each case) used per day. The total amount of water applied was calculated from the quantity applied per day and the length of the cropping cycle and was multiplied by the nutrient concentration in the water source. Nutrient inputs through rainwater were calculated from the amount of rainfall measured by a rain gauge at 1.5 m above ground in each garden and the nutrient concentrations therein.
To quantify the outputs throughout the 24-months measurement period, the harvested biomass of all vegetables (except for minor quantities of medicinal or ornamental plants) was determined on the selected plots of each garden by either weighing the total crop harvested per plot or by sampling and weighing all material removed from two sampling areas of 1 m2 per plot and multiplied by the total area harvested. Samples were pooled by garden, harvest date, type of vegetable and fertilization treatment. In the fields, the grain and straw yield of millet and cowpea was quantified at harvest (October) on the selected plots, and representative samples were kept for the analysis of C, N, P, K. All samples of manure and harvested plant matter were oven-dried to constant weight at 65°C and ground to 1.5 mm particle size before chemical analysis using standard methods (see below).
Nutrient fluxes were estimated by multiplying the oven-dry mass of material by their nutrient concentrations using Eq. 1.
where F is the total nutrient flow (input or output) over the period of measurement, n is the number of events (application of fertilizer, irrigation water, rain or crop removal, etc.), Q i is the quantity of raw material at event i and C i is the nutrient concentration in the raw material at event i.
Soil and water sampling
To assess the status quo of soil fertility in each garden and field, soil samples were collected at 0–20 cm (garden and field) and 20–50 cm (fields only) depths using an auger. Two subsamples each taken from two different spots within the same plot were pooled to obtain a total of five samples per field and three samples per garden, thereby differentiating samples of differently managed plots. In the gardens, the samples were collected before crop fertilization and after 12 and 24 months of intense cultivation, while in the millet fields samples were collected before the onset of the rainy season in the first year (2006) and after the harvest in the first and in the second year (2007). Soil samples from fields were pooled by soil depth into one composite sample. All samples were air-dried on a clean paper within a few hours after sampling and analyzed for mineral N (NO3 − and NH4 +), Bray-P, pH, organic carbon, effective cation exchange capacity (CEC), exchangeable K and total N using standard analytical techniques (see below).
For each garden on a bi-monthly basis 100 ml of irrigation water were collected in duplicates from the watering cans or the source point. For rain water two samples were collected at one rainfall event in the beginning (July) and the middle of the rainy season (mid-August). After sampling, one drop of 0.1 N HCl was added to each water sample after which samples were kept in the refrigerator at 4°C until analysis of pH, N, P, and K.
Chemical analyses
In soil, irrigation water and rainwater samples pH was determined in 1:2.5 soil:water (w:v) and water:water (v:v). In soil samples, organic carbon was determined according to the wet oxidation method (Walkley and Black 1934) and P-Bray according to Bray and Kurtz (1945). Total N and mineral N as nitrate (NO3 −-N) and ammonium (NH4 +-N) were determined colorimetrically with an Alpkem Rapid Flow Analyzer (RFA 1985) at 520 and 660 nm, respectively. Soil effective cation exchange capacity (ECEC) was determined by summation of exchangeable cations after their extraction with 1 n NH4-acetate and analysis of the extract by atomic absorption spectroscopy or flame emission spectro-photometry and of exchangeable acidity (H+ and Al3+) according to Espiau and Peyronel (1976). In manure, water and plant samples, total N was determined colorimetrically using the Bertholet reaction (Chaney and Marbach 1962) with an N-auto-analyzer (TECHNICON AAII, Ontario, Canada). Total P was also determined colorimetrically based on the phosphomolybdate complex reduced with ascorbic acid (Lowry and Lopez 1946) and K by flame photometry (Instrument Laboratory 543, CA, USA).
Calculation of nutrient balances
Soil surface nutrient budgets were compared to the change in extractable nutrients over the 24-months period using Eq. 2 proposed by Khai et al. (2007). To this end C, N, P and K partial balances were computed at the level of an individual field and garden by subtracting the nutrient outputs (through all harvested products) from the nutrient inputs.
where ΔP E, I E and O E stand for the change in the soil pool, the input and the output of element E, respectively. In our case, the equation takes into account the following inputs of element E from soil amendments: either organic or mineral fertilizer (FE), irrigation water (IRWE), wet plus dry depositions (WDE), biological nitrogen fixation (BNFE) and the outputs of E through harvested products (HPE). If also leaching losses (LE) and gaseous emissions (GEE) from the soil surface were accounted for, the net change in the soil storage (ΔSoilE) of element E were calculated as:
However, leaching losses and gaseous emissions were only available for some of the studied gardens and fields (Predotova et al. 2010b); they were therefore not included in the nutrient flux equation. The apparent partial, that is horizontal, balance of element E thus resulted from Eq. 4:
For cowpea annual symbiotic N2-fixation was assumed to amount to 40 kg ha−1 as it has been previously reported for the acid sandy soils of the Sahelian zone of Niger and total annual non-symbiotic N2-fixation was estimated at 5 kg ha−1 (Roy et al. 2003). Yearly dry depositions of Harmattan dust were set at 1,200 kg ha−1 with nutrient concentrations of 0.0038 kg N kg−1 dust, 0.00079 kg P kg−1 dust and 0.0187 kg K kg−1 dust (FAO 2005).
Vegetable contamination with pathogens and heavy metals
To assess a possible pathogen contamination of produced vegetables, two samples of irrigation water and of different leafy vegetables (cabbage, lettuce—Lactuca sativa L., and amaranth—Amaranthus cruentus L.) were aseptically (sterile equipment) collected per garden, once in the hot dry season (April 2007) and in the cool dry season (January 2008). Samples were kept in a refrigerator at 4°C after collection and composites per type of material and garden were analysed within 24 h for total mesophilic aerobic micro-organisms (Staphylococcus sp.) and for faecal pathogens of animal origin (Salmonella spp., Escherichia coli, Streptococci and total coliforms following standard procedures (APHA-AWWA-WEF 2001). Additionally, irrigation water (n = 2) was sampled in each garden before (May) and after (October) the rains in 2006, and analysed for total concentrations of the heavy metals copper (Cu), cadmium (Cd), lead (Pb), zinc (Zn) and nickel (Ni) using Inductive Coupled Plasma Atomic Emission Spectrometry (ICP-AES, Spectro Analytical Instruments, Kleve, Germany; Heinrichs 1989).
Statistical analysis
For each plot, horizontal partial nutrient balances of C, N, P, and K were converted to a hectare basis and F-tests performed using the General Linear Models (GLM) procedure within SAS 9.1 (SAS 2003). Independent variables were management intensity, season, and year, while dependent variables comprised soil chemical parameters, inputs and outputs of C, N, P and K as well as plant dry matter (DM) yields. Means were separated by t-tests (LSD) at P = 0.05.
Results
Main characteristics of high and low input systems
In the high input vegetable gardens, annual total nutrient inputs ranged from 1,109 to 3,816 kg N ha−1, 143 to 644 kg P ha−1, and 640 to 2,019 kg K ha−1 as opposed to 198–782 kg N ha−1, 86–253 kg P ha−1 and 315–898 kg K ha−1 for low input gardens. Similarly, for high input millet fields annual total nutrient inputs varied from 87 to 173 kg N ha−1, 19 to 44 kg P ha−1 and 54 to 115 kg K ha−1, while for low input millet fields annual nutrient inputs ranged from 0.1 to 11.4 kg N ha−1, 0.9 to 5.6 kg P ha−1 and 13 to 21.9 kg K ha−1.
Nutrient concentrations in irrigation and rain water
The use of wastewater for irrigation was most common in the gardens located along the wadi (Gountou Yena). This water contained, per litre, 150 mg N, 19 mg P and 66 mg K in the dry season (Fig. 2). In the rainy season, nutrient concentrations were 5-fold lower for N, 3-fold lower for P, and 50% lower for K. For the other sources of irrigation water, however, seasonal differences in nutrient concentrations were not significant. For the dry season, the nutrient concentrations per litre of well, river (upstream and downstream), and pond water ranged from 0.2 to 19.2 mg N, 0.2 to 0.5 mg P and 4.2 to 8.7 mg K as opposed to rainy season concentrations of 0.1–0.9 mg N, 0.4–0.5 mg P and 2.9–7.4 mg K. Average nutrient concentrations in rain water were 0.03 mg N l−1, 0.20 mg P l−1 and 3.77 mg K l−1.
Horizontal nutrient balances in vegetable gardens
Nutrient inputs varied significantly between the high and the low input gardens. Mineral fertilizers were the major sources of N and P in the high input gardens, accounting for 48 and 80% of total N and P inputs, respectively. Average annual inputs through mineral fertilizers were 711 kg N ha−1 and 234 kg P ha−1 in the high input gardens (Fig. 3) compared to 164 kg N ha−1 and 25 kg P ha−1 in the low input gardens (P < 0.05). Application of livestock manure accounted for 44, 61 and 75% of the total inputs of N, P and K, respectively, in the high input vegetable gardens, while it supplied 68% N, 73% P and 48% K in the low input gardens. However, no significant differences were found between the two types of gardens as far as the amounts of nutrients applied with manure were concerned. Likewise, C influx through manure plus estimated deposits (root exudates assumed to be equivalent to harvested shoot C) was similar for the two types of gardens (Fig. 3). Nutrient inflows through irrigation water were considerable, mainly for high input gardens where wastewater was used for irrigation, although the amounts of wastewater applied were lower than the amounts of water drawn from other water sources (Table 1). Due to its high nutrient concentrations it supplied annually up to 2,427 kg N ha−1, 376 kg P ha−1 and 1,439 kg K ha−1 (Fig. 2).
The total amounts of C, N, P and K exported through harvests in high input vegetable gardens significantly (P < 0.05) exceeded the exports in low input gardens (Table 3).
Given higher inputs of nutrients as compared to their removal with harvested produce, partial horizontal balances were strongly positive for both types of gardens. Average annual horizontal carbon and nutrient balances in high input vegetable gardens amounted to 9,936 kg C ha−1, 1,133 kg N ha−1, 223 kg P ha−1 and 312 kg K ha−1 as compared to 9,580 kg C ha−1 (P > 0.05), 290 kg N ha−1 (P < 0.05), 125 kg P ha−1 (P > 0.05) and 351 kg K ha−1 (P > 0.05) in low input gardens (Fig. 4).
The outputs (yields for one cycle of cultivation) obtained for the four major vegetables greatly depended on the crop type and the nutrient input rates. In high input gardens, the average amount of carbon and nutrients applied to cabbage (kg ha−1) was 5,613 kg C, 949 kg N, 202 kg P and 435 kg K per cropping cycle (85-days), while 7,515 kg C, 398 kg N, 103 kg P and 416 kg K were applied to tomato for each 3-month cropping cycle. The resulting yields were 8 t DM ha−1 of cabbage and 0.6 t DM ha−1 of tomato, which exceeded the yields in low input gardens by a factor of 3.8 and 6.0, respectively (Table 4). Carbon and nutrients applied to lettuce (kg ha−1, per 1.5-month cropping cycle) amounted to 5,260 kg C, 173 kg N, 52 kg P and 195 kg K in low input gardens and were 50% lower for C and P and about 3-fold lower for N and 2-fold lower for K, compared to high input gardens. For amaranth, nutrient application (kg ha−1, per month of cropping cycle) averaged 81 kg N, 5 kg P and 122 kg K in low input gardens as opposed to 531 kg N, 73 kg P and 300 kg K in high input gardens. Regardless of management intensity, no organic amendments were applied to amaranth (Table 4). For both vegetables, yields in low input gardens amounted to 2.6 t DM ha−1 (lettuce) and 6.3 t DM ha−1 (amaranth) per cropping cycle, as compared to 2.4 t DM ha−1 for lettuce and amaranth, respectively, in high input gardens.
Horizontal nutrient balances in millet fields
Animal manure was the main source of nutrient inputs to millet fields, applied annually at an average rate of 10.3 t DM ha−1 (SD = 3.8) in high input fields, thereby supplying 129 kg N ha−1, 25 kg P ha−1 and 62 kg K ha−1. Manure application accounted for 76, 91 and 65% of total N, P and K inputs in high input fields. Additional nutrient inputs originated from mineral fertilizers, which were, however, applied at low rates (Table 1). At an average of 1.5 t DM ha−1 (SD = 0.2) the annual amount of manure applied to low input fields was significantly lower (P < 0.05), supplying only 7 kg N ha−1, 3 kg P ha−1 and 7 kg K ha−1 (Fig. 5). Annual C inputs through manure plus the estimated root deposition (root debris and exudates) amounted to 1,723 kg ha−1 in high input as opposed to 1,014 kg ha−1 in low input millet fields. In low input fields, calculated wet plus dry depositions supplied up to 93% of the K inputs as compared to calculated 39% in high input fields. Additional N inputs to the fields might have resulted from the unquantified N2-fixation of cowpea intercropped with millet in both management systems. However, this contribution to horizontal balances is likely to be <20 kg ha−1 given the low stand density of cowpea in all monitored fields (1,000–2,000 plants ha−1). Annual N removals through harvest of cowpea shoots and hay averaged 6.8 kg ha−1 (SD = 5.7) in high input fields and accounted for 16% of the total N exports, while in low input fields the average removal of 5.8 kg N ha−1 (SD = 4.9) accounted for 27% of total N exports. Nutrient removals from high input millet fields through millet grain and stover harvest exceeded those from low input fields for all nutrients studied (Table 5). During the 2 years cumulative C and nutrient exports were 1.5-fold higher for C and P, 2.4-fold higher for N and 3-fold higher for K in the high input gardens compared to the low input gardens.
In the millet fields about 20–25% of the stalks were left on the field after harvest while up to 80% was removed and used as animal feed at the homestead. Horizontal balances were positive for C, N, P and K in high input fields with annual carbon and nutrient surpluses of 259 kg C ha−1, 125 kg N ha−1, 20 kg P ha−1 and 0.4 kg K ha−1, and differed significantly (P < 0.05 for C, N, P only) from those of low input fields (Fig. 6).
In contrast, in low input fields, horizontal balances were negative for P and K and only slightly positive for C and N.
Millet stover and grain yields strongly varied with the year and management intensity. In 2006, stover and grain yields averaged 2,932 kg DM ha−1 and 644 kg DM ha−1 in high input fields versus 821 kg DM ha−1 for stover and 167 kg DM ha−1 for grain in low input fields. However, in 2007, the yields obtained in high input fields were lower (2,603 kg DM ha−1 for stover and 614 kg DM ha−1 for grain), while stover (1,723 kg DM ha−1) and grain (451 kg DM ha−1) yields were higher in low input fields compared to the previous year.
Changes in the soil nutrient pool and chemical properties of vegetable gardens and millet fields
In high input gardens, average soil pH was 7.1 (SD = 0.5) in 2006, remained unchanged in 2007 and decreased to 6.7 (SD = 0.7) in 2008 (P > 0.05). In low input gardens, no changes in soil pH were observed throughout the study period (Table 6). Millet soils had a much lower pH than those of vegetable gardens, but no significant changes were observed in the topsoil and subsoil pH of millet fields during the study period. In high input gardens soil Corg increased by 36% from 4.9 g kg−1 (SD = 1.8) in 2006 to 7.6 g kg−1 (SD = 5.3) in 2008, while during the same period it decreased by a factor of 1.2 in low input gardens; a similar trend was determined for soil total N (Table 6). However, none of these changes was statistically significant. In the millet fields soil Corg remained unchanged over the 2-year study period.
In soils of vegetable gardens available nutrients increased over the study period, notably for exchangeable K (P > 0.05) and Nmin (P < 0.05, except for NO3 −-N). The concentrations of NH4 +-N determined in soils of high input gardens were 53 times higher in 2008 than in 2006, while NO3 −-N decreased by a factor of 7 during the same period. In low input gardens, soil NH4 +-N increased by a factor of 9 between the start and the end of the study period, while NO3 −-N slightly decreased (Table 6). In high input millet systems, a 55% decrease of NH4 +-N was determined in the surface soil and a similar trend was observed for NO3 −-N. In the subsoil NH4 +-N increased by 16%, while NO3 −-N decreased by 57%. In contrast, no major changes in available soil N were observed in low input millet systems. Over the 2-year study period, soil concentrations of P-Bray decreased significantly in the high input and slightly in the low input gardens. Effective CEC increased significantly in vegetable gardens while no changes were found in millet fields (Table 6).
Contamination of water and vegetables with pathogens and heavy metals
Irrigation water from the river, ponds, and wastewater sources were contaminated with Staphylococcus aureus and other pathogens mainly in the cool dry but also the hot dry season, whereby the level of contamination was higher in wastewater than in the other water sources (Table 7). The outer leaves of vegetables such as amaranth, lettuce and cabbage irrigated with river water or wastewater were contaminated with Salmonella spp. as well as with E. coli. In cabbage irrigated with wastewater and river water as well as in amaranth irrigated with wastewater, total mesophilic aerobic microorganism counts exceeded 106 CFU g−1 fresh matter in the hot dry season and were thus above the threshold value recommended by CNERNA (1996). However, in the cool dry season, pathogen levels were low in lettuce and cabbage (Table 8). Although Salmonella spp. counts in the wastewater used in garden Gountou Yena 1 amounted to 5 × 102 CFU 100 ml−1 in the hot dry season, no contamination was determined in cabbage leaves. In the cool dry season Salmonella spp. counts in this water source were 12-fold higher (6 × 103 CFU 100 ml−1), and the irrigated lettuce harbored the pathogens at a concentration of 9.8 × 104 CFU 25 g−1 fresh matter of the leaves. In the irrigated garden Gountou Yena 2, amaranth and cabbage leaves were contaminated with Salmonella spp. in the hot dry and cool dry season even though no pathogens were detected in the wastewater used for irrigation (Table 8). In the cool dry season, lettuce leaves irrigated with river water were also contaminated with Salmonella spp. in the gardens Yantala Bas 1, Yantala Bas 2 and Nogare 2, and with E. coli in the gardens Yantala Bas 2 and Saga (Table 8).
In the hot dry season of 2006, the concentration (mg l−1) of heavy metals upstream and downstream of the Niger River ranged from 0.00 to 0.02 for Zn, 0.01 to 0.03 for Cu and 0.01 to 0.01 for Ni. In the wastewater running through the wadi, the respective concentrations varied from 0.03 to 0.11 for Zn, 0.03 to 0.04 for Cu and 0.01 for Ni. In pond water Zn, Cu and Ni concentrations averaged 0.16, 0.12 and 0.04, respectively (Table 9). Shortly after the rainy season 2006, no Ni was detected in any of the water sources, and only traces of Zn were present in river and pond water, while for wastewater the Zn concentration ranged from 0.02 to 0.04 mg l−1. Post rainy season Cu concentration in upstream and downstream river water was 0.01 mg l−1, while values of 0.01–0.02 mg l−1 were determined for wastewater and 0.01 mg l−1 for pond water (Table 9).
Discussion
Horizontal nutrient balances in vegetable gardens
The management practices in Niamey’s UPA vegetable gardens were characterized by large nutrient inputs from mineral fertilizers and livestock manure to which in some cases high nutrient inputs from wastewater irrigation added. Similar observations were reported for the vegetable systems in and around Kumasi, Ghana, where local application rates of poultry manure amounted to 20–50 t ha−1 year−1 for cabbage and 50–100 t ha−1 year−1 for lettuce and spring onion (Allium spp.), equivalent to annual inputs of 770–1,650 kg N ha−1, 420–900 kg P ha−1 and 350–750 kg K ha−1 (Drechsel et al. 2004). Similarly large application rates of organic (>40 t ha−1) and mineral (360–1150 kg ha−1) fertilizers to African eggplant and amaranth were reported for UPA systems of Cotonou, Benin (Assogba-Komlan et al. 2007).
While in high input gardens of Niamey application rates per cropping cycle to cabbage and lettuce ranged from 10 to 30 t ha−1 for animal manure, 43 to 1,771 kg ha−1 for urea and 120 to 628 kg ha−1 for NPK (15:15:15), application rates in low input gardens were 9–28 t ha−1 for animal manure, 38–278 kg ha−1 for urea and 55–252 kg ha−1 for NPK. The high application rates of urea, NPK and livestock dung and the addition of high amounts of N through wastewater in some gardens caused large N surpluses in high input gardens. Although the latter allowed for nutrient extractions in harvested products that were more than 4-fold higher than in low input gardens, nutrient uptake varied greatly among the crops grown and was particularly high for leafy vegetables such as lettuce, cabbage and amaranth. With an average of 45 t ha−1 of fresh matter (FM) per cropping cycle, the yield of lettuce in low input gardens corresponded well to the value of 39 t FM ha−1 reported for similar production systems elsewhere (Khai et al. 2007), and was substantially higher than the 15–20 t FM ha−1 reported by PSEAU (2007) for Niamey at a dung application of 15–25 t ha−1. Moreover, average cabbage yields of 25 t FM ha−1 recorded in low input gardens were within the range of 10–40 t FM ha−1 reported by PSEAU (2007), while average yields of 97 t FM ha−1 obtained in high input gardens were far above this range.
Annual surpluses of 223 kg P ha−1 and 312 kg K ha−1 were calculated for high input gardens in Niamey. These figures compared well to horizontal balances reported for intensively managed small-scale vegetable systems in Hanoi, Vietnam, for which annual surpluses of 109–196 kg P ha−1 and 20–306 kg K ha−1 were published by Khai et al. (2007). However, at 1,133 kg ha−1 the average annual N surplus in Niamey by far exceeded the 85–882 kg N ha−1 balance reported for Hanoi (Khai et al. 2007). Despite the highly positive N balance over the 2-year study period, no significant changes in total soil N contents were found. This may be due to gaseous and leaching losses of N, particularly as urea and manure were often not incorporated into the topsoil immediately after application. In a companion study of UPA gardens in Niamey, annual losses of 92 kg N ha−1 in the form of NH3 and N2O were reported, with particularly high emission rates at the end of the dry season and the start of the first rains (Predotova et al. 2010a). For the same gardens, the average annual leaching losses were estimated at 11.4 kg N ha−1, 1.2 kg P ha−1 and 24.9 kg K ha−1 (Predotova et al. 2010b).
To estimate total annual balances of C, N, P and K for intensively managed gardens in Niamey, the above mentioned gaseous and leaching losses were used and complemented by annual CO2-C and CH4-C losses of 27 t C ha−1 (Predotova et al. 2010a). The resulting average annual total balances were with 843 kg N ha−1, 70 kg P ha−1 and 200 kg K ha−1 still strongly positive for these major plant nutrients, which was in contrast to a C deficit of −26 t ha−1 reflecting high mineralisation rates of organic matter. While such a negative C balance points to the need of maintaining high rates of manure application, the input of mineral fertilizer could be substantially reduced, which would lower production costs and increase resource use efficiency of UPA vegetable production in Niamey. This is all the more important since in the high input vegetable gardens a decrease in soil pH has been observed during the 24 months of our study, which may be due to the high rates of mineral N application and related leaching losses and may in the long run have negative consequences on P availability. A decrease in soil pH by 1.4 units was reported for intensive production of broccoli (Brassica oleracea var. silvestris L.) in the USA with surface application of ammonium nitrate, leading to increased nitrification and soil acidification (Stamatiadis et al. 1999). Similarly, excessive N application has been reported to increase topsoil acidification in tomato (Solanum lycopersicum L.) and maize (Zea mays L.) fields (Dougill et al. 2002; Ju et al. 2007) and to cause yield reductions in tomato (Badr and Talaab 2008) and summer cabbage (Smith and Hadley 1992). The substantial accumulation of Nmin, notably NH4 + in the topsoil of both high and low input vegetable systems may reflect residual N surpluses and increase the acidification of the topsoil. The observed Nmin increases in the topsoil may indicate NO3 −-N accumulation in the cultivated leafy vegetables. However, this would need verification. Pôrto et al. (2008) reported such increases in leaf, stem and roots of lettuce with increased application levels of urea and cattle manure.
Horizontal nutrient balances in peri-urban millet fields
In peri-urban millet production, partial nutrient balances were strongly positive for high input fields. In low inputs fields, P and K mining occurred as nutrient removal through harvested millet and cowpea grain and stover by far exceeded the very low input levels applied to these subsistence crops. This compares well to earlier reports about typical rural millet cultivation in SW Niger (Bationo and Buerkert 2001). The strongly positive horizontal balances in high input millet fields resulted mainly from manure application at an average annual rate of 10.3 t DM ha−1 through corralling of sheep, goats and cattle, which reflects the often close agro-pastoral linkages in low-intensity land use systems of Niger. Such agro-pastoral linkages were also reported for millet systems in northern Burkina Faso (Quilfen and Milleville 1983; Berger et al. 1987) and underline the role of livestock for the cereal farming systems in the Sahelian zone. To minimize nutrient leaching on sandy Sahelian soils, Brouwer and Powell (1998) recommended not to exceed an annual manure application rate of 2.5 t DM ha−1. In the present study the annual quantity of manure applied to the high input fields was 4-fold higher than this amount and by the same magnitude lower than amounts determined in high input vegetable gardens. The stover yields obtained in low input fields (1,122 kg DM ha−1 year−1) compared well to average millet stover yields in the Sahel (1,390 kg DM ha−1 year−1) reported by Yamoah et al. (2002), but were lower than the 1,625 kg DM ha−1 year−1 published for an on-station experiment in Niger where 2.5 t DM ha−1 year−1 of manure were applied (Akponikpe et al. 2008). The grain yields obtained in the studied high input millet fields (630 kg DM ha−1 year−1) were also lower than the 964 kg DM ha−1 year−1 reported for farmers’ fields in Niger receiving 10 t DM ha−1 year−1 of manure (Schlecht et al. 2004), an input similar to the amount applied to millet fields of our study. These findings provide evidence for the poor resource use efficiency in Niamey’s peri-urban millet production. Predotova et al. (2010a) reported average annual losses of 17 kg N ha−1 as NH3 and N2O and of 5,765 kg C ha−1 as CH4 and CO2 from Niamey’s UPA millet fields, accompanied by annual leaching losses of 3.6 kg N ha−1 and 2.7 kg P ha−1 (Predotova et al. 2010b). Taking into account these gaseous and leaching losses, total annual balances for an intensively managed UPA millet field were estimated at −4.8 t C ha−1, 118 kg N ha−1, 17 kg P ha−1 and 95 kg K ha−1. The latter three values are more than twice the total annual balances of 25 kg N ha−1, 7.8 kg P ha−1 and 24.1 kg K ha−1 calculated for millet fields in Niger that received 2.5 t DM ha−1 of manure (Akponikpe et al. 2008). Provided that sufficient family labour is available, farmers might thus be advised to redirect the available manure from high input fields into low input fields, so as to increase the overall productivity and efficiency of peri-urban millet production.
Contamination of water and vegetables with pathogens and heavy metals
The low amount of mesophilic aerobic microorganisms in the wastewater samples collected during the cool dry season might have been due to dilution effects which had occurred during the rainy season. Possible sources of Staphylococcus aureus in irrigation water are air-borne particles deposited by sandstorms or Harmattan dust, human excreta and skin abrasions, since this pathogen is closely associated with nasal secretions of humans (Bremer et al. 2004). The presence of Streptococci, E. coli and Salmonella in the wastewater is an indication of faecal contamination, which is an issue of general concern when untreated wastewater is used for irrigation. A study in El Azouzzia, Morocco, showed that lettuce and parsley (Petroselinum crispum var. neapolitanum) irrigated with untreated wastewater were contaminated with the same serogroups of Salmonella B and C that were identified in the water source (Melloul et al. 2001). It is evident that the particularities of a crop species and its consumption patterns (e.g. lettuce versus carrot, Daucus carota subsp. sativus) largely determine the level of and risk for bacterial transmission to the consumer. A recent Salmonella spp. risk assessment study showed that human infection strongly depends on the type of crop, irrigation method, and most importantly the number of days elapsed between the last irrigation and consumption (Stine et al. 2005). The presence of E. coli on lettuce at Yantala Bas 1, Nogare 2 and Gountou Yena 1 may be due to the application of only partially composted ruminant manure in these gardens which is another possible source of contamination. This application practice is quite common in the UPA of Niamey where farmers broadcast manure on the standing crop. A contamination of lettuce with faecal coliforms originating from poultry manure was previously reported from Accra and Kumasi (Ghana), independently of the type of irrigation water used (Drechsel et al. 2000; Amoah et al. 2005). These reports show that health risk assessments should not be limited to the quality of the irrigation water, but also address alternative pathways of vegetable contamination such as by animal manure and soil splash. Recent studies in Kumasi showed that in the dry season the avoidance of lettuce irrigation with wastewater six days before harvest effectively reduced microbial contamination of this important UPA produce (Keraita et al. 2007). Similar results were reported from Yuma, Arizona, where iceberg lettuce subjected to early termination of irrigation showed reduced microbial counts (Jorge 2006). However, in Niger this measure seems to be inefficient in the wet season, and it might adversely affect the productivity and freshness of vegetables in the dry season, thereby decreasing farmers’ profits. Therefore, an integrated approach targeting all farm-relevant contamination sources apart from irrigation water and manure is required. Further studies should determine the survival conditions of Salmonella spp. and E. coli in the soil and manure stacks under the Sahelian conditions, so as to derive more environmentally safe dung management strategies, thereby reducing health risks for vegetable consumers. The concentrations of Zn, Cu and Ni in all water sources were far below the established threshold values for irrigation water estimated at 2 mg Zn l−1, 0.2 mg Cu l−1 and 0.2 mg Ni l−1 (Pescod 1992) and for vegetables set at 50 mg Zn kg−1 dry weight (DW), 30 mg Cu kg−1 DW and 1.5 mg Ni kg−1 DW (Awashthi 2000). The difference between the low heavy metal concentrations found in our study and the values of 1.3 mg Zn l−1 and 0.7 mg Cu l−1 reported for the same water sources by Graefe et al. (2008) is most likely due to a difference in sampling location. Our samples were collected at the gardeners’ points of water withdrawal for crop irrigation, which were located a few 100 m downstream of the source points used by Graefe et al. (2008), leading to dilution effects. In previous UPA studies crop irrigation with sewage water and industrial effluents, application of municipal solid wastes and lavish pesticide usage have been identified as the main sources for toxic levels of heavy metals, mainly Zn and Ni, on lettuce (171 and 52 mg kg−1 DM), spinach (Spinacia oleracea L., 154 and 69 mg kg−1 DM) and radish (Raphanus sativus L., 139 and 63 mg kg−1 DM), respectively (Awashthi 2000; Binns et al. 2003; Gupta et al. 2008). In Lagos, Nigeria, concentrations of 106 mg Cu kg−1 and 25 mg Ni kg−1 were found in (dried) soil of industrial areas as opposed to 63 mg Cu kg−1 and 13 mg Ni kg−1 in residential areas (Yusuf et al. 2003). Vegetables such as water leaf (Talinum triangulare J.), bush okra (Corchorus olitorus L.), bitter leaf (Vernonia amygdalina L.) and fluted pumpkin (Telfairia occidentalis H.) cultivated in the industrial areas accumulated significantly higher amounts of Cu and Ni than those cultivated in the residential areas (Yusuf et al. 2003). In Titagarh, West Bengal, India, mean concentrations of 1.9 g Zn l−1, 1.6 g Cu l−1 and 0.7 g Ni l−1 were reported for untreated wastewater used for irrigation. These were leading to soil concentrations of 217 mg Zn kg−1, 90 mg Cu kg−1 and 104 mg Ni kg−1 and resulted in subsequent accumulation of these metals in vegetables far beyond recommended threshold values (Gupta et al. 2008). Given the low industrial development of Niamey, the accumulation of metal elements in irrigated vegetables seems at present of only minor concern.
Conclusions
The findings of this study indicate that UPA vegetable and millet production in Niamey are characterized by poor nutrient use and management:
-
(i)
large surpluses of N, P and K were observed in vegetable gardens of low and high input intensity but C balances remain critical and require recycling of manure to maintain soil C levels;
-
(ii)
in peri-urban millet cultivation, surpluses of N (for high and low input fields), P and K (high input fields only) prevailed, however, mining of P and K was shown for low input fields;
-
(iii)
the observed surpluses were derived from a wide range of sources whose contribution varied among sites. In the vegetable gardens, mineral fertilizers accounted for 34–48% of N, 15–80% of P and 2–12% of K inputs. Animal manure contributed 69–79% to the C input, 44–68% to N, 61–73% to P and 48–75% to K. In the millet fields manure contributed significantly to the positive partial nutrient balances and accounted for 13–76% of N, 79–91% of P and 17–65% of K inputs, while root exudates were estimated to contribute 85–99% of the C inputs. Atmospheric deposition contributed mainly to the K input and biological N2-fixation to the N input.
The results of this study suggest that there is a scope for improved nutrient use efficiency and management in Niamey’s UPA systems. To achieve this, strategies that better match nutrient supply to crop demand need to be applied. Pre-treatment of wastewater prior to use for irrigation and application of composted animal dung will contribute to minimize produce contamination, NO3 − leaching and ammonia volatilisation and to enhance food safety, thereby reducing the negative externalities of UPA on the environment and human health.
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Acknowledgements
We are grateful to I. Kadaoré for mapping Niamey’s UPA gardens and fields, and to Dr. A. Ayantunde, Dr. D. Fatondji and M. Diolombi (ICRISAT Sahelian Centre, Niamey, Niger) for scientific advice and logistic support. We also thank the UPA farmers of Niamey for their patience and collaboration and the Deutsche Forschungsgemeinschaft (DFG) for financial support of this study.
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Diogo, R.V.C., Buerkert, A. & Schlecht, E. Horizontal nutrient fluxes and food safety in urban and peri-urban vegetable and millet cultivation of Niamey, Niger. Nutr Cycl Agroecosyst 87, 81–102 (2010). https://doi.org/10.1007/s10705-009-9315-2
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DOI: https://doi.org/10.1007/s10705-009-9315-2