A G R I C U L T U R A L A N D F O O D S C I E N C E E. Brod et al. (2012) 21: 332–347 332 Fertilization effects of organic waste resources and bottom wood ash: results from a pot experiment Eva Brod1,2, Trond Knapp Haraldsen1 and Tor Arvid Breland2 1 Bioforsk – Norwegian Institute for Agricultural and Environmental Research, Fredrik A. Dahls vei 20, 1432, Ås, Norway 2 Norwegian University of Life Sciences, Department of Plant and Environmental Sciences, P.O. Box 5003, 1432, Ås, Norway e-mail: eva.brod@bioforsk.no A pot experiment was conducted to study the fertilization effects of four N- and P-rich organic waste resources alone and in combination with K-rich bottom wood ash at two application rates (150 kg N ha–1 + 120 kg K ha–1, 300 kg N ha-1 + 240 kg K ha–1). Plant-available N was the growth-limiting factor. 48–73% of N applied with meat and bone meal (MBM) and composted fish sludge (CFS) was taken up in aboveground biomass, resulting in mineral fertilizer equivalents (MFE%) of 53–81% for N uptake and 61–104% for yield. MFE% of MBM and CFS decreased for increas- ing application rates. Two industrial composts had weak N fertilization effects and are to be considered as soil con- ditioners rather than fertilizers. Possible P and K fertilization effects of waste resources were masked by the soil’s ability to supply plant-available P and K, but effects on plant-available P and K contents in soil suggest that the waste resources may have positive effects under more nutrient-deficient conditions. Key words: meat and bone meal, fish sludge, compost, nitrogen use efficiency, mineral fertilizer equivalent Introduction Today’s agriculture relies on the application of mineral fertilizers to return plant nutrients to agricultural land. However, global resources of fossil fuel and phosphate rock, raw material for the production of mineral fertilizers, are limited. According to current calculations, economically exploitable P will be exhausted within 50–100 (Cordell et al. 2009) to 300–400 years (van Kauwenbergh 2010), and several investigations suggest that we might already have passed peak oil. In order to ensure food security in the future, we will have to reduce our dependence on mineral fertilizers and to replace linear nutrient flows by nutrient cycles. Returning waste to agricultural land by the application of waste-based fertilizer products is a systemic approach to meeting the challenging task of future food supply. There are many derivatives from the food industry as well as waste products from industry and bioenergy plants that are considered as waste despite considerable contents of valuable plant nutrients. The potential of these by-products as fertilizers in agriculture is still largely unexploited. Meat and bone meal (MBM) is a by-product from industrial slaughtering operations with considerable amounts of N (~8%), P (~5%) and Ca (~10%) (Jeng et al. 2006), making it interesting as fertilizer to agricultural crops. Each year, Norwegian slaughterhouses produce 30000 Mg of low-risk category 3 MBM, containing about 2400 Mg N and 1500 Mg P (Haraldsen et al. 2011b). Assuming N and P fertilization effects of respectively 80% and 50% (Jeng et al. 2004, 2006), Norwegian MBM has the potential to compensate for 1900 Mg N and 750 Mg P, commensurating 2% and 10% of N and P that was applied to Norwegian agricultural land with artificial fertilizers in 2010 (SSB 2011). Previous studies have shown that MBM is a predictable organic N fertilizer with similar fertilization effects as min- eral fertilizers (Salomonsson et al. 1994, 1995, Jeng et al. 2004, 2006, Chen et al. 2011), and that it has a positive effects on the baking performance of wheat (Triticum aestivum L.), as well as on common quality parameters in barley (Hordeum vulgare) and oat (Avena sativa) (Fredriksson et al. 1997, 1998, Chen et al. 2011). Phosphorus in MBM is partly present as organic P in the meat fraction, which can easily be taken up by the plants, but the the largest amount is present as apatite in the bone fraction, requiring H+ to become available to plants and making the P fertilization effect of MBM dependent on soil pH (Jeng et al. 2006, Ylivainio et al. 2008). Due to low N:P ratios (< 2–3, Jeng et al. 2004, 2006, Ylivainio et al. 2008, Jeng and Vagstad 2009), it has previously been recommended that MBM fertilizer rates should be adjusted to the plants’ P demands and to the long term P fertilization effect of the material, rather than to N contents (Jeng et al. 2006). Manuscript received April 2012 A G R I C U L T U R A L A N D F O O D S C I E N C E E. Brod et al. (2012) 21: 332–347 333 Fish sludge is the accumulation of N- and P-rich faeces and feed residues on the ground of hatcheries and fish farms, which is today commonly discharged directly into the sea (Norwegian Ministry of Fisheries and Coastal 2008). Based on the number of Norwegian hatcheries for salmon and trout and their production volume we esti- mated that there were collected around 40000–50000 Mg of fish sludge in 2010. With a dry matter (DM) content of 10% and respectively 4 – 5% N and 2 – 3% P, Norwegian fish sludge contains 200–250 Mg N and 80–150 Mg P. According to previous studies on fertilization effects both untreated and anaerobically treated fish sludge have the potential to result in larger biomass production and N and P uptake in crops than conventional animal manure (Gebauer and Eikebrokk 2006, Uhlig and Haugland 2007). Fish sludge from freshwater hatcheries is better suited as fertilizer than fish sludge originating from seawater fish farms, which can result in sodium (Na) uptake by the crops (Teuber et al. 2005). Treating fish sludge in a composting reactor developed by the company Global Enviro AS produces material that is in its consistency and composition very similar to MBM, and studies of Haraldsen and Krogstad (2011) let assume that fertilization effects of MBM and composted fish sludge (CFS) are comparable. Biomass ashes, residues from thermal combustion activities, are potential Ca, P, K and Mg fertilizers, provided that their heavy metal contents are low (Mozaffari et al. 2002, Haraldsen et al. 2011b, Schiemenz et al. 2011). Still, biomass ashes have so far mainly been considered as liming products (Knapp and Insam 2011). Narrow Ca:K ra- tios (< 3 or less) and high K contents (> 6 g (100g)–1 DM) are the requirements to ashes when used as alternative fertilizer products in order to keep their neutralizing effect in accordance with annual acidification of agricultural soils (Haraldsen et al. 2012). There are large variations in terms of quality of biomass ashes produced by Norwe- gian bioenergy plants and so far there is a lack of knowledge about available material of a quality fulfilling the governmental, regulative (Norwegian Ministry of Agriculture 2003) and agronomic requirements. There are several challenges, which prevent farmers from applying by-products from food-industry and other in- dustrial waste products to agricultural land. Some of the major drawbacks associated with the re-use of waste in agriculture are minimum requirements according to material quality (Norwegian Ministry of Agriculture 2003, §10), energy- and cost-intensive transport of products with low dry matter contents, as well as the challenge of even application of bulky or dusty waste. Moreover, actual fertilization and liming effects of waste products are largely unknown, and NPK ratios in waste material are usually unbalanced in comparison to the plants’ needs (Haraldsen and Krogstad 2011, Haraldsen et al. 2011b). Combining various waste resources potentially overcomes the chal- lenge of unbalanced NPK ratios in waste material. Several studies have already tested the concept of recycled NPK fertilizer based on waste resources and results have been promising. Haraldsen et al. (2011b) found in a pot experiment, where combined waste resources were applied to spring cereals, that fertilization with MBM and bottom wood ash (BWA) can result in significantly larger yields than fertilization with MBM alone, and in yields as large as after fertilization with mineral compound ferti- lizer (Haraldsen et al. 2011b). Haraldsen and Krogstad (2011) combined various N-rich waste resources with BWA in a two-year pot experiment with spring cereals as experimental crops and suggested that BWA has potential P and K fertilization effects if N is in sufficient supply. Pradhan et al. (2010) studied the fertilization effect of hu- man urine combined with wood ash during a field experiment on red beet (Beta vulgaris) and concluded that the waste-based fertilizer combination can increase plant biomass production compared to mineral compound ferti- lizer. Kuba et al. (2008) found that addition of wood ashes to organic waste can improve compost quality and nu- trient balances in the end-product. Still, more research has to be done on the fertilization effects of specific waste resources and their combinations to improve the utilisation of containing nutrients, and to re-close nutrient cycles. The intention of the present study was to contribute to the development of waste-based compound fertilizer products by investigating (i) N use efficiency and (ii) P and K fertilization effects of various waste resources. Since N turned out to be the growth-limiting factor, in the present paper we focus on N fertilization effects of N-rich organic waste resources included in the experiment. Fertilization effects were determined by aboveground bio- mass production and nutrient uptake of Italian ryegrass (Lolium multiflorum var. italicum) in response to fertilizer application and compared with the effects of mineral compound fertilizer. A G R I C U L T U R A L A N D F O O D S C I E N C E E. Brod et al. (2012) 21: 332–347 334 Materials and methods Waste resources Waste resources included in the experiment all originated from industrialized food production or other industry activities and are briefly described in Table 1. Table 1. Description of waste resources. Waste resource Abbreviation Nutrients Description Bottom wood ash BWA K Biomass ash originating from a grate fired boiler system of the company Akershus Energi AS, which is located in Årnes (63°96’N, 10°23’E), Norway. Parent material was timber unfeasible for industrial use and residues from the local mill. Both sources were clean of or had a low contents of heavy metals. Meat and bone meal MBM N and P Stabilized, sanitized and pelletized meat and bone meal originating from the slaughterhouse in Mosvik (63°82’N, 11°01’E), Norway. Composted fish sludge CFS N and P Parent material was a mixture of feed residues and excrements from salmon hatchery of the company Åsen settefisk AS (63°61’N, 11°05’E) in Trøndelag, Norway. After dewatering of the sludge using mechanical filters, the material was composted for 18 h in a reactor developed by the company Global Enviro AS. Neutral Dynea compost Dynea 2009 N Industrial compost. Parent material was based on an effluent containing polymers of urea, melamine and formaldehyde from the international company Dynea ASA, which is located in Lillestrøm (59°96’N, 11°05’E), Norway. The effluent was cleaned through a microbial filter. The N-rich sediment including microbial biomass of the filter was mixed with wood chips before the material was composted in windrows outdoors. Acid Dynea compost Dynea 2004 N Industrial compost with the same parent material as Dynea 2009. During storage polymers of formaldehyde break down to formic acid and lower the pH to around 3.5. Samples of each of the waste resources were analysed before application. pH was determined according to NS 4720 (1979) or NS-EN 13037 (2000). The total contents of P and K as well as of trace elements (Cd, Cr, Cu, Hg, Ni, Pb, Zn) were determined after dissolution with nitric acid (7 M HNO 3 ) according to NS 4770 (1994) by simultane- ous ICP-AES according to NS EN ISO 11885 (2009). Total N contents were determined by the modified Kjeldahl method (EN 13654-1 2001). NO 2 - and NO 3 -N and NH 4 -N were determined after extraction with 2 M KCl (Henrik- sen and Selmer-Olsen 1970, Selmer-Olsen 1971) by a Konelab Aqua 60 analyser. To analyse the content of to- tal organic carbon (TOC), the material was first washed with a 2 M HCl solution to remove any inorganic carbon. Then a crushed sample was burned at 925 °C using a Perkin Elmer 2400 CHN analyser. Readily available P-AL, K-AL, Mg-AL and Ca-AL were determined on ICP-AES after extraction with a solution composed of 0.4 M acetic acid and 0.1 M ammonium lactate (pH 3.75) in a solid-to-solution ratio of 1:20 (w/v) (Egnér et al. 1960). Table 2 summarizes the chemical properties of the waste resources that were applied as fertilizer in the experiment. MBM and CFS had high contents of N and P. N:P ratios were 2 and 4, respectively. BWA was due to its high K content and solubility of the nutrient in ashes considered as potential K fertilizer. BWA also contained some P but plant- availability was assumed to be low according to P-AL analysis. Dynea compost is an N-rich industrial by-product of the industry business Dynea ASA in Lillestrøm, Norway. Even if the annual production is minor, Dynea compost is a valuable local resource and studies on the material were, therefore, included in the experiment. A G R I C U L T U R A L A N D F O O D S C I E N C E E. Brod et al. (2012) 21: 332–347 335 Table 2. Chemical characteristics of waste resources. See Table 1 for explanation of the abbreviations of the waste resources. Parameter, unit BWA MBM CFS Dynea 2009 Dynea 2004 pH 12.0 6.5 5.7 7.3 3.5 DM, g (100g)–1 100 98 86 29 43 Loss on ignition, g (100g)–1 DM 0.23 71 88 66 63 Total N, g (100g)–1 DM 0.1 9.0 6.9 7.3 7.8 C:N ratio 1 5 7 5 5 NH 4 -N, g (100g)–1 DM 0.00046 0.03100 0.25850 0.00887 0.06410 NO 2 - and NO 3 -N, g (100g)–1 DM 0.00036 0.00028 0.00019 0.08400 0.17960 N min (% of total N) 0.81 0.35 3.75 1.27 3.12 Total P, g (100g)–1 DM 1.7 4.5 1.7 0.2 0.3 P-AL, g (100g)–1 DM 0.19 2.00 1.60 0.09 0.06 N:P ratio 0.06 2 4 37 31 N:P-AL ratio 1 5 4 84 130 Total K, g (100g)–1 DM 7.7 n.d. 0.15 n.d. n.d. K-AL, g (100g)–1 DM 6.4 0.3 0.3 0.1 0.0 Mg-AL, g (100g)–1 DM 1.5 0.1 0.3 0.1 0.0 Ca-AL, g (100g)–1 DM 8.6 4.2 2.8 0.8 0.0 DM = dry matter, N min = ammonium-N and nitrate-N, AL = extraction with 0.4 M acetic acid and 0.1 M ammonium lactate, n.d. = not determined. All of the waste resources fulfilled the Norwegian requirements for waste-based fertilizer products. For content of heavy metals in the waste resources see Table 3. MBM was in quality class 0 according the Norwegian regula- tions considering the content of heavy metals in the material. Therefore, there are no restrictions regarding the amount of MBM that could be applied to agricultural land other than the plants’ demands, and that it should not be applied on areas for grazing and production of grass for feeding of production animals unless it is blended with a mixing component, according to the EU by-product ordinance 1774/2002. BWA and CFS were in quality class I, their use on agricultural land would therefore be restricted to 40 Mg DM ha–1 and 10 yr–1. Both Dynea 2009 and Dynea 2004 were in quality class II. Therefore, their use on agricultural land would be restricted to 20 Mg DM ha–1 and 10 yr–1 (Norwegian Ministry of Agriculture 2003, §10 and §27). According to the current legislation on organic farming in Norway (Mattilsynet 2009), the use of MBM and untreated BWA is also allowed on organic agricultural fields. The parent material of CFS is in its consistency and composition similar to animal manure and can, there- fore, be defined as animal manure of fish. The content of heavy metals in CFS was at the same level as Norwegian animal manure from various types of animals (Paulsrud et al. 1997). Table 3. Contents of heavy metals (mg kg–1 dry matter) in waste resources. See Table 1 for explanation of the abbreviations of the waste resources. Parameter BWA MBM CFS Dynea 2009 Dynea 2004 Cd 0.60 0.02 0.40 0.21 0.27 Cr 15.00 1.60 1.70 15.00 16.00 Cu 75.00 8.70 11.00 42.00 59.00 Hg 0.00 0.01 0.01 0.18 0.73 Ni 16.00 1.80 0.53 32.00 22.00 Pb 7.80 1.10 0.35 33.00 31.00 Zn 200.00 99.00 290.00 150.00 84.00 A G R I C U L T U R A L A N D F O O D S C I E N C E E. Brod et al. (2012) 21: 332–347 336 Soil The experimental soil was a sandy loam with large fractions of gravel and organic matter with origin in Kise (60°78’N, 10°81’E) in the municipality Ringsaker in Norway, where rocks are calciferous dolomites and sediments are morainic soils (NGU 2011). Table 4 is an overview over the distribution of the size of soil particles, which was determined according to Elonen (1971). Table 4. Size of soil particles in the experimental soil. Unit Coarse sand Medium sand Fine sand Coarse silt Medium silt Fine silt Clay mm 2–0.6 0.6–0.2 0.2–0.06 0.06–0.02 0.02–0.006 0.006–0.002 <0.002 % 21.4 25.1 11.0 9.4 9.4 6.6 17.1 Table 5 describes the chemical characteristics of the soil used in the experiment, which was taken from an experi- mental field with organic production in 2009. Analyses were conducted in 2009. TOC, P-AL, K-AL, Mg-AL and Ca-AL were determined by the methods as described for the waste resources. K-HNO 3 , an estimate for exchangeable and non-exchangeable K reserves in the soil, was determined after boiling the soil in a 1 HNO 3 solution (Pratt 1965). pH was determined in a soil water suspension of 1:2.5 (v/v). Contents of readily available P-AL were low, contents of readily available K-AL were intermediate and K reserves measured as acid-soluble K-HNO 3 were low (Bioforsk 2003). Low nutrient contents in the soil were supposed to enable the evaluation of NPK fertilization effects of the waste resources. Due to the soil’s origin in calciferous dolomite rocks, it contained considerable amounts of Mg-AL and large amounts of Ca-AL (Landbrukets analysesenter s.a.). The waste resources were not assessed re- garding their contents of Mg and Ca, and adequate amounts in the soil were, therefore, desirable to prevent de- ficiency of Mg and Ca in the plants. Table 5. Chemical characteristics of the experimental soil at the beginning of the experiment (measured in 2009). pH TOC Total N C:N P-AL K-AL K-HNO 3 Mg-AL Ca-AL g (100g)–1 g (100g)–1 mg (100g)–1 mg (100g)–1 mg (100g)–1 mg (100g)–1 mg (100g)–1 6.4–6.5 3.1–3.3 0.27– 0.31 11.3–11.8 2.5–3.0 8.2–8.7 34–38 15–17 284– 304 TOC = total organic carbon, AL = extraction with ammonium lactate, HNO 3 = extraction with nitric acid. In 2009, 2/3 of the soil was used for a pot experiment with Chinese cabbage (Brassica rapa), where different lim- ing strategies were tested, and in 2010 spring wheat (Triticum aestivum) was grown to test the fertilization effect of digestate from biogas plants. In both cases, fertilization was adapted to the plants’ needs and a decrease or in- crease of nutrient contents in the soil was, therefore, not expected. About 1/3 of the soil had been stored under outdoor conditions for the last three years, when we mixed all of the soil thoroughly during set-up of the experi- ment. Possible influences of previous activities were, therefore, evenly distributed on all experimental treatments. The soil was sieved at a mesh width of 4 mm to sort out the gravel before filling of experimental pots. After the experiment had finished, soil samples from all of treatments were taken (0–20 cm). pH, Ca-AL, K-AL, Mg-AL, Na- AL, P-AL, NO 2 - and NO 3 -N and NH 4 -N were determined as described. Experimental design The experiment was conducted outdoors under a transparent, synthetic roof in Ås, Norway (59°39’N, 10°45’E). Kick/Brauckmann pots (7.5 l with a top diameter of 21.5 cm) were randomized side by side on a table where the plants were protected from precipitation but otherwise exposed to daylight and outdoor climate. Due to wind protection on the north and east side of the roof, average temperature was somewhat higher than data for the growing season, which is presented in Table 6. A G R I C U L T U R A L A N D F O O D S C I E N C E E. Brod et al. (2012) 21: 332–347 337 Table 6. Average temperature (°C) for each month compared to the standard reference period (Lippestad 2011). Temperature (°C) 2011 Reference period a May 10.5 10.3 June 15.0 14.8 July 17.0 16.1 August 15.3 14.9 September 12.3 10.6 a Monthly temperature average in the period 1961–1990. The plants were irrigated three times a week. Each pot was watered up and kept at a water level of 0.25–0.35 m3 m–3, which was estimated to represent a water potential between –10 and –100 kPa in the experimental soil. To measure the soil water content a HH2 moisture meter with a Delta-T Devices soil moisture sensor SM 200 was used. The experimental crop was Italian ryegrass (Lolium multiflorum var. italicum cv. ‘Macho’), which commonly clearly responds to fertilization (Frame 1992) being a good indicator of the amount of plant-available nutrients in soils. Hence, it was used to study mineralization rates and fertilization effects of the waste resources by uptake of nu- trients in aboveground biomass. In the field, seed rates of 30–40 kg ha–1 are recommended when Italian ryegrass is sown in pure stand (Lund et al. 2011). In the pot experiment a seed rate of 30 kg ha–1 was chosen. This amount is equivalent to 0.11 g pot–1. The experiment was designed to supply plants with N, P and K similar to that supplied with the compound fer- tilizer Yara Fullgjødsel® 18 – 3 – 15 (minNPK). All of the four N-rich waste resources were tested alone and in com- bination with K-rich BWA. Fertilizer combinations were compared with the effect of minNPK. An unfertilized treat- ment and only calcium nitrate (minN) were included to study the soil’s ability to supply plant nutrients. Addition- ally, there were reference treatments with minN in combination with BWA and BWA alone. Each treatment was tested at two application rates, calculated with respect to the amount of total N (Kjeldahl-N) and total K content (extraction with 7 M HNO 3 ) in N-rich waste and K-rich BWA, respectively. Application rates (150 kg N ha–1 + 120 kg K ha–1 by 300 kg N ha–1 + 240 kg K ha–1) were chosen based on fertilizer recommendations for pastures with three cuts in Norway (Bioforsk 2003), and calculated based on the surface area of the pots. The soil depth was with 20 cm in accordance with the depth of cultivated topsoil. There were three replicates for each treatment. The ex- perimental design is presented in Table 7. Planting took place on 9 May 2011. The upper 5 cm of soil in the pots were removed and fertilizer was applied evenly on the soil together with the seeds. Then the upper soil layer was placed back on top. Hence, seeds were placed deeper than intended, and deeper than commonly recommended for grasses, resulting in delayed germi- nation and reduced biomass production during the first harvest (Table 8). During the first weeks, weeds were re- moved to avoid interplant competition until the experimental crop was fully established. The pots did not receive any further fertilization throughout the summer. Biomass was harvested manually with scissors at a height of 1.5 cm from soil surface on 21 June, 19 July, 17 August and 27 September 2011. For each pot, plant material was dried at 40 °C for one week, and dry matter production was calculated. Chemical analyses were conducted for one pooled sample per treatment. Total N in plant mate- rial was determined by the Dumas method (NS-EN 13654-2 2001). Total tissue concentrations of P, K, Mg, Ca and micronutrients were determined as described for the waste resources. Nutrient uptake (kg ha–1) was computed by multiplying concentration of the pooled samples by the yield of each replication. A G R I C U L T U R A L A N D F O O D S C I E N C E E. Brod et al. (2012) 21: 332–347 338 Table 7. Amount of waste resources applied with contents of mineral N (N min ), total P, P-AL and total K/K-AL as kg ha–1. See Table 1 for explanation of the abbreviations of the waste resources. Application rates 150 kg N ha–1 + 120 kg K ha–1 300 kg N ha–1 + 240 kg K ha–1 Amount N min total P P-AL K/-AL a Amount N min t o t a l P P-AL K/-AL a Treatment BWA 1558 0 26 3 120 3117 0 53 6 240 minNPK 852 150 22 22 124 1705 300 44 44 249 minN 968 150 0 0 0 1935 300 0 0 0 minN + BWA 2526 150 26 3 120 5052 300 53 6 240 MBM 1701 0.5 75 33 5 3401 1 150 67 10 MBM + BWA 3259 0.5 101 36 125 6518 1 203 73 250 CFS 2528 5.6 37 35 7 5056 11 74 70 13 CFS + BWA 4086 5.6 63 38 127 8172 11 127 75 253 Dynea 2009 7110 0.5 4 0 2 14220 1 8 0 4 Dynea 2009 + BWA 8668 0.5 31 3 122 17337 1 61 6 244 Dynea 2004 4495 4.7 6 1 0 8991 9 12 2 0 Dynea 2004 + BWA 6054 4.7 32 4 120 12107 9 65 8 240 a K in BWA was calculated based on total K. K in other material is based on K-AL. AL = extraction with 0.4 M acetic acid and 0.1 M ammonium lactate. Data analysis Nitrogen use efficiency (NUE%, Salomonsson et al. 1994, 1995, Jeng et al. 2004) was calculated as follows: (1) where NUE = N use efficiency N up = N in aboveground biomass as sum of all four harvests (kg N ha–1) c = unfertilized control treatment N applied = Total N amount applied with fertilizer treatment Mineral fertilizer equivalent (MFE%, Delin 2011), which is defined as the application rate of mineral fertilizer N (kg N ha–1) to which the fertilization effect of organic waste on yield or N uptake (Y) is equivalent, expressed as per- centage of total N applied, was calculated as follows: (2) where MFE = mineral fertilizer equivalent X tot = 150 or 300 kg N ha–1 (3) Y 1 = yield or N uptake obtained with waste resource a and b are slope and intercept obtained from linear regression by the minimum least squares method of yield or N uptake (Y) obtained with mineral fertilizer (minNPK) on mineral N application rate (X = 0, 150 and 300 kg N ha–1, respectively). Multiple comparisons between treatments were statistically performed by one-way analysis of variance (ANOVA) including all treatments. Tukey’s studentized range test was applied with a significance level of p ≤ 0.05. The pro- gram package SAS/STAT (SAS Institute Inc. 1989) was used for the statistical analysis. NUE (%) = 100 × [Nup– Nup(c)] Napplied X1 = (Y1 – b) / a MFE% = 100 × X1 / Xtot A G R I C U L T U R A L A N D F O O D S C I E N C E E. Brod et al. (2012) 21: 332–347 339 Results Effects of fertilizer treatments on biomass production The highest fertilizer rates of minNPK and minN treatments resulted in the largest total yields (Table 8). The re- gression of yield (Y) on mineral N application rate (X) gave the following response function: Y = 24.46X + 2157.95 (R2=0.98). Table 8. Mean (n=3) biomass production (kg ha–1) as influenced by the fertilizer treatments. See Table 1 for explanation of the abbreviations of the waste resources. Treatment Amount applied 1st harvest 2nd harvest 3rd harvest 4th harvest Total Control 0 489 877 445 146 1958 BWA 150 593 1068 552 326 2539 300 451 1387 628 329 2795 minNPK 150 669 3355 1722 482 6228 300 716 4796 2911 872 9295 minN 150 401 2556 2407 673 6038 300 268 2370 4403 1839 8879 minN + BWA 150 490 3095 2271 431 6287 300 231 2073 3960 1994 8258 MBM 150 549 2882 1353 621 5405 300 354 3062 2570 837 6823 MBM + BWA 150 558 3178 1510 720 5966 300 544 3552 1886 665 6647 CFS 150 717 2795 1146 680 5338 300 713 3396 1801 930 6840 CFS + BWA 150 713 2794 1104 656 5266 300 553 3621 2059 991 7224 Dynea 2009 150 409 1285 617 391 2701 300 492 1116 578 388 2574 Dynea 2009 + BWA 150 490 876 421 315 2103 300 381 1250 647 450 2728 Dynea 2004 150 452 1789 733 445 3418 300 428 2096 1023 479 4026 Dynea 2004 + BWA 150 441 1931 813 454 3638 300 320 2034 960 442 3755 MSD a , p ≤ 0.05 455 1242 1076 555 1965 a MSD = minimum significant difference. Application of MBM and CFS resulted in similar biomass production. All in all, total yields were smaller after MBM and CFS fertilization than after mineral fertilizer treatments of the same N amount, but differences were only signif- icant for the higher rates (300 kg N ha–1). According to calculations of MFE% for yield (Table 9) MBM and CFS could respectively achieve 89–104% and 85–97% of the total yield of 150 kg N ha–1 minNPK and 61–64% and 64–69% after fertilization with the total yield of 300 kg N ha–1 minNPK. Among Dynea compost treatments, only the effect of 300 kg N ha–1 Dynea 2004 was significantly different from the unfertilized control treatment. Dynea 2009 and 2004 compensated for up to 15% and for 34–40% of the total yield after fertilization with 150 kg N ha–1 minNPK and for 6–8% and 22–25% of the total yield after fertilization with 300 kg N ha–1 minNPK (Table 9). Dynea 2004 re- sulted generally in larger yields than Dynea 2009, but differences between effects of the two compost types were not significant. Application of BWA alone resulted in equally small yield as the unfertilized control reference and there was no significant effect of BWA in combination with minN or N-rich waste resources on biomass produc- tion in comparison to the same treatment without BWA. A G R I C U L T U R A L A N D F O O D S C I E N C E E. Brod et al. (2012) 21: 332–347 340 At the first harvest, yields were very small (Table 8). However, despite poor establishment there was no need of reseeding, as reduced germination was compensated by tillering. Especially minN treatments resulted in poor es- tablishment and 300 kg N ha–1 minN + BWA gave the smallest yield. 150 kg N ha–1 CFS without BWA and 300 kg N ha–1 minNPK resulted in the largest yields, but their effects were only significantly different from the poorly es- tablished minN + BWA (300 kg N ha–1) treatment. During the second harvest, 300 kg N ha–1 minNPK treatments resulted in significantly larger biomass than all other treatments except for 300 kg N ha–1 CFS + BWA. MinN treat- ments of the lowest application rate (150 kg N ha–1) resulted in biomass production at the same level as all MBM and CFS treatments, and 300 kg N ha–1 minN treatments tended to result in smaller yields than lower application rates (150 kg N ha–1). At times of the third harvest, plants that had been fertilized with minN, were well developed and 300 kg N ha–1 minN treatments resulted in the largest yields among all treatments. There were no significant differences between effects of minNPK, MBM and CFS treatments of the same application rate. At the fourth har- vest, yields were again small in general. Biomass production after fertilization with 300 kg N ha–1 minN was sig- nificantly different from all other treatments (Table 8). Effects of fertilizer treatments on N in plant biomass and soil N uptake of unfertilized plants indicated that about 39 kg N ha–1 was directly plant-available from the experimen- tal soil. Plants utilized 86–107% of N applied with minNPK and minN (NUE%, Fig. 1). After MBM and CFS fertiliza- tion, respectively, plants utilized 49–73% and 48–50% of N applied. After MBM and CFS fertilization, plants took up less N than after mineral fertilizer treatments of the same N amount, but differences were only significant for 300 kg N ha–1 treatments. None of the Dynea compost treatments was significantly different from the unfertilized control treatment regarding N uptake in biomass. Plants took up 3–11% of N applied with Dynea 2009 and 16–28% of N applied with Dynea 2004 (NUE%, Fig. 1). The regression of N uptake (Y) on mineral N application rate (X) gave the following response function: Y = 0.92X + 36.21 (R2=0.98). MFE% for N uptake showed that MBM and CFS, could, respectively, compensate for 76–81% and 65–67% of N uptake after fertilization with 150 kg N ha–1 minNPK, and for 54–65% and 53–56% after fertiliza- tion with 300 kg N ha–1 minNPK. Dynea composts could compensate for 5–32% of N uptake after fertilization with 150 kg N ha–1 minNPK, and for 7–19% after fertilization with 300 kg N ha–1 minNPK (MFE% for N uptake, Table 9). Fig. 1. Total N uptake in plant biomass (kg N ha–1) as influenced by fertilizer treatments (150 kg N ha–1 + 120 kg K ha–1, 300 kg N ha–1 + 240 kg K ha–1). Percentages refer to NUE (%). Means followed by the same letter are not statistically different. See Table 1 for explanation of the abbreviations of the waste resources, C = unfertilized control treatment. A G R I C U L T U R A L A N D F O O D S C I E N C E E. Brod et al. (2012) 21: 332–347 341 43 days after MBM and CFS fertilization (first harvest), 5–13% of the N harvested during the entire experimentalp- eriod was present in aboveground biomass, and 71 days after MBM and CFS fertilization (second harvest) 50–67% of the N harvested during the entire experimental period was present in aboveground biomass. 100 days after MBM and CFS fertilization (third harvest) 86–89% of totally harvested N was taken up in aboveground biomass. Analyses of soil samples that were taken at the last day of the experiment suggested that practically all plant- available N was taken up by the plants. There were no significant differences between the treatments regarding residual mineral N in the soil. The minimum significant difference was 0.2 mg (100g)–1 soil for NH 4 -N and NO 2 - and NO 3 -N measurements, respectively. Assuming soil density of 1.2 g cm–3 and soil depth of 20 cm, there was around 10 kg ha–1 of mineral N left in the soil on the day of the last harvest (results not shown). Table 9. Mineral fertilizer equivalents (MFE%) of organic waste resources for yield and N uptake. See Table 1 for explanation of the abbreviations of the waste resources. Application rates 150 kg N ha–1 + 120 kg K ha–1 300 kg N ha–1 + 240 kg K ha–1 Treatment Yield N uptake Yield N uptake MBM 89 76 64 65 MBM + BWA 104 81 61 54 CFS 87 67 64 53 CFS + BWA 85 65 69 56 Dynea 2009 15 14 6 7 Dynea 2009 + BWA –2 5 8 7 Dynea 2004 34 30 25 19 Dynea 2004 + BWA 40 32 22 18 Effects of fertilizer treatments on P and K in plant biomass and soil There were no significant differences in P uptake as kg P ha–1 after fertilization with minNPK or MBM and CFS at any rate. Overall, utilization of fertilized P tended to be best after CFS application, which resulted in the highest P uptake for all rates and combinations but there were no significant differences to minNPK and MBM fertilization (Table 10). MinN fertilization resulted in fairly low P concentration in plant biomass, especially during the first two harvests (results are not shown). However, there were no significant differences between total P uptake as kg P ha–1 after fertilization with minN and minNPK. All MBM treatments and 300 kg N ha–1 CFS and CFS + BWA resulted in significant effects on P-AL values in the soil in comparison to the unfertilized control treatment. All MBM treatments except for 150 kg N ha–1 MBM increased P-AL in the soil from low to high values according to Norwegian classifications (Krogstad et al. 2008). Also BWA tended to increase P-AL values in the soil, but significant effects on P-AL values in the soil were only found for 150 kg N ha–1 MBM and 300 kg N ha–1 CFS, when treatments with and without BWA were compared (Table 10). All plants were sufficiently supplied with K and there were no significant effects of BWA on K uptake as kg K ha–1 compared to the same treatments without BWA. The amount of plant-available K in the soil measured as K-AL de- creased after all treatments in the course of the experiment. BWA application tended to result in larger amounts of plant-available K (K-AL) in the soil compared to the same treatments without BWA, and BWA treatments of both rates (120 and 240 kg K ha–1) were significantly different from the unfertilized control regarding K-AL con- tents in the soil (Table 10). A G R I C U L T U R A L A N D F O O D S C I E N C E E. Brod et al. (2012) 21: 332–347 342 Table 10. Uptake of total P and K in plant biomass (kg ha–1) and effects of fertilizer treatments on contents of P-AL and K-AL [mg (100g)–1soil] and pH. See Table 1 for explanation of the abbreviations of the waste resources. Application rates 150 kg N ha–1 + 120 kg K ha–1 300 kg N ha–1 + 240 kg K ha–1 P K P-AL K-AL pH P K P-AL K-AL pH kg ha–1 kg ha–1 mg (100g)–1 soil mg (100g)–1 soil kg ha–1 kg ha–1 mg (100g)–1 soil mg (100g)–1 soil Treatment Control 7 79 3 3 6.7 7 79 3 3 BWA 9 106 5 7 6.8 9 114 5 8 6.8 minNPK 16 258 3 4 6.5 23 412 4 4 6.3 minN 14 254 3 4 6.8 18 317 3 4 6.6 minN + BWA 15 290 4 5 7.0 19 350 4 6 6.9 MBM 15 230 7 4 6.7 19 265 11 4 6.4 MBM + BWA 17 259 12 6 6.8 18 282 13 6 6.8 CFS 18 227 4 4 6.6 24 255 6 3 6.4 CFS + BWA 19 240 6 5 6.8 24 315 10 9 6.7 Dynea 2009 9 110 3 3 6.7 9 112 3 3 6.5 Dynea 2009 + BWA 8 90 4 6 6.8 9 114 4 7 6.6 Dynea 2004 11 146 3 3 6.6 12 160 3 4 6.4 Dynea 2004 + BWA 11 155 4 6 6.8 11 166 5 7 6.7 MSD a, p ≤ 0.05 6 85 3 3 0.5 6 85 3 3 0.5 a MSD = minimum significant difference. Effects of fertilizer treatments on soil pH Overall, there were only minor effects of fertilizer treatments on soil pH as result of buffering reactions in the ex- perimental soil, which were due to relatively high concentrations of organic material and relatively high clay con- tent (Table 4, Table 5). BWA fertilization tended to result in higher pH values than the unfertilized control and all fertilizer combinations with BWA showed a tendency of higher soil pH than equivalent fertilizer treatments with- out BWA but effects were not significant. Discussion Nitrogen use efficiency and mineral fertilizer equivalents of organic waste resources N uptake in aboveground biomass (NUE%) after MBM (49–73%) and CFS (48–59%) fertilization and N mineraliza- tion over time were similar to results of previous studies on mineralization dynamics of MBM. Delin and Engström (2010) concluded after incubation studies with various organic waste resources under Swedish field conditions that 65% of N applied with MBM can be released within 30–50 days and that N mineralization is flattening out thereafter. Also reduced biomass production at times of the fourth harvest during the present experiment (Table 8) can be explained by decreasing N mineralization of MBM and CFS with time, as indicated by negligible con- tents of residual mineral N in the soil at the last day of the experiment. Mondini et al. (2008) studied mineraliza- tion dynamics of MBM under laboratory conditions for 14 days and found that 50% of N applied with MBM was mineralized within the course of the experiment. Consequently, scarce biomass production at the first harvest of the present experiment (Table 8) was surprising, also because ryegrass is commonly characterized by early plant development (Fustec et al. 2005). However, it was probably too deep placement of seeds that resulted in delayed germination and initial growth, rather than of a lack of mineralized N. Total net-mineralization of N applied with MBM and CFS was higher than NUE% let assume, as N uptake in root biomass was not taken into account for the calculation of NUE%. A G R I C U L T U R A L A N D F O O D S C I E N C E E. Brod et al. (2012) 21: 332–347 343 Relative N replacement values of MBM and CFS (MFE% for N uptake, Table 9) are well in accordance with studies of Delin et al. (2011), who investigated fertilization effects of MBM during two pot experiments with Italian rye- grass, and somewhat lower than equivalent values calculated based on previous studies that compared N uptake in grain after fertilization with MBM or CFS with mineral N fertilization (76% in Salomonsson et al. 1995, 91% in Jeng et al. 2004, 71–124% in Chen et al. 2011, 80–90% in Haraldsen et al. 2011a). Lower MFE% for N uptake of MBM and CFS in the present study can be explained by the experimental design, which intentionally avoided de- nitrification and N leaching losses. Irrigation was adapted to the specific soil characteristics so that denitrification losses were reduced and closed plant–soil systems set up by Kick/Brauckman pots prevented nitrate from leach- ing to deeper soil layers. All of the studies with cereals as experimental crops referred to were conducted under field conditions or as pot experiments with an intended leaching episode. According to studies by Haraldsen et al. (2011a) and Haraldsen and Krogstad (2011) N-rich waste is less prone to nitrate leaching than mineral N fertilizer. Consequently, we may assume that immediately soluble mineral fertilizers would have come out less favourable in comparison to organic waste resources, if leaching had occurred. MFE% for yield tended to be higher than MFE% for N uptake, indicating that MBM and CFS have the potential to result in almost equally large yield as mineral fertilizers, but in lower N concentration. If MBM or CFS is applied as fertilizer to cereals, lower N concentration might result in lower grain quality. This assumption is, however, not in accordance with previous studies by Salmonsson (1994, 1995), Fredriksson et al. (1997, 1998) and Chen et al. (2011) who found equally good quality parameters of cereals after fertilization with MBM as after the mineral reference treatment during field experiments. It has to be taken into account that high MFE% values can only be achieved, if N release matches with the crops’ demands in time. In cereal production the time for N recovery is much shorter than the duration of the present experiment, where ryegrass was used as a method to study nutrient supply over time. If MBM or CFS is used as fertilizer to cereals, N will have to be mineralized before ear emergence, as cereal plants mainly utilize nutrients from their own vegetative reserves after this physiological stage (Spiertz and de Vos 1983). In Norway, grain is harvested 100–120 days after sowing, at a time when only 86–89% of total N taken up in plants after MBM and CFS fertilization was taken up by ryegrass during present experiment. MFE% of MBM and CFS might therefore be clearly lower than presented in the present study, if applied as alternative N fertilizer to cereals. Relationship between fertilizer amount and N fertilization effect The effects of the highest application rates of MBM and CFS (300 kg N ha–1) on plant biomass were significantly different from effects of mineral fertilizer treatments of the same rate, which was puzzling because of equally good effects of the lowest rates (150 kg N ha–1) (Table 8). Decreasing effectiveness of organic fertilizers for increas- ing amounts is known from application of manure to agricultural land (Bioforsk 2003), and has moreover earlier been described by Boen and Haraldsen (2011) after application of increasing amounts of composted biowaste to perennial ryegrass (Lolium perenne) as well as by Trøite (2007) after studies on different organic fertilizers in a pot experiment with barley and by Kristoffersen et al. (2012) after application of increasing amounts of liquid residues from biogas production to barley. Likewise, Delin and Engström (2010) found reduced mineralization after incuba- tion of larger amounts of various organic waste types. A possible explanation for reduced fertilization effects of 300 kg N ha–1 MBM and CFS in comparison to 150 kg N ha–1 is a lack of oxygen when microbial activity increased with increasing amounts of organic material. Application of organic material can considerably reduce oxygen availability in the soil atmosphere with associated negative effects on plant and root growth as shown by Hossain et al. (2005) who studied the composition of soil gases af- ter application of increasing amounts of manure. Delin and Engström (2010) suggested that reduced net-N min- eralization of larger amounts of organic material could be explained by denitrification of mineralized N as result of anaerobic conditions due to increased microbial oxygen consumption. Another possible explanation for decreasing fertilizer efficiency for organic waste resources at higher rates are phy- totoxic effects of fatty acids, which might have accumulated when organic material was degraded under oxygen depleted conditions. Fatty acids are known to have harmful effects on germination and seedling root and shoot development (Schuman and McCalla 1976), and an accumulation after fertilization with 300 kg N ha–1 MBM and CFS might therefore have resulted in decreased nutrient uptake. Oxygen deficiency and phytotoxic effects of fatty acids as result of MBM and CFS treatments might have had a particularly strong effect on biomass production during the present experiment as fertilizers were not evenly A G R I C U L T U R A L A N D F O O D S C I E N C E E. Brod et al. (2012) 21: 332–347 344 distributed in the soil, but concentrated at a depth of 5 cm in the same layer as the seeds. In similar studies on effects of organic fertilizers, the material had been mixed into the top layer to simulate even distribution by har- rowing (Haraldsen et al. 2011a) or into the entire soil volume similar to incorporation by ploughing (Boen and Haraldsen 2011). However, neither oxygen supply nor the development of fatty acids was measured in the pres- ent experiment and their effects remain therefore assumptions. N fertilization effects of Dynea composts Dynea composts showed reduced N fertilization effects for all rates and combinations resulting in small biomass production throughout the season (Fig. 1, Table 8). This indicates that organic N in Dynea composts was rather re- calcitrant. Slow N mineralization is typical for mature compost material (Amlinger et al. 2003, Bar-Tal et al. 2004, Boen and Haraldsen 2011) irrespective of its C:N ratio, as carbon in compost is of low availability and hence not well suited as source of energy to soil microorganisms. Asdal and Breland (2003) even suggested that mature com- post material releases mineral N so slowly that the amount of inorganic N probably is almost equivalent to plant- available N during a growing season. N in Dynea composts was mainly present as polymers of urea, melamine and formaldehyde. Although Dynea composts originated from industrial processes, net-N mineralization of these composts seemed to be at the same level as net-mineralization of mature composts based on biological organic waste materials. Based on analyses of chemical properties prior to the experiment 0.5–1 kg mineral N ha–1 and 4.7–9 kg mineral N ha–1 were applied with Dynea 2009 and Dynea 2004, respectively (Table 7). Obviously these amounts were far from sufficient to supply plants with N. Better fertilization effects of the older material can pos- sibly be explained by larger initial amounts of mineral N in Dynea 2004 compared with Dynea 2009. The results suggest that Dynea composts can generally be applied in relatively large amounts without intensive effects on plant growth. Therefore, they are rather to be classified as soil conditioners with potentially positive effects on physical, chemical or biological soil characteristics than as fertilizers, which are defined as products with the key task of supplying plants with nutrients (Norwegian Ministry of Agriculture 2003, appendix 1). P fertilization effects of waste resources Even though initial contents of plant-available P in the soil were estimated to be low (P-AL, Table 5, Krogstad et al. 2008), the soil still supplied plants with sufficient P. Therefore, P fertilization effects of waste residues did not become visible in biomass production or as P uptake during the present experiment. Sufficient P uptake despite low soil P contents can be explained by grasses being fairly tolerant to low P availability in soils in comparison to other crops (Caradus 1980) and by Italian ryegrass being adapted to P deficient conditions due to fast root devel- opment (Kemp and Blair 1994). Even plants fertilized with minN with initially low P concentration in plant tissue, achieved total yields at the same level as plants fertilized with minNPK. Delayed biomass production initiated by initial P deficiency after minN fertilization could be compensated due to the closed plant-soil system set up by Kick-Brauckmann pots, which prevented nitrate-N from leaching. Under field conditions nitrate-N would probably already have been lost by the time when plants were sufficiently supplied with P. CFS tended to result in higher P uptake than MBM, even though larger total P amounts were applied with MBM (Table 7, Table 10). This is in agreement with studies of Haraldsen and Krogstad (2011) who found significantly higher P uptake by wheat after fertilization with CFS of codfish hatcheries than after MBM amendments of the same origin as in the present study. It seems, therefore, as if CFS-P is better available to plants than MBM-P, and that P fertilization effects of CFS are independent of pH, whereas MBM-P apparently is more soluble in acidic than in neutral or alkaline soils (Jeng et al. 2006, Ylivainio et al. 2008). Surprisingly, MBM fertilization resulted in an amount of soluble P in the plant-soil system (P-AL in the soil and P taken up by plants) that was higher than total P applied with the material (Table 7, Table 10). Similar effects of MBM on plant-available P measured as P-AL were observed by Haraldsen et al. (2011a), when MBM was applied to barley. According to findings of present and previous studies, one has to question if P-AL analysis is suited as indicator for P fertilization effects of MBM. The present investigation indicated a need for more thorough studies on the actual P fertilization effect of MBM, and evaluations of the P-AL method as indicator for P availability in different types of organic wastes applied as P fertilizer. A G R I C U L T U R A L A N D F O O D S C I E N C E E. Brod et al. (2012) 21: 332–347 345 K fertilization effect of bottom wood ash K fertilization effects of BWA were hidden by the soil’s ability to supply plant-available K. This is in accordance with studies of Øgaard et al. (2002), who found no yield response of plants on K fertilizers when soil K exceeded 8 mg K-AL (100g)–1. The amount of plant-available K in the experimental soil measured as K-AL was between 8.2 and 8.7 mg K-AL (100g)–1 and, therefore, high enough to result in luxury K uptake in ryegrass even after applica- tion of minN, which supplied plants with sufficient N but no K. Even though K fertilization effects of BWA were not evident as biomass production or uptake in plant biomass, K-AL values in the soil indicated potential fertiliza- tion effects (Table 10). Also Ferreiro et al. (2011) observed an increase of K contents in the soils of mountain pas- tures after fertilization with wood ashes. Therefore it is likely that BWA has a long-term K fertilization effect when K contents in the soil are depleted. As BWA from Akershus Energi AS did not significantly increase soil pH (Table 10), it seems to be well suited for annual application to agricultural land and hence as ingredient in waste-based NPK fertilizer products. To detect P and K fertilization effects of respective MBM, CFS and BWA, long-term experiments should be con- ducted, which guarantee sufficient supply of N and all other essential nutrients except the one to be studied. Conclusion Mineral N was the growth-limiting factor in the current experiment and fertilization effects of organic waste re- sources were therefore determined by their net-mineralization rate. 48–73% of N applied with meat and bone meal and composted fish sludge was taken up in aboveground biomass, resulting in mineral fertilizer equivalents of 53–81% for N uptake and 61–104% for yield. Decreasing mineral fertilizer equivalents for increasing fertilizer rates were most likely caused mainly by unintended concentrated application of organic waste resources. Meat and bone meal and composted fish sludge represent valuable alternative N fertilizers and potential ingredients in waste-based NPK fertilizer products, provided that they are included in crop rotations with N-fixing legumes or that their N-fertilization value is enriched with mineral N. Dynea composts were characterized by weak N fertil- ization effects, as is typical for mature compost material, and are thus to be classified as soil conditioners rather than fertilizers. Possible P and K fertilization effects of waste resources were masked by the soil’s ability to pro- vide plant-available P and K, but effects of waste resources on plant-available P and K contents in soil suggest that plant growth responses may be expected under more P- and K-deficient conditions. Acknowledgements The experiment, which this paper is based on, was carried out as part of CenBio WP 1.4, Bioenergy Innovation Centre (http://www.cenbio.no), which is supported by the Research Council of Norway, Norsk Protein AS and Ak- ershus Energi AS. Moreover, the project was financially supported by Dynea ASA. 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Fertilization effects of organic waste resources and bottom woodash: results from a pot experiment Introduction Materials and methods Waste resources Soil Experimental design Data analysis Results Effects of fertilizer treatments on biomass production Effects of fertilizer treatments on N in plant biomass and soil Effects of fertilizer treatments on P and K in plant biomass and soil Effects of fertilizer treatments on soil pH Discussion Nitrogen use efficiency and mineral fertilizer equivalents of organic waste resources Relationship between fertilizer amount and N fertilization effect N fertilization effects of Dynea composts P fertilization effects of waste resources K fertilization effect of bottom wood ash Conclusion Acknowledgements References