{"refrec":{"BRefID":99471,"RR":"<b>Muendo, P.N.</b> (2006). The role of fish ponds in the nutrient dynamics of mixed farming systems. PhD Thesis. Universiteit Wageningen: Wageningen. ISBN 90-8504-459-6. 120 pp.","BEntID":94731,"PublicFlag":1,"CheckedFlag":0,"wosflag":null,"vabbflag":null,"RefStringPartII":". PhD Thesis. Universiteit Wageningen: Wageningen. ISBN 90-8504-459-6. 120 pp.","DocTypID":5,"DocType":"Book/Monograph","MarineFlag":0,"FreshFlag":0,"BrackishFlag":0,"TerrestrialFlag":0,"Authorstring":"Muendo, P.N.","OrigTitleTranslFlag":0,"Authorstringtrunc":"Muendo, P.N.","Englishabstract":"Rapid population growth in developing countries has resulted in increased demand for food, leading to increased pressure to extend land under cultivation and to intensify food production. Because most of the arable land has already been utilized, further intensification of agricultural production has involved conversion of marginal lands such as forest reserves, communal grazing lands and fragile areas such as river banks and steep hill slopes. Intensified crop production on marginal lands enhances the risk for soil degradation, like soil fertility decline. In many situations, inorganic fertilizers are not available or are too expensive, and efficient utilization of organ~residues such as crop residues and manures is constrained by a temporal mismatch between availability and application. Diversification of farming activities potentially increases nutrient efficiencies. One promising additional activity is aquaculture and the development of integrated aquaculture - agriculture (IAA) systems. Although integrated aquaculture - agriculture farming systems have been developed and practiced in some parts of Asia, they have not been widely adopted. In many developing countries, especially in Africa, aquaculture itself is still poorly developed. Aquaculture is considered separately from agriculture and its benefits are measured in terms of fish production, ignoring its role in nutrient cycling through integrated farming systems. Yet, the majority of nutrients entering ponds, including fertilizers, feeds and nutrients contained in inflows from channels or run-off from watersheds, accumulate in the sediment. These nutrients are a potential nutrient source for terrestrial agriculture. This thesis explored the use of fish ponds as nutrient traps (besides fish production) to increase the nutrient use efficiency in mixed farming systems. Focus was put on (i) nutrient utilization efficiency of agricultural by-products such as crop residues and animal manure in aquaculture production, and(ii) in quantitative aspects of sediment and nutrient accumulation in aquaculture ponds, and pond sediments' potential as a fertilizer in landbased agriculture In chapter 2, aquaculture components were ideotyped for existing agricultural farming systems and benefits from resultant ideotyped integrated aquaculture - agriculture (IAA) farming systems were evaluated and quantified. The results showed that integration of an aquaculture component in agricultural farming systems provided the opportunity to recycle eroded nutrients. In addition, aquaculture provided an opportunity to utilize nutrients from agricultural by-products otherwise lost through leaching during storage. As the majority of nutrients added to ponds accumulate in the sediment, nutrients are stored for later use. In different agro-ecological zones of the Kenyan highlands this practice reduced soil fertility decline by 23 - 35%, increased agricultural production by 2 - 26% and raised the overall farm food productionby 22 - 70%.The results indicatedthat there may be more benefits from pond sediment utilization than fish production alone and also demonstrated that integration of aquaculture is not a threat to agricultural production. The nutrient storage capacity of ponds and the linked increase in productivity largely compensates for the small loss in land surface for crop production. In chapter 3, the nutrient utilization efficiency of agricultural by-products in fish ponds was investigated and compared to that of supplemental foods. Using multivariate analyses, the trophic pathways in organically fertilized and feed driven semi-intensive culture environments were explored. By ANOVA models, water quality, sediment quality and tilapia growth and yields in the two environments were also compared. In both environments, a phytoplankton based food web dominated, and fish nutrition in both environments was mainly based on natural foods. Extrapolated fish yield data indicated that with equal nutrient i","AbstractOtherLang":"De toenemende bevolkingsgroei in ontwikkelingslanden gaat gepaard met een grotere vraag naar voedsel dat vervolgens leidt tot een groeiende vraag naar de uitbreiding van het areaal landbouwgronden en een intensivering van de voedselproductie. Omdat het meeste, voor landbouw geschikte, land reeds in gebruik is, heeft de uitbreiding van de agrarische productie tot gevolg gehad dat marginale gebieden (bosreservaten, gemeenschappelijke graaslandschappen en kwetsbare gebieden zoals rivieroevers en steile heuvelhellingen) zijn omgevormd tot landbouwgrond. Intensieve landbouw op aangrenzende stukken land vergroot het risico op bodemdegradatie, zoals het verminderen van de bodemvruchtbaarheid. In veel gevallen is anorganische mest niet beschikbaar of te duur, en efficiënt gebruik van organische residuen zoals gewasresten en mest is beperkt doordat de beschikbaarheid en het gebruik ervan niet gelijktijdig plaatsvindt. De diversificatie van de lanbouwsystemen kan mogelijk de nutrientenefficientie vergroten. Een veelbelovende aanvullende activiteit is visteelt m.n. in combinatie met grondgebonden landbouw en veeteelt. Hoewel geïntegreerde landbouw-visteelt systemen al zijn ontwikkeld en worden toegepast in sommige delen van Azie, worden ze nog niet wijdverspreid toegepast. In veel ontwikkelingslanden, en met name in Afrika, is visteelt zelf nog maar nauwelijks ontwikkeld. Visteelt vindt vaak onafhankelijk van de landbouw plaats in gespecialiseerde bedrijfssystemen. De voordelen van visteelt worden gemeten in termen van visproductie en de rol van visteelt in het recyclen van nutrienten door geïntegreerde systemen wordt daarmee verwaarloosd. De meerderheid van de nutrienten die de vijvers binnenkomt, inclusief mest, voedsel en nutrienten in de toevoer van kanalen en afvloei water van waterkeerpunten, hopen op in het sediment. Deze nutriënten zijn een potentiële bron van nutriënten voor de landbouwsystemen. Dit proefschrift onderzocht het gebruik van visvijvers als \"nutriënten val\" (naast visproductie) om de efficiëntie van het nutriëntengebruik in gemengde bedrijfssystemen te verhogen. Nadruk werd gelegd op (i) de efficiëntie van nutriëntengebruik van bijproducten uit de landbouw zoals gewasresiduen en dierlijke mest in visteelt productie, en (ii) de kwantitatieve aspecten van sediment- en nutrientenophoping in kweekvijvers en de potentie van het vijversediment als meststof in de landbouw. In hoofdstuk 2 zijn onderdelen van visteelt getypeerd voor bestaande landbouwkundige teeltsystemen. Voordelen van resulterende getypeerde geïntegreerde visteelt - landbouw (IAA) teeltsystemen zijn geevalueerd en gekwantificeerd. De resultaten lieten zien dat integratie van een visteelt component in landbouwsystemen de gelegenheid biedt om geërodeerde nutriënten te recyclen. Bovendien konden door visteelt nutriënten van bijproducten van de landbouw gebruikt worden die anders verloren waren gegaan door verliezen tijdens opslag. Aangezien de meerderheid van de toegevoegde nutriënten aan vijvers accumuleren in het sediment, worden de nutriënten opgeslagen voor later gebruik. In verschillende agro-ecologische zones van de Keniaanse hooglanden verminderden deze geïntegreerde systemen de verliezen in bodemvruchtbaarheid met 23-35%, verhoogden ze de landbouwproductie met 2-26% en verhoogden ze de algemene voedselproductie met 22-70%. De resultaten geven aan dat er meer voordelen zijn van het gebruik van vijversediment dan visproductie en lieten ook zien dat integratie van viskweek geen bedreiging is voor landbouwproductie. De nutriëntenopslagcapaciteit van vijvers en de daarmee verbonden verhoging in productiviteit compenseert in hoge mate voor de kleine verliezen in landoppervlakte voor gewasproductie. In hoofdstuk 3 is de efficiëntie van het nutriëntenverbruik van landbouwkundige bijproducten in visvijvers onderzocht en vergeleken met dat van supplementenvoeders. Gebruikmakend van multivariate analyse is het nutriëntenweb in organisch bemeste en voedselgedreve","BibLvlCode":"M","StandardTitle":"The role of fish ponds in the nutrient dynamics of mixed farming systems","OrigTitleLangCode":"en","OrigTitleLangCodeExtended":"eng","OrigTitleLangID":15,"DateLastModified":{"date":"2024-12-10 01:33:17.368041","timezone_type":1,"timezone":"+01:00"},"UserAccessRight":null,"UserAccID":null,"AuthorKeywords":null,"OtherDescriptors":null,"Notes":null,"AnaPub":null,"MonPub":2006,"DateUpdate":"2012-12-13","DateCreate":"2006-06-09","SecASFANote":null,"ConfID":null,"PeerRev":null,"VlizCoreFlag":1,"WoScode":null,"VABBcode":null,"OpenAcc":0},"refs":null,"anarec":null,"monrec":{"MonID":99471,"ISBN":"90-8504-459-6","PubliDate":2006,"IssueDate":null,"Volume":null,"Issue":null,"Pagination":"120","Place":"Wageningen","Edition":null,"BRefXtra":null,"BRefXtraRR":null,"SerID":null,"SerRR":null,"Ser2BRefID":null,"Ser2RR":null,"StandardTitleSer":null,"ISSN":null,"AbbrevSer":null,"Degree":"PhD","ThesisID":99471,"InsID":5450,"Acronym":"WUR","FullStandardName":"Wageningen University and Research Centre","ToPubliDate":null,"SerNotes":null,"eISBN":null,"Pages":120},"serrec":null,"relations":null,"relationsRev":null,"addrec":null,"othpubs":null,"ownerships":null,"authors":[{"AutName":"Muendo","Firstname":"Patricia Nduku","Initials":"P.N.","Affiliation":null,"Discriminator":null,"CorporateFlag":0,"BEntID":94731,"AutID":66641,"OrderNr":1,"DegrID":null,"EditorFlag":0,"CorrespFlag":0,"IllustratorFlag":0,"ReviserFlag":0,"TranslatorFlag":0,"InsAcronym":null,"InsFSN":null,"ORCID":null,"PersID":null,"InsID":null}],"mapdetails":null,"datasets":null,"monographs":null,"monparts":null,"serparts":null,"BEntOpen":null,"BEntPrivate":null,"availability":[{"BInstID":230419,"LibID":36,"BRefID":99471,"EmbargoDate":null,"FullEmbargoDate":null,"PhysMedID":16,"hasOCRd":1,"ShelfLocCode":"230419","RFID":null,"PaidValue":null,"Medium":"Server","Description":"Interne VLIZ documenten","Acronym":"VLIZ","Library":"Vlaams Instituut voor de Zee","DutchTerm":"Non-open access","URL":null,"ClassifID":228,"Classification":"Non-open access","ReqLink":1,"ClassifTypID":3,"URLLocation":"https://www.vliz.be/imisdocs/publications/","SubDir":1,"InternalReq":1,"LoggedInReq":1,"Disclaimer":"Disclaimer_VLIZ_Intern","DutchDisclaimer":"<p>Deze publicatie is enkel beschikbaar voor persoonlijk gebruik binnen de Innovocean site <br />en mag op geen enkele manier verder worden verspreid.</p>","FileFormat":".pdf","FileDescr":"pdf","InsPub":1,"InsID":36,"FileFormID":6,"LendableFlag":1,"PublicFlag":1,"orderLib":"A","Notes":null,"AccConID":null,"AccessConstraint":null,"LicURL":null}],"litstyles":[{"LitStyID":7,"Style":"Dissertation"}],"thespers":[{"PersID":343,"Surname":"Verreth","Firstname":"Johan Alfons Jozef","Initials":"J.","Role":"Promotor"}],"arch2discl":null,"SERpubls":null,"MONpubls":null,"pictures":[],"thestermsPath":[{"ThesaurusTerm":"Fish culture","ThestID":3152,"Acronym":"ASFA","ThesTermPath":"Cultures > Fish culture"},{"ThesaurusTerm":"Nutrient cycles","ThestID":5625,"Acronym":"ASFA","ThesTermPath":"Cycles > Chemical cycles > Geochemical cycle > Biogeochemical cycle > Nutrient cycles"},{"ThesaurusTerm":"Fish ponds","ThestID":3191,"Acronym":"ASFA","ThesTermPath":"Water bodies > Inland waters > Ponds > Fish ponds"}],"thestermsASFA":[{"ThesaurusTerm":"Fish culture"},{"ThesaurusTerm":"Fish ponds"},{"ThesaurusTerm":"Nutrient cycles"}],"taxtermsASFA":null,"geotermsASFA":null,"collections":null,"conf":null,"proj":null,"Physdatasets":null,"spcols":null,"doi":null,"publs":[{"PublID":1865,"PublName":"Universiteit Wageningen","InsID":2954,"PersID":null,"INBOID":6345,"OrderNr":1}],"serparttypes":null,"monauthors":null,"MParts":null,"SParts":null,"hLibs":null,"langs":[{"BEntID":94731,"AbstractFlag":-1,"LangID":15,"LangCode":"en","Lang":"English","DutchTerm":"Engels","LangCodeExtended":"eng"},{"BEntID":94731,"AbstractFlag":-1,"LangID":41,"LangCode":"nl","Lang":"Dutch","DutchTerm":"Nederlands","LangCodeExtended":"dut"},{"BEntID":94731,"AbstractFlag":0,"LangID":15,"LangCode":"en","Lang":"English","DutchTerm":"Engels","LangCodeExtended":"eng"},{"BEntID":94731,"AbstractFlag":0,"LangID":41,"LangCode":"nl","Lang":"Dutch","DutchTerm":"Nederlands","LangCodeExtended":"dut"}],"urls":null,"thesterms":[{"ThesaurusTerm":"Fish culture","ThestID":3152,"Acronym":"ASFA","ThesTypID":1,"ThesType":"ASFA Thesaurus List"},{"ThesaurusTerm":"Fish ponds","ThestID":3191,"Acronym":"ASFA","ThesTypID":1,"ThesType":"ASFA Thesaurus List"},{"ThesaurusTerm":"Nutrient cycles","ThestID":5625,"Acronym":"ASFA","ThesTypID":1,"ThesType":"ASFA Thesaurus List"}],"taxterms":null,"geoterms":null,"othterms":null,"asfacodes":null,"asfa2codes":null,"thestermsFRIS":[{"ThesaurusTerm":"Fish culture","DutchTerm":null,"ThestID":3152,"Acronym":"ASFA","ThesTypID":1,"ThesType":"ASFA Thesaurus List"},{"ThesaurusTerm":"Fish ponds","DutchTerm":null,"ThestID":3191,"Acronym":"ASFA","ThesTypID":1,"ThesType":"ASFA Thesaurus List"},{"ThesaurusTerm":"Nutrient cycles","DutchTerm":"Nutrientencyclus","ThestID":5625,"Acronym":"ASFA","ThesTypID":1,"ThesType":"ASFA Thesaurus List"}],"taxtermsFRIS":null,"geotermsFRIS":null,"othtermsFRIS":null,"resmessage":"","complete":1,"sessions":{"newSesName":"Chisala, Chilekwa, C.","newSesDate":{"date":"2006-06-09 08:53:34.827000","timezone_type":3,"timezone":"Europe/Brussels"},"updSesName":"Vanhaecke, Delphine, D.","updSesDate":{"date":"2012-12-13 10:50:26.230000","timezone_type":3,"timezone":"Europe/Brussels"}}}