DeNitrification-DeComposition (DNDC) Improvement through Model Coupling and Sub-model Development Considering Agricultural Land Use and Future Climate Change |
Min, Hyungi
(Department of Environmental Science and Ecological Engineering, Graduate School, Korea University)
Hwang, Wonjae (Department of Environmental Science and Ecological Engineering, Graduate School, Korea University) Kim, Min-Suk (Department of Environmental Science and Ecological Engineering, Graduate School, Korea University) Kim, Jeong-Gyu (Department of Environmental Science and Ecological Engineering, Graduate School, Korea University) |
1 | Giltrap D, S Saggar, C Li and H Wilde. 2008. Using the NZDNDC model to estimate agricultural emissions in the Manawatu-Wanganui region. Plant Soil 309:191-209. DOI |
2 | Huber S, G Bareth and R Doluschitz. 2002. Integrating the Process-based Simulation Model DNDC into GIS. Environmental Communication in the Information Society - Proceedings of the 16th Conference. |
3 | Kludze HK and RD DeLaune. 1995. Gaseous exchange and wetland plant response to soil redox intensity and capacity. Soil. Sci. Soc. Am. J. 59:939-945. DOI |
4 | Krobel R, WN Smith, BB Grant, RL Desjarins, CA Campbell, N Tremblay, CS Li, RP Zentner and BG McConkey. 2011. Development and evaluation of a new Canadian spring wheat sub-model for DNDC. Can. J. Soil Sci. 91:503-520. DOI |
5 | Lane SN, V Tayefi, SC Reid, D Yu and RJ Hardy. 2007. Interactions between sediment delivery, channel change, climate change and flood risk in a temperate upland environment. Earth. Surf. Proc. Land. 32:429-446. DOI |
6 | Li C, J Aber, F Stange, K Butterbach-Bahl and H Papen. 2000. A process-oriented model of and NO emissions from forest soils: 1. Model development. J. Geophys. Res. 105: 4369-4384. DOI |
7 | Li C, J Cui, G Sun and C Trettin. 2004. Modelling impacts on carbon sequestration and trace gas emissions in forested wetland ecosystems. Environ. Manage. 33:s176-s186. |
8 | Li C, N Farahbakhshazad, DB Jaynes, DL Dinnes, W Salas and D McLaughlin. 2006. Modelling nitrate leaching with a biogeochemical model modified based on observations in a row-crop field in Iowa. Ecol. Model. 196:116-130. DOI |
9 | Li C, S Frolking and TA Frolking. 1992. A model of evolution from soil driven by rainfall events: 1. Model structure and sensitivity. J. Geophys. Res. 97:9759-9776. DOI |
10 | Li C, W Salas, R Zhang, C Krauter, A Rotz and F Mitloehner. 2012a. Manure-DNDC: a biogeochemical process model for quantifying greenhouse gas and ammonia emissions from livestock manure systems. Nutr. Cycl. Agroecosys. 93:163-200. DOI |
11 | Li CS, S Frolking and R Harriss. 1994. Modelling carbon biogeochemistry in agricultural soils. Global. Biogeochem. Cy. 8:237-254. DOI |
12 | Li T, Y Huang, W Zhang and YQ Yu. 2012b. Methane emissions associated with the conversion of marshland to cropland and climate change on the Sanjiang Plain of northeast China from 1950 to 2100. Biogeosciences 9: 5199-5218. DOI |
13 | Masscheleyn PH, RD DeLaune and WH Patrick Jr. 1993. Methane and nitrous oxide emission from laboratory measurements of rice soil suspension: effect of soil oxidation- reduction status. Chemosphere 26:251-260. DOI |
14 | McGill WB, HW Hunt, RG Woodmansee and JO Reuss. 1981. Phoenix, a model of the dynamics of carbon and nitrogen in grassland soils. Ecological Bulletins. Sweden. |
15 | Moss R, M Babiker, S Brinkman, E Calvo, T Carter, J Edmonds, I Elgizouli, S Emori, L Erda, K Hibbard, R Jones, M Kainuma, J Kelleher, JF Lamarque, M Manning, B Matthews, J Meehl, L Meyer, J Mitchell, N Nakicenovic, B O'Neill, R Pichs, K Riahi, S Rose, P Runci, R Stouffer, D van Vuuren, J Weyant, T Wilbanks, JP van Ypersele and M Zurek. 2008. Towards new scenarios for analysis of emissions, climate change, impacts, and response strategies, Technical summary, Intergovernmental Panel on Climate Change. pp. 25. Geneva. |
16 | Neufeldta H, M Schaferb, E Angenendtb, C Li, M Kaltschmitta and J Zeddiesb. 2006. Disaggregated greenhouse gas emission inventories from agriculture via a coupled economicecosystem model. Agr. Ecosyst. Environ. 112:233-240. DOI |
17 | Rosenzweig C, A Iglesias, XB Yang, PR Epstein and E Chivian. 2001. Climate Change and Extreme Weather Events; Implications for Food Production, Plant Diseases, and Pests. Global Change Human Health. 2:90-104. DOI |
18 | Phillips SJ and M Dudik. 2008. Modeling of species distributions with Maxent: new extensions and a comprehensive evaluation. Ecography 31:161-175. DOI |
19 | Pinnschmidt HO, WD Batchelor and PS Teng. 1995. Simulation of multiple species pest damage in rice using CERESrice. Agr. Syst. 48:193-222. DOI |
20 | Ramirez-Villegasa J, A Jarvisa and P Laderachd. 2013. Empirical approaches for assessing impacts of climate change on agriculture: The EcoCrop model and a case study with grain sorghum. Agr. Forest. Meteorol. 170:67-78. DOI |
21 | Saggar S, DL Giltrap, C Li and KR Tate. 2007. Modelling nitrous oxide emissions from grazed grasslands in New Zealand. Agric. Ecosyst. Environ. 119:205-216. DOI |
22 | Sass RL, FM Fisher, PA Harcombe and FT Turner. 1991. Mitigation of methane emissions from rice fields: possible adverse effects of incorporated rice straw. Global Biogeochem. Cycles. 5:275-287 DOI |
23 | Schipper L and M pelling. 2006. Disaster risk, climate change and international development: scope for, and challenges to, integration. Disasters 30:19-38. DOI |
24 | Seiler W, A Holzapfel-Pschorn, R Conrad and D Scharffe. 1983. Methane emission from rice paddies. J. Atmos. Chem. 1:241-268. DOI |
25 | Shabani F, L Kumar and S Taylor. 2012. Climate Change Impacts on the Future Distribution of Date Palms: A Modeling Exercise Using CLIMEX. PLos One 7:e48021. DOI |
26 | Smith WN, BB Grant, RL Desjardins, R Kroebel, C Li, B Qian, DE Worth, BG McConkey and CF Drury. 2013. Assessing the effects of climate change on crop production and GHG emissions in Canada. Agr. Ecosyst. Environ. 179:139-150. DOI |
27 | Shaw MW and Osborne TM. 2011. Geographic distribution of plant pathogens in response to climate change. Plant. Pathol. 60:31-43. DOI |
28 | Shirato Y. 2005. Testing the suitability of the DNDC model for simulating long-term soil organic carbon dynamics in Japanese paddy soils. Soil. Sci. Plant. Nutr. 51:183-192. DOI |
29 | Smith WN, BB Grant, RL Desjardins, D Worth, C Li, SH Boles and EC Huffman. 2010. A tool to link agricultural activity data with the DNDC model to estimate GHG emission factor in Canada. Agr. Ecosyst. Environ. 136:301-309. DOI |
30 | Stehfest E, M Heistermann, JA Priess, DS Ojima and J Alcamo. 2007. Simulation of global crop production with the ecosystem model DayCent. Ecol. Model. 209:203-219. DOI |
31 | Sutherst RW, BS Collyer and T Yonow. 2000. The vulnerability of Australian horticulture to the Queensland fruit fly, Bactrocera (Dacus) tryoni, under climate change. Aust. J. Agr. Res. 51:467-480. DOI |
32 | Tallis H and S Polasky. 2009. Mapping and Valuing Ecosystem Services as an Approach for Conservation and Natural-Resource Management. Ecology and Conservation Biology 1162:265-283. |
33 | Thomson LJ, S Macfadyen and A Hoffmann. 2010. Predicting the effects of climate change on natural enemies of agricultural pests. Biol. Control. 52:296-306. DOI |
34 | Veldkamp A and EF Lambin. 2001. Predicting land-use change. Agr. Ecosyst. Environ. 85:1-6. DOI |
35 | Wang ZP, RD DeLaune, PH Masscheleyn and WH Patrick Jr. 1993. Soil redox and pH effects on methane production in a flooded rice soil. Soil Sci. Soc. Am. J. 51:382-385. |
36 | Vidal JP and SD Wade. 2008. Multimodel projections of catchment- scale precipitation regime. J. Hydrol. 353:143-158. DOI |
37 | Wang JX, JK Huang and J Yang. 2014. Overview of Impacts of Climate Change and Adaptation in China's Agriculture. J. Intergr. Agr. 13:1-17. DOI |
38 | Wang L, LJ Qiu, H Tang, H Li, C Li and EV Ranst. 2008. Modelling soil organic carbon dynamics in the major agricultural regions of China. Geoderma 147:47-55. DOI |
39 | Wassmann R, H Papen and H Rennenberg. 1993. Methane emission from rice paddies and possible mitigation strategies. Chemosphere 26:201-217. DOI |
40 | Zhang Z, K Hu, K Li, C Zheng and B Li. 2016. Simulating the effects of long-term discontinuous and continuous fertilization with straw return on crop yields and soil organic carbon dynamics using the DNDC model. Soil Tillage Res. 165:302-314. |
41 | Fumoto T, K Kobayashi, C Li, K Yagi and T Hasegawa. 2008. Revising a process-based biogeochemistry model (DNDC) to simulate methane emission from rice paddy fields under various residue management and fertilizer regimes. Glob. Chang. Biol. 14:382-402. |
42 | IPCC. 2013. Working group I contribution to the IPCC fifth assessment report climate change 2013: The physical science basis. http://www.climatechange2013.org/report/. Accessed 3. Feb. 2017. |
43 | Abdalla M, S Kumar, M Jones, J Burke and M Williams. 2011. Testing DNDC model for simulating soil respiration and assessing the effects of climate change on the gas flux from Irish agriculture. Glob. Planet. Change. 78:106-115. DOI |
44 | Aggarwal PK, N Kalra, S Chander and H Pathak. 2006. Info- Crop: A dynamic simulation model for the assessment of crop yields, losses due to pests, and environmental impact of agro-ecosystems in tropical environments. Agr. Syst. 89: 1-25. DOI |
45 | Butterbach-Bahl K, M Kahl, L Mykhayliv, C Werner, R Kiese and C Li. 2009. A European-wide inventory of soil NO emissions using the biogeochemical models DNDC/Forest- DNDC. Atmos. Eniviron. 43:1392-1402. DOI |
46 | Dankers R and L Feyen. 2008. Climate change impact on flood hazard in Europe: An assessment based on high-resolution climate simulations. J. Geophys. Res. 113:D19105. DOI |
47 | Gilhespy SL, S Anthony, L Cardenas, D Chadwick, A del Prado, CS Li, T Misselbrook, RM Rees, W Salas, A Sanz-Cobena, P Smith, EL Tilston, CFE Topp, S Vetter and JB Yeluripati. 2014. First 20 years of DNDC (DeNitrification DeComposition): Model evolution. Ecol. Model. 292:51- 62. DOI |
48 | Giltrap D, C Li and S Saggar. 2010. DNDC: A process-based model of greenhouse gas fluxes from agricultural soils. Agr. Ecosyst. Environ. 136:292-300. DOI |