• Title/Summary/Keyword: Decomposition rates

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The Relationship between the Fractionation Characteristics and Decomposition Rate of Organic Carbon in Nam River and Geumho River (남강 및 금호강에서 유기탄소 존재형태와 분해속도와의 관계)

  • Ho-Sub Kim;Seok-Gyu Kim;Seung-Young Oh
    • Journal of Korean Society on Water Environment
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    • v.39 no.2
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    • pp.131-141
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    • 2023
  • In this study, the relationship between organic carbon distribution characteristics and decomposition rate classified according to the particle size and biological degradation characteristics in water was investigated for the Nam river and Geumho river. The average concentrations of TOC in the Nam river and Geumho river were 2.7±1.2 mg/L and 5.0±1.2 mg/L, respectively, but the composition ratios for each type of organic carbon were similar. An average value of 80.9% of TOC was present as DOC and 72.8% of DOC consisted of Refractory-DOC (RDOC). In addition, the change in the RDOC composition ratio according to temporal and spatial distribution was the smallest. There was no difference in the decomposition rate of organic carbon except for TOC by the site (p≥0.108, one-way ANOVA), and the decomposition rates of Labile-POC (LPOC) and LDOC were similar at 0.139±0.102 and 0.137±0.149 day-1, respectively (p=0.110, paired t-test). The coefficient of variation (CV) of the decomposition rate of DOC (average 8.1%), which had the smallest composition ratio of organic carbon, was 1.1, showing the largest temporal variation. The TOC, POC, and DOC decomposition rates showed a significant correlation with the ratio of the initial concentration to the concentration after 25 days of decomposition (OC25/OC0) (r2=0.89~0.94, p<0.001), and the decomposition rates of LPOC and LDOC were significantly correlated with the ratio of the initial concentration to the concentration after 5 days of decomposition (LOC5/LOC0) (r2=0.67~0.75). This suggests that it is possible to estimate the decomposition rate through the concentration of each type of organic carbon.

The Study on Increase the Decomposition of Organics and Organic Removal Rates by using Sulfate in Sanitary Landfills (황산염을 이용한 매립지 유기물분해 촉진과 분해속도에 관한 연구)

  • Kim, Jeong Gwon;Yun, Tae Gyeong;Kim, Ga Ya
    • Journal of Environmental Science International
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    • v.13 no.1
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    • pp.69-77
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    • 2004
  • In this study, sulfate reduction reaction was used to increase the decomposition of organics, which is the most critical factor for the stabilization of a landfill site. Composite of sewage sludge, papers, and incineration ashes was used in the column. The experimental results indicated that out of 10 reactors, the reactors 3, 4, 8. and 9 showed higher organics (i.e., TOC) removal rate than that in the absence of sulfate. The organics removal rates (K) in R3 and R9 were 8.65e$\^$-4/d and 3.82e$\^$-4//d, respectively. The times to reach 10% of initial concentrations in R3 and R9 was 7.3 and 16.5 years, respectively, showing faster organics decomposition rates in these reactors.

A Comparative Study on Litter Decomposition of Emergent Macrophytes in the Littoral Zone of Reservoir

  • Jo, Kang-Hyun;Gong, Hak-Yang
    • Animal cells and systems
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    • v.2 no.3
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    • pp.333-339
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    • 1998
  • Litter decomposition is a key process in energy flow and nutrient cycling in the freshwater littoral zone, and is regulated by physicochemical properties of litters. Using a litterbag method, we compared the decomposition rates of 16 different litter types from 10 plant species of the emergent macrophytes for one year in the littoral zone of the Paltangho Reservoir, Korea. The regression analysis fitted to the various decomposition models showed that mass loss of the litters with time best fitted an asymptotic function. The litters of the emergent macrophytes were composed of two compartments, labile and refractory. The macrophytic litters showed a great variety in decomposition dynamics depending on sources of litters. The labile compartment of the initial litter mass was in a wide range between 18% and 99%, and their decomposition rates varied from 0.0037 to 0.0131 day-1. The decomposition processes of the emergent macrophytes were determined by the relative amounts of the labile and refractory compartments and by the decomposition rate of the habile one in the littoral zone.

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Feature Extraction and Statistical Pattern Recognition for Image Data using Wavelet Decomposition

  • Kim, Min-Soo;Baek, Jang-Sun
    • Communications for Statistical Applications and Methods
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    • v.6 no.3
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    • pp.831-842
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    • 1999
  • We propose a wavelet decomposition feature extraction method for the hand-written character recognition. Comparing the recognition rates of which methods with original image features and with selected features by the wavelet decomposition we study the characteristics of the proposed method. LDA(Linear Discriminant Analysis) QDA(Quadratic Discriminant Analysis) RDA(Regularized Discriminant Analysis) and NN(Neural network) are used for the calculation of recognition rates. 6000 hand-written numerals from CENPARMI at Concordia University are used for the experiment. We found that the set of significantly selected wavelet decomposed features generates higher recognition rate than the original image features.

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Thermogravimetric and Fourier Transform Infrared Analysis of Switchgrass Pyrolysis (스위치그라스 열분해에 대한 TGA-FTIR 분석)

  • Lee, Seong-Beom;Fasina, Oladiran O.
    • Journal of Biosystems Engineering
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    • v.34 no.1
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    • pp.44-49
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    • 2009
  • This study was conducted to investigate the pyrolysis characteristics of switchgrass using TGA-FTIR instrument. Switchgrass is a high yielding perennial grass that has been designated as a potential energy crop, because of its high energy value. Ground switchgrass were pyrolysed at different heating rates of 10, 20, 30, and $40^{\circ}C/min$ in a TGA-FTIR instrument. The thermal decomposition characteristics of switchgrass were analyzed, and the gases volatilized during the experiment were identified. The thermal decomposition of switchgrass started at approximately $220^{\circ}C$, followed by a major loss of weight, where the main volatilization occurred, and the thermal decomposition was essentially completed by $430^{\circ}C$. The pyrolysis process was found to compose of four stages; moisture evaporation, hemicellulose decomposition, cellulose decomposition, and lignin degradation. The peak temperatures for hemicellulose decomposition ($306^{\circ}C$ to $327^{\circ}C$) and cellulose decomposition ($351^{\circ}C$ to $369^{\circ}C$) were increased with greater heating rates. FTIR analysis showed that the following gases were released during the pyrolysis of switchgrass; $CO_2$, CO, $CH_4$, $NH_3$, COS, $C_{2}H_{4}$, and some acetic acid. The most gas species were released at low temperature from 310 to $380^{\circ}C$, which was corresponding well with the observation of thermal decomposition.

Fertilization and Tree Density Effects on Cellulose Decomposition in a Larix leptolepis Plantation

  • Kim, Choonsig;Kim, Oue-Ryong;Ahn, Hyun-Chul;Cho, Hyun-Seo;Choo, Gab-Chul;Park, Jae-Hyeon
    • The Korean Journal of Ecology
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    • v.25 no.6
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    • pp.399-403
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    • 2002
  • Cellulose mass loss by cellulose filter papers was measured for 3 time (35 days, 70 days, 105 days) incubation during the growing season (from May to September 2002) with different tree density and after fertilization in a Japanese larch (Larix leptolepis) plantation. Cellulose mass loss rates were significantly different between tree density types and fertilization treatments during the study periods. After 105 day incubation of cellulose filter paper, cellulose mass loss rates were significantly higher in the low tree density (70.1 $\%$) than in the high tree density (49.9$\%$). Cellulose mass loss rates averaged 62.8$\%$ in the fertilization and 58.9% in the unfertilization treatments during the same periods. However, cellulose mass loss was not significantly different between the forest floor and the mineral soil layer except for 35 day incubation. The results indicate that cellulose decomposition rates are a useful index to express differences in organic matter decomposition activity in different tree density and after fertilizer treatments.

Ammonia decomposition over titanium carbides

  • Choi, Jeong-Gil
    • Journal of the Korean Crystal Growth and Crystal Technology
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    • v.22 no.6
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    • pp.269-273
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    • 2012
  • Ammonia decomposition over titanium carbides were investigated using eight different samples which have been synthesized by TPR (temperature-programmed reduction) method of titanium oxide ($TiO_2$) with pure $CH_4$. The resulting materials which were synthesized using wo different heating rates and space velocity exhibited the different surface areas. These results indicated that the structural properties of these materials have been related to heating rates and space velocity employed. The titanium carbides prepared in this study proved to be active for ammonia decomposition, and the activity changed with the particle size/surface area. These showed the relationship between ammonia decomposition activity and the different active species. Compared to molybdenum carbide, the titanium carbides were one order of magnitude less active, suggesting the correlation between the activity difference and the degree of electron transfer between metals and carbon in metal carbides.

Distributions of Urea and Urea Decomposition Rates in an Estuarine System of Mankyung and Dongjin Rivers, Korea (만경.동진강 하구계에서 요소와 요소 분해속도의 분포)

  • 심재형;조병철
    • 한국해양학회지
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    • v.29 no.4
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    • pp.402-413
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    • 1994
  • To understand the significance of urea in the pool size of nitrogenous nutrients and in nitrogen (N) requirements of primary producers in and estuarine system of Mankyung and Dongjin rivers nutrients, and urea decomposition rates between June 1992 and February 1994. Urea concentration during the study period ranged from undetectable to 12.5 ug-at. N 1/SUP -1/, contributing to 0-96% (mean of 11%) of the total nitrogenous nutrients in the study area. Urea comprised a major component of the total nitrogenous nutrients when concentration of total nitrogenous nutrients was low. Urea decomposition rates in the water column ranged from 0.02 to 5.77 nM h/SUP -1/, and netplankton was the major decomposer of urea. Vertical distributions of urea decomposition rates in the water column showed generally small variabilities (i.e. < 3 fold). The decomposition rates of urea in the MD estuary would supply 0.2 ∼88.4% of phytoplankton N requirements. The major contribution of urea to phytoplankton N requirements was found when phytoplankton production was low (<50 mg C m/SUP -2/d/SUP -1/).

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Comparisons of Decomposition Rates, Carbon and Nitrogen Dynamics of Branches in Pinus densiflora and Quercus variabilis Stands (소나무와 굴참나무 임분의 가지 분해율과 탄소 및 질소 동태 비교)

  • Choi, Byeonggil;Baek, Gyeongwon;Kim, Hyungsub;Son, Yowhan;Kim, Choonsig
    • Korean Journal of Agricultural and Forest Meteorology
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    • v.23 no.2
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    • pp.89-99
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    • 2021
  • This study was carried out to understand how factors of decomposition such as quality of the substrate (tree species), forest types, and soil·meteorological conditions affect decomposition rates and dynamics of carbon (C) and nitrogen (N) of branches in adjacent Pinus densiflora and Quercus variabilis stands in Sancheong and J inju in Southern Korea. The branch bags (30 cm × 30 cm) with branch samples (a diameter of 2.0 - 4.0 cm and length of 10 cm) were placed on the forest floor at each stand in May 2018. The branch bags were collected in August and November 2018, February and May 2019, respectively. The decomposition rates of branches in P. densiflora stands were 4.49 % for Sancheong, and 5.75 % for Jinju. Whereas, the decomposition rates in Q. variabilis were 20.01 % for Sancheong, and 24.68 % for Jinju, respectively. The decomposition of branches was more rapid in Q. variabilis compared with P. densiflora in both regions. C and N in decomposed branches were more mineralized in Q. variabilis, whereas C and N were more accumulated in P. densiflora. These results indicated that the decomposition rates, C and N of decomposed branches may be affected by differences in substrate quality such as initial N concentration and C/N ratio rather than differences between both regions including different environmental factors.

Nutrient dynamics in montane wetlands, emphasizing the relationship between cellulose decomposition and water chemistry

  • Kim, Jae Geun
    • Journal of Wetlands Research
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    • v.7 no.4
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    • pp.33-42
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    • 2005
  • Wetlands often function as a nutrient sink. It is well known that increased input of nutrient increases the primary productivity but it is not well understood what is the fate of produced biomass in wetland ecosystem. Water and sediment quality, decomposition rate of cellulose, and sediment accumulation rate in 11 montane marshes in northern Sierra Nevada, California were analyzed to trace the effect of nitrogen and phosphorus content in water on nutrient dynamics. Concentrations of ammonium, nitrate, soluble reactive phosphorus (SRP) in water were in the range of 27 to 607, 8 to 73, and 6 to 109 ppb, respectively. Concentrations of ammonium, calcium, magnesium, sodium, and potassium in water were the highest in Markleeville, which has been impacted by animal farming. Nitrate and SRP concentrations in water were the highest in Snow Creek, which has been impacted by human residence and a golf course. Cellulose decomposition rates ranged from 4 to 75 % per 90 days and the highest values were measured in Snow Creek. Concentrations of total carbon, nitrogen, and phosphorus in sediment ranged from 8.0 to 42.8, 0.5 to 3.0, and 0.076 to 0.162 %, respectively. Accumulation rates of carbon, nitrogen, and phosphorus fluctuated between 32.7 to 97.1, 2.4 to 9.0, and 0.08 to $1.14gm^{-2}yr{-1}$, respectively. Accumulation rates of carbon and nitrogen were highest in Markleeville and that of phosphorus was highest in Lake Van Norden. Correlation analysis showed that decay rate is correlated with ammonium, nitrate, and SRP in water. There was no correlation between element content in sediment and water quality. Nitrogen accumulation rate was correlated with ammonium in water. These results showed that element accumulation rates in montane wetland ecosystems are determined by decomposition rate rather than nutrient input. This study stresses a need for eco-physiological researches on the response of microbial community to increased nutrient input and environmental change because the microbial community is responsible for the decomposition process.

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