Your search keyword '"Park, Byung Bae"' showing total 6 results

1. Metabolic profiling and secondary metabolite accumulation during fruit development of Cornus officinalis Sieb. et Zucc

Author

Park, Chang Ha, Sathasivam, Ramaraj, Kim, Tae Jin, Park, Byung Bae, Kim, Jae Kwang, and Park, Sang Un

Published

2022

2. Assessment on the influence of resistive superconducting fault current limiter in VSC-HVDC system

Author

Lee, Jong-Geon, Khan, Umer Amir, Hwang, Jae-Sang, Seong, Jae-Kyu, Shin, Woo-Ju, Park, Byung-Bae, and Lee, Bang-Wook

Published

2014

3. Nutrient concentrations in roots, leaves and wood of seedling and mature sugar maple and American beech at two contrasting sites.

Author

Park, Byung Bae and Yanai, Ruth D.

Subjects

PLANT nutrients, PLANT roots, FOLIAR diagnosis, WOOD chemistry, SEEDLINGS, SUGAR maple, AMERICAN beech, PLANT-soil relationships, TREE development

Abstract

Abstract: Differences in sensitivity to soil conditions across tree species and developmental stage are important to predicting forest response to environmental change. This study was conducted to compare elemental concentrations in leaves, stems, and roots of (1) sugar maple (Acer saccharum Marsh.) seedlings vs. mature trees and (2) mature sugar maple vs. mature American beech (Fagus grandifolia Ehrh.) in two sites that differ in soil base saturation and pH. Both sites are located in Huntington Forest, NY, USA; one site (hereafter ‘H’) has higher soil pH and Ca, Mg, and Mn concentrations than the other site (hereafter ‘L’). Sugar maple growth at H (14.8cm2 year−1 per tree) was much greater than at L (8.6cm2 year−1 per tree), but the growth of beech was not different between the two sites. Leaves, roots, and stem wood of mature beech trees and sugar maple seedlings and mature trees were sampled for nutrient analysis. Foliar Ca, K, and Al concentrations were positively correlated with soil elements, but Mn concentrations were negatively correlated. Sugar maple differed more than beech between sites in foliar K and Mn concentrations. Root Mg and P concentrations reflected soil chemistry differences, in contrast to foliar concentrations of Mg and P, which were indistinguishable between the sites. In sugar maple, seedlings differed more than in mature trees in nutrient concentrations in roots, especially for Mg and Mn. Although beech was not as responsive to nutrient availability as sugar maple in foliar and root nutrient concentrations, Ca and Mg concentrations in beech wood were higher in H (52% higher for Ca and 68% higher for Mg), while sugar maple did not differ between sites. Sugar maple regeneration failure on acidic soils in the same region is consistent with our finding that sugar maple seedlings were very sensitive to nutrient availability. This sensitivity could ultimately contribute to the replacement of sugar maple by American beech in regions of low pH and base cations if base cation leaching by anthropogenic deposition and tree harvesting continues. [Copyright &y& Elsevier]

Published

2009

4. Wood ash effects on plant and soil in a willow bioenergy plantation

Author

Park, Byung Bae, Yanai, Ruth D., Sahm, James M., Lee, Don K., and Abrahamson, Lawrence P.

Subjects

*BIOMASS, *BIOMASS energy, *PLANT growth, *POTASSIUM

Abstract

Abstract: Intensive management for biomass production results in high rates of nutrient removal by harvesting. We tested whether wood ash generated when burning wood for energy could be used to ameliorate negative soil effects of short-rotation harvesting practices. We measured the temporal and spatial dynamics of soil nutrient properties after wood ash applications in a willow plantation in central New York State and determined the influence of wood ash application on willow growth. Wood ash was applied annually for 3 years at the rates of 10 and 20Mgha−1 to coppiced willow, Salix purpurea, clone SP3. Wood ash application significantly increased soil pH in the 0–10cm soil layer from 6.1 in the control to 6.9 and 7.1 in the 10 and 20Mgha−1 treated plots. Wood ash application significantly increased soil extractable phosphorus, potassium, calcium, and magnesium concentrations. Potassium was the element most affected by wood ash treatment at all soil depths. Wood ash had no significant effect on nutrient concentrations of foliar, litter, and stem tissue. Wood ash did not affect either individual plant growth or plot biomass production, which declined over the course of the study; it did increase the size of stems, but this effect was balanced by a decrease in the number of stems. Applying nitrogen as well as wood ash might be required to maintain the productivity of this SRIC system. [Copyright &y& Elsevier]

Published

2005

5. Biochar production using a Flexible Counter Flow Multi-Baffle (F-COMB) reactor.

Author

Rani, Irma Thya, Wijaya, Bangun Adi, Lee, Sihyun, Kim, Sangdo, Choi, Hokyung, Chun, Donghyuk, Im, Hyuk, Kim, Soohyun, Lim, Jeonghwan, Yoo, Jiho, and Park, Byung Bae

Subjects

*CARBON sequestration, *FLOW meters, *BIOCHAR, *WOOD pellets, *ENERGY consumption, *GAS flow

Abstract

Pyrogenic carbon capture and storage (PyCCS) based on biochar is considered a negative emission technology (NET) aimed at mitigating climate change, with the potential to reduce CO 2 by 0.3–2 gigaton/yr at the cost of $30–120/ton-CO 2. The annual biochar production needs a substantial scaling up of the current production rates (i.e., >150 million tons by 2050) to meet the above demand. However, current biochar production predominantly relies on a small-scale operation, which generally leads to high operational costs and limited control of the biochar properties. This work presents the operation of a state-of-the-art 1 ton/d pilot-scale Flexible Counter Flow Multi-Baffle (F-COMB) pyrolyzer designed for continuous biochar production, which is a prototype reactor for the scale-up. The F-COMB utilizes counter-flow and vortex mixing in a multi-baffle column structure to enable efficient contact of feedstock with hot gas. It boasts high energy efficiency and economic feasibility through a short residence time, reduced gas flow rate, and simple structure. It produces wood pellet biochar with accurate control of the reaction conditions such as temperature, retention time, hot gas flow rate, and feedstock loading. Moreover, continuous biochar production is done successfully with three flexible baffles configuration, demonstrating the significant potential for the scale-up. • Flexible Counter Flow Multi-Baffle (F-COMB) reactor is designed for pyrolysis. • F-COMB provides high energy efficiency via efficient contact of feedstock & hot gas. • Vortex mixing induced by multiple baffles gives the efficient contact. • Biochar production using a F-COMB was demonstrated at 1 ton/day scale successfully. • Continuous biochar production shows significant potential for the F-COMB scale-up. [ABSTRACT FROM AUTHOR]

Published

2024

6. Litterfall and element fluxes in secondary successional forests of South Korea.

Author

Carayugan, Mark Bryan, An, Ji Young, Han, Si Ho, and Park, Byung Bae

Subjects

*SECONDARY forests, *CONIFEROUS forests, *BROADLEAF forests, *NUTRIENT cycles, *DECIDUOUS forests, *TEMPERATE forests

Abstract

• Floristic structure effects on litterfall are masked by local site and stand traits. • Broadleaf deciduous litter returns more macronutrients than coniferous evergreens. • Inter-stand variations in element flux indicate biomass allocation and nutrient use. • Nutrient cycling in secondary forests is determined by litter quantity. Determining litterfall and corresponding element fluxes is valuable in understanding productivity and biogeochemical cycling in floristically distinct secondary successional zones. Secondary-growth forests form a major portion of the cool-temperate forests of South Korea following decades of severe disturbance and intensive rehabilitation efforts. This study monitored the total and fraction-specific litterfall mass, element flux, and nutrient use efficiency patterns of a secondary-growth broadleaf deciduous forest (hereafter, BDF A) and compared these values in forests with contrasting sub-canopy compositions (BDF B) and with coniferous evergreen forests (CEF). Mean annual total litterfall mass was uniform across stands at a range of 871.5 g m−2 yr−1 to 990.2 g m−2 yr−1. Litterfall mass of seed, bark, and miscellaneous fractions varied per stand (p < 0.05 for seed; p < 0.01 for bark and miscellaneous). A pronounced unimodal litterfall peak was detected for all stands, with total litterfall responding positively to relative humidity but negatively to windspeed and solar radiation. Coniferous evergreen litter contained higher C but lower macronutrients relative to broadleaf deciduous litter. Macronutrient fluxes ranged from 156.2 to 183.9 kg ha−1 yr−1, with broadleaf stands having significantly higher K and Ca rates. Macronutrients were returned in all stands in the order of N > Ca > K > Mg > P, whereas NUE followed a reverse sequence. NUE in CEF was higher than BDF A and BDF B for all macronutrients, reflecting the distinct biomass allocation and nutrient utilization strategies between conifers and broadleaves. In temperate secondary-growth forests, nutrient cycling via litterfall is substantiated primarily by litterfall quantity and secondarily by litter element concentration. Our findings have important implications for elucidating forest litter ecology and improving sustainable management practices in secondary successional forests. [ABSTRACT FROM AUTHOR]

Published

2023