본 연구에서는 2010년 여름에 천수만에서 저층해수를 채집하여 용존산소와 영양염 농도를 측정하였다. 또한 benthic chamber내의 해수시료를 시계열로 채집하는 자동화된 Benthic Lander를 설치하여 해수-퇴적물간 영양염 플럭스를 측정하였다. 오염된 인공호수 유출수가 들어오는 천수만 북쪽에서는 저층수의 용존산소는 2 mg/l로 hypoxia의 존재 가능성이 확인되었다. 반면 남쪽 천수만 입구의 저층 용존산소는 5 mg/l이었다. 영양염은 용존산소와 반대의 분포 경향을 보였고, N/P ratio의 변화는 hypoxia에 의해 발생된 인산염의 탈착과 용출 때문으로 보인다. 만 북쪽 해역의 유기탄소 산화율과 산소소비율은 남쪽 만 입구 해역보다 약 2배 큰 값을 보였고, 영양염 benthic flux는 천수만 북쪽에서 4내지 6배 높았다. 이러한 결과는 해수-퇴적물간 물질 플럭스를 정확히 추정하기 위해서는 hypoxia의 역할에 대한 이해가 중요하다는 점을 시사해준다.

In this study, the amount of harmful fungi and bacteria contained in the drainage and culture medium from the paprika hydroponic facility is identified. In addition, by proposing the necessity of effective purification of discharged drainage, this study attempted to confirm the possibility of drainage reuse. Finally, this study provides basic data on the basis for calculating the need for purification facilities in the future, as well as improvements in horticulture facility for sustainable agriculture. As a result of the analysis, a total of 12 types of fungi were detected in paprika medium and 10 types of fungi were detected in the drainage, and their densities were 130 and 68, respectively. Among the fungi detected in the media and drainage of the paprika hydroponic facility, the fungi with the highest detection frequency are Fusarium, Phytophthora, and Pythium. In the case of bacteria, a total of 2 types of bacteria were detected in the paprika facilities, and the density was 28 and 23, respectively. Therefore, in order to reuse the drainage and settle the circulating hydroponic cultivation system, a water treatment process capable of appropriate treatment is required.

This study investigated the use of a hydroxyl-radicals-generated microbubble/catalyst (MB/Cat) system for removing organic pollutants, nitrogen, and phosphorous from liquid fertilizer produced by livestock wastewater treatment. Use of the MB/Cat system aims to improve the quality of liquid fertilizer by removing pollutants originally found in the wastewater. In addition, a reduction effect has been reported for antibiotics classified as representative non-biodegradable matter. Samples of liquid fertilizer produced by an aerobic biological reactor for swine wastewater treatment were first analyzed for initial concentrations of pollutants and antibiotics. When the MB/Cat system was applied to the liquid fertilizer, TCOD, TOC, BOD5, and NH3-N, and PO4-P removal efficiencies were found to be approximately 52%, 51%, 30%, 21%, and 66%, respectively. Additionally, Amoxicillin hydrate was removed by 10%, and Chlortetracycline HCl and Florfenicol were not present at detectable levels These findings confirm that the MB/Cat system can be used with livestock wastewater treatment to improve liquid fertilizer quality and to process wastewater that is safe for agricultural re-use.

글로우 고압 방전 방식에 의한 저온 플라즈마(Non-thermal Plasma, NTP) 공정은 액상에서 광전자, 전자, OH-라디칼, 전자기 에너지 등 반응성이 높은 화학물질의 형성할 수 있다. 이 NTP는 공기를 carrier 가스로 활용하여 반응성이 높은 화학종을 생성하는데, 유기물을 효과적으로 산화시키는 고도산화공법의 일종이다. NTP의 강력한 산화력에도 불구하고, NTP 공정에서 발현되는 오염물질의 분해 메커니즘과 그 중간부산물 및 최종 생성물의 경로는 명확하게 밝혀지지 않아 연구가 필요한 실정이다. 본 연구는 폐수 내 다양한 오염물질이 어떠한 메커니즘으로 분해되는가를 실험적으로 규명하고, 2종(sulfamethazine sodium salt와 sulfathiazole sodium salt)의 sulfonamide 계열 항생제에 NTP 공정을 적용하여 제거성능과 분해경로를 검증한다. 또한, 대상 항생제의 분해가 폐수처리 과정에서의 분해 동역학 및 생태 독성과 어떻게 관련되는지를 확인하기 위해 주요 중간부산물 및 신규생성물의 fate를 확인한다. NTP 공정의 진보된 효과를 증명하기 위해 반응성 화학종인 과산화수소 (H2O2)의 순간 생성량을 정량하였으며, OH-라디칼 생성의 간접지표인 N-Dimethyl-4-Nitrosoaniline (RNO) 물질의 분해동역학적 성질을 바탕으로 분해속도계수를 산출하였다. H2O2의 농도는 초기 NTP 공정 적용 시 300 mg/L 까지 증가하였고, 1440 min 적용 시 약 12 mg/L로 감소하며 OH-라디칼 생성과 오염물질 분해에 관여하는 것을 확인하였다. 또한 RNO 물질은 일차함수 형태로 감소하며, 0.91/hr의 속도로 제거되었다. LC-MS/MS (6410 LC-ESI/MS/MS (QQQ), Agilent, USA) 분석을 통해 검출된 중간부산물과 신규생성물을 통해 분해경로를 확인하였다. 문헌과 실험결과의 비교는 NTP 공정이 OH-라디칼 발생 및 산화 환원제와 반응종의 상호 작용으로 인한 산화력 측면에서 다른 산화 공정보다 우수함을 보여준다. Daphnia magna를 이용한 생태독성(Toxicity Unit, TU) 결과는 폐수처리에 대한 NTP 공정 적용이 반응성 화학종의 생성촉진을 통해 독성의 저감에 기여함을 보여주며, 실험결과 TU 값은 초기 2.2 대비 24 hr 적용 후 0.8로 크게 감소하였고, 충분한 체류 시간이 핵심 설계요소임을 밝혔다. 궁극적으로 본 연구는 항생제의 효과적인 제어 및 부산물 관리방안에 대한 유용한 정보를 제공한다.

In these days, agricultural products are regarded as a core income source in tourism villages. Nevertheless, poor packaging of agricultural products has threatened the competitiveness and quality of products. For farmers, it is less likely to employ individual designer for developing and improving their packages due to low accessability to rural villages and budgets. Based on this background, this study conducted 'Charrette' in order to improve agricultural product packaging. The target village was 'Goraday' in Gangwon province. This study consisted of different steps for building and implementing proper 'Charrette' programs. Then, it also conducted empirical investigation about the effectiveness and efficiency of 'Charrette'. 'Charrette' has made progress as follows; first step was concerned with advance preparation for constructing program. Second, implementation of 'Charratte' included data collection and analysis, and development of design. Third, evaluation and feedback stage have given presentation and discussion about suggested design with local residents. Empirical investigation about the effectiveness and efficiency of 'Charrette' has been composed with survey and interview targeting participants. In survey and interviews, designers were asked about their attitudinal changes in relation to knowledge, recognition, function, motivation, and satisfaction toward 'Charrette' and 'agricultural product package design' before and after participating the event. The results showed that knowledge and perception of designers toward 'agricultural product package design' have positively increased. In addition, it revealed that designers were satisfied with collaborations with others and their contribution to rural community business. However, the results also suggested that sufficient preparation time/schedules and opportunity to meet other and farmers before events would be required to have better communication and understanding in relation to their tasks and role distribution. Furthermore, it is also required for designers to hold relationship with local community in order to actualize their packaging design.

The main contents of revision of the rural landscape planning according to Landscape Law discussed in this study show that the urban landscape and rural landscape have a propulsion system which integrate them into the national landscape and manages through the landscape planning. However, management and conservation reflecting the fundamental difference between urban and rural areas are needed. Planning the landscape by generalizing the size of the population, administrative district, the surface area does not meet the ultimate purpose of the Landscape Law that tries to establish differentiated local landscapes. Therefore, the association of professionals who can support and establish a propulsion system for landscape planning with the consideration of regional characteristics. For the urban landscape, the landscape committee is fulfilling the role, but none is available for the rural areas. This study is mostly based on previous literatures, however, in the future, it is desirable to have selected pilot areas for different landscape types and review problems that may occur during the application and process, in order to establish the landscape guidelines for the rural landscape plan.