본 연구에서는 펄라이트 단용 및 혼합배지를 이용한 양액재배 기술을 개발하기 위하여 이들 배지 자체가 갖는 물리ㆍ화학적 특성에 따른 양액 및 작물체의 관리방법을 계량화하는데 실험목적을 두고 토마토를 대상으로 하여 상이한 배지에 대한 생장반응 및 과실수량을 비교하였다. 1. 초장은 단용배지에서 피트모스(C처리구)와 왕겨배지(D처리구)가 102cm와 101.67cm로 높은 생장을 보였으나 세립 펄라이트는 80.67cm로 가장 작은 초장을 나타냈다. 혼합 배지의 경우 펄라이트의 함량이 많은 처리구(F, G, M처리구)에서 초장이 높은 것으로 나타났다. 2. 엽면적은 단용배지보다는 혼용배지에서 높게 나타났으며, 특히 F처리구(대림 펄라이트+세립 펄라이트+피트모스=5:3:2)에서 2,893 cm2로 가장 높았다. 3. 상대생장률(RGR)은 F, B, G, A처리구 순으로 높았고, 순동화율(NAR)도 이와 유사한 경향을 나타냈다. 4. 총과실수량은 세립 펄라이트 단용처리구에서 5,103g으로 가장 많았으며, 왕겨 단용처리구가 가장 낮아 3,213g 이었다. 펄라이트의 양이 많을수록 수량이 높았으며 왕겨의 사용량이 많을수록 수량이 낮게 나타났다. 5. 당도는 수량이 많은 세립 펄라이트 단용 처리구가 4.99-5.38, 대립 펄라이트+세립 펄라이트+훈탄=5:3:2로 혼합한 처리구에서 5.26-5.43 정도를 나타냈으며, 수량이 가장 적은 왕겨 단용처리구가 전체 화방에서 6 이상의 당도를 나타냈다.

본 실험은 배수성과 통기성이 우수한 양액 재배 배지로써 perlite와 구입이 용이한 왕겨 및 훈탄의 혼합배지를 이용하여 스티로폼 성형베드 및 상자, 플라스틱 자루, 폿트 등의 재배용기의 차이와 배지의 종류에 따른 양액재배 오이의 생육 및 수량반응을 구명하고자 수행하였 다. 1. 스티로폼베드와 상자가 다른 용기보다 초장이 높게 나타났으며, 스티로폼 상자를 용기로 사용할 때 펄라이트 단용처리구가 275.5cm, 왕겨 혼합처리구가 277.0cm로 초장이 가장 높았다. 2. 엽면적은 스티로폼 성형베드와 상자가 가장 높게 나타났고, 자루재배, 폿트재배의 순으로 나타났다. 스티로폼 성형베드와 상자의 경우에는 펄라이트 단용>왕겨 혼합배지>훈탄 혼합배지의 순으로 나타났으나, 자루재배에서는 왕겨, 폿트재배에서는 왕겨 혼합배지에서 엽면적이 높게 나타났다. 3. 과실수량은 스티로폼 상자를 용기로 한 펄라이트 단용구가 2097.1g으로 가장 많았으며 과수도 13.4개로 높게 나타났다. 4. 상품과율은 스티로폼 베드와 상자에서 70%이상을 나타냈으나 자루재배와 폿트재배에서는 70%이하로 나타났다. 5. 곡과율과 선세과는 자루재배에서 10%이상으로 높게 나타난 반면 스티로폼 상자에서는 낮게 나타났다.

LPE방법을 이용하여 InP기판 상에 GaAs이종접합 박막을 최초로 성장하였으며 제반 성장조건들이 박막특성에 미치는 영향을 NDIC광학현미경, SEM, TEM 및 DCXRD 등을 이용하여 조사하였다. 적정 LPE성장온도는 720˚C(냉각속도 0.5˚C/min.)이었으며 성장된 GaAs 박막의 표면형상은 융액 균질화 처리 시 기판을 InP cover웨이퍼로 보호한 경우가 In/InP 융액으로 보호한 경우에 비해 현저히 개선되었다. 박막 성장 시 Ga성장융액 내에 0.005wt% 정도의 Se을 첨가함으로서 기판의 열융해(meltback)현상이 억제되었고 박막의 표면 거칠기도 현저히 개선되었다. 미세 격자가 식각된 InP기판 상에 성장된 GaAs 박막의 DCXRD측정결과 미세 격자 패턴이 없는 기판 위에 성장된 시료보다 결정성이 더욱 향상되었으며 이는 TEM 관찰결과 GaAs/InP계면에서 생성된 전위들 중 일부가 상호반응에 의하여 미세격자 영역 내에 국한되기 때문으로 판단되었다.

(PbZr52,Ti48)O3인 composite ceramic target을 사용하여 R. F. 마그네트론 스퍼터링 방법으로 기판온도 300˚C에서 Pt/Ti/Si 기판위에 PZT 박막을 증착하였다. 페롭스 카이트 PZT박막을 얻기 위하여 PbO분위기에서 로열처리를 행하였다. 하부전극으로 Pt를 사용하였으며 Pt(205Å)/Ti(500 Å)/Si 및 Pt(1000Å)/Ti(500Å)/Si기판을 준비하여 Pt두께화 Ti층이 산소의sink로 작용함으로서 이를 가속화하였다. Ti층의 상부는 산소의 확산으로 인하여 TiOx층으로 변태하였고 하부는 in diffused Pt와 함께 실리사이드층을 형성하였다. TiOx 층의 형성은PZT층의 방향성에 영향을 주었다. 유전상수 (10kHz), 누설전류, 파괴전압, 잔류분극 및 항전계는 각각 571, 32,65μ A /cm2, 0.40MV/cm, 3.3μ C /cm2, 0.15MV/cm이었다.

국내 원예시설이 고정화되면서 각종 연작 장해가 나타남에 따라 객토와 토양소독의 필요성이 커지고 있으나 객토와 토양소독에 소요되는 비용 증가가 큰 문제로 대두되고 있다. 이에 따른 간이한 양액재배 시스템으로서 농가에서도 투자비용과 운용비용이 저렴하면서 환경오염의 염려가 없거나 적은 각종 인공배지를 활용한 토마토 자루재배(bag culture) 실험결과는 다음과 같다. 1. 단용배지를 이용한 토마토 자루배재에서 질석, 훈탄, 모래, 페놀수지 (PRE), 입상면, perlite 등에서 생육, 수량 및 품질면에서 이용가능성이 높고 이들 배지의 단점을 보완한다면 암면 대체도 가능할 것으로 보인다. 2. 혼합배지를 이용한 토마토 자루재배에서 perlite와 입상면 혼합처리에서는 perlite 20-40％수준과 입상면 80-60％수준에서, peatmoss와 질석 혼합처리에서는 peatmoss 40-60％와, 질석 60-40％ 혼합비율에서, peatmoss+질석 +입 상면 혼합처리에서는 peatmoss를 50-60％로 하고 질석과 입상면을 각각 25-20％로 혼합한 경우에서 각각 높은 수량과 품질을 보여주었다.

Ta-silicide의 게이트 전극 및 비트라인(bit line)으로의 사용가능성을 알아보기 위하여 As, P, BF2가 5×1015cm-2의 농도로 이온주입된 다결정 실리콘에 탄탈륨을 스퍼터링으로 증착한 후 급속 열처리로 Ta-silicide를 형성하였다. 형성된 Ta-silicide의 특성은 4-탐침법, X-rayghlwjf, SEM 단면사진과 α-step으로 조사하였으며, 불순물들의 거동은 Secondary Ion Mass Spectroscopy(SIMS)로 알아보았다. TaSi2의 형성은 800˚C에서 시작하며 1000˚C 이상에서 완료됨을 알았다. 형성된 TaSi2층으로 out-diffusion 하였다.

불순물이 주입된 실리콘 기판에 500 두께의 탄탈륨 박막을 증착한 후 실리사이드를 형성시키기 위해 아르곤 분위기에서 급속열처리(RTA)률 하였다. 형성된 TaSi2와 불순물의 거동은 XRD, SEM, 4-point probe, HP4145와 SIMS로 조사하였다. 불순물의 종류에 관계없이 TaSi2는 RTA 온도가 800˚C일때 형성되기 시작하였으며 1000˚C이상에서 증착된 Ta가 전부 TaSi2로 상 전이가 일어났다. 또한 TaSi2/P+영역에 대한 접촉저항간은 contact size가 0.9×0.9(μm2)일때 22Ω 낮은값을 가졌으며 이온 주입된 불순물은 RTA처리시 형성된 TaSi2층으로 out-diffusion이 일어났다.

Supply electrical conductivity (EC) concentration of the nutrition solution is an important factor in the absorption of nutrients by plants and the management of the root zone, as it can control the vegetative/reproductive growth of a plant. Paprika usually undergoes its reproductive and vegetative growth simultaneously. Therefore, ensuring proper growth of the plant leads to increased yield of paprika. In this study, growth characteristics of paprika were examined according to the EC concentration of a coir and a rockwool substrate. The supply EC was 1.0, 2.0, and 4.0 mS·cm-1 applied at the initial stages of the growth using the rockwool (commonly used by paprika farmers) and the coir substrate with a chip and dust ratio of 50:50 and 70:30. For up to 16 weeks of paprika growth, EC concentrations of 1.0 and 2.0 mS·cm-1 were found to have a greater effect on the growth than EC at 4.0 mSꞏcm-1. The normality (marketable) rate of fruit, the soluble solid content, and paprika growth showed that the coir was generally better than the rockwool regardless of the supply EC concentration. The values of the yield per plant at an EC concentration of 4.0 mS·cm-1 was mostly similar at 1.6 kg (coir 50:50), 1.5 kg (coir 70:30) and 1.5 kg (rockwool), but the yield of the rockwool was 88%, which was lower than 98% and 94% yield of the coir substrate. Therefore, this concludes that coir substrate is more effective than rockwool at improving paprika productivity. The results also suggest that the use of coir substrate for paprika has many benefits in terms of reducing production costs and preventing environmental destruction during post-processing.

This study investigated the applicability of horticultural media with recycled coir substrates the growth of Chinese cabbage (Brassica campestris L. ssp. Pekinensis) and lettuce (Lactuca sativa L.) crop. The six different types of coir based substrates were A, Coir 45: Perlite 35: Vermiculite 12: Zeolite 8 (%), B, Coir 55: Perlite 25: Vermiculite 12: Zeolite 8 (%), C, Coir 65: Perlite 15: Vermiculite 12: Zeolite 8 (%), D, Coir 75: Perlite 5: Vermiculite 12: Zeolite 8 (%), E, Coir 85: Perlite 5: Vermiculite 5: Zeolite 5 (%) and F, nursery media (control). The pH and Electric conductivity of the horticultural nursery media were 6.06–7.00 and 0.45–1.10 dS/m-1, respectively. The nursery media containing coir substrates had higher level of Total N, Ca, K, Mg and P than those without coir. Additionally, it was observed that the growth of Chinese cabbage was the best on D (containing 75% coir) while that of lettuce was the best on E (containing 85% coir). In general, when substrates containg a higher percentage of coir were used, the growth of Chinese cabbage and lettuce was ideal. Additionally, the P, Ca, and Mg content in both plants was not significantly altered by the amount of coir present in the media. However, with an increase in the amount of coir substrate, the chlorophyll, N, and K content was increased. After harvesting, there was no significant difference in the chemical properties of the horticultural nursery media of both plants. Thus, it can be suggested that, coir substrate after a single use could be recycled as horticulture nursery media.

In order to determine the short-term impact induced by chloride ionic, CaCl2 was used to study the chloride ionic effects of salinity on substrate and growth of Dracacena braunii grown in ornamental hydro-culture. A distilled water (control) was enriched with 10, 20, 50, 100, and 150 g･L -1 of CaCl2, respectively. Before planting, acidity and electronic conductivity values remarkably increased with increasing concentration of CaCl2. However, 4 weeks after planting, acidity values decreased to a slightly acidic pH, while there were not significant differences among electronic conductivity values obtained. Number of root, fresh weight, and total chlorophyll content were significantly decreased in response to CaCl2 concentration in comparison with control, whereas dry weight, water content, and color of stem were no significant effect of CaCl2 concentration less than 20 g･L -1 . These results showed that initial CaCl2 concentrations above 20 g･L -1 is considered to be the threshold value that will sustain the Dracacena braunii in the growth condition and above which plant growth will be retarded.

The current study was performed to investigate the effect of recycling coir substrates on the growth, fruit yield, and quality of strawberry plants. Analysis of physical properties revealed that the pH of a fresh coir substrate was 5.04 while those of substrates reused for one and two years were 5.20 and 5.33, respectively. The electrical conductivity (EC) of a new substrate was as high as 4.58 dS·m−1. This can cause salt stress after transplanting. The EC tended to decrease as the substrate was recycled, and the EC of a two-year recycled substrate was 1.48 dS·m−1. The fresh substrate had lower nitrogen and calcium concentrations, but higher phosphate, potassium, and sodium concentrations than the recycled coir substrate. The coir substrates recycled for one or two years maintained better chemical properties for plant growth than the fresh substrate. Strawberry growth varied depending on the number of years that the coir substrate was recycled. In general, strawberries grown in substrates that had been reused for two years did better than those grown in substrates that had been reused once or were fresh. Ninety days after transplanting, a plant grown in a substrate that had been reused for two years contained 25 leaves, which was 3.6 more than with a fresh substrate. In addition, the plants grown in a substrate that had been reused for two years exhibited larger leaf areas than those grown in other substrates. Coir substrates that had been reused for one year increased the number and area of leaves, but not as much as the substrate that had been reused for two years. One- and two-year reused coir substrates increased the weight of strawberries produced relative to the unused substrate, but the difference was not statistically significant. The plants grown in two-year reused substrates were longer and wider, as well. Also, the number of fruits per plant was higher when substrates were reused. Specifically, the number of fruits per plant was 28.7 with a two-year reused substrate, but only 22.2 with a fresh substrate. The fruit color indices (as represented by their Hunter L, a, b values) were not considerably affected by recycling of the coir substrate. The Hunter L value, which indicates the brightness of the fruit, did not change significantly when the substrate was recycled. Neither Hunter a (red) nor b (yellow) values were changed by recycling. In addition, there were no significant changes in the hardnesses, acidities, or soluble solid-acid ratios of fruits grown in recycled substrates. Thus, it is thought that recycling the coir substrate does not affect measures of fruit quality such as color, hardness, and sugar content. Overall, reuse of coir substrates from hydroponic culture as high-bed strawberry growth substrates would solve the problems of new substrate costs and the disposal of substrates that had been used once.

The present study was investigated the effect of recycled coir organic substrates on the growth of different vegetable crops. The recycled coir had better physical and chemical properties than the new coir. The growth of tomato plant was better on the coir substrate that had been used for 2 years than that on the new coir substrate. The average number of tomato fruits was 108 on the new coir substrate, while it was 179 and 165 on the coir substrate used for 1 and 2 years, respectively. The growth of cherry tomato plant was also better on the coir substrate used for 2 years than that on the new coir substrate. The average number of cherry tomato fruits was 43 on the new coir substrate, while it was 206 and 164 on the coir substrate used for 1 and 2 years, respectively. The growth of brussel sprout was better on the coir substrate used for 3 years than that on the new coir substrate and the average number of brussel sprout leaves was 26.8 on the new coir substrate, while it was 34.3 on the coir substrate used for 3 years. The growth of Korean cabbage improved on the coir substrate used for 1 years compared to the new coir substrate and the number of leaves was 15.1 on the new coir substrate, while it was 24.3 on the coir substrate used for 1 year. Thus, used coir can be recycled to improve vegetable yields compared to using new coirs.

The objectives of this study were to assess plant growth of the flowering shrub species for adapting to growing on hanging baskets in the vertical greenery system with different cover materials and substrates for low maintenance effectively utilizing rainfall. Water amount taken up by the fabric cover was higher than that by the plastic film cover. Evaporated water amount from the fabric cover was much slower than that from the plastic cover. A higher ratio of hydrophilic polymer to the substrate resulted in higher substrate water content within the same cover material. The relative growth rates of plant height, leaf width and stem diameter were higher when the Cotoneaster horizontal was grown in the vertical greenery system with the fabric cover, whereas the leaf number and survival rate were higher with the plastic film cover. The relative growth rates of plant height, leaf width and leaf number and the survival rate was higher when the Euonymus fortunei ‘Emerald n Gold’ was grown in the vertical greenery system with plastic film cover than those with both fabric cover and hydrophilic polymer treatment. In contrast, the stem diameter of Euonymus fortunei ‘Emerald n Gold’ was higher in the plants grown in the vertical greenery system with the fabric cover at a 1.0% ratio of hydrophilic polymer to substrate than that with plastic film cover. The highest stem diameter of Spiraea × bumalda ‘Gold Mound’ was observed in the plant grown in the vertical greenery system with fabric cover and at a 1.0% ratio of hydrophilic polymer to substrate, while there was no significant difference in the plant height. The leaf number was decreased with increase in the ratio of hydrophilic polymer to substrate, while the leaf width was decreased. The survival rate of Spiraea × bumalda ‘Gold Mound’ was higher than 80% regardless of treatments. In particular, the highest survival rate was observed in the plastic film cover treatment after overwintering.

The present study was conducted to find a way to recycle the coir substrate by investigating changes in its physical and chemical properties based on the number of use year. Specific gravity of unused coir substrate was 0.212 g/cm3 , while it was higher for the substrate used for 2 years. Porosity was different depending on the number of use year. The porosity of unused substrate was 51.9%, but it increased to 68.6% after used for 2 years. In general, physical and chemical properties were better in the coir substrate used for 2 years than in unused one. The number of leaves, leaf area, flesh weight and dry weight of oriental cabbage and lettuce were higher in coir substrate used for 2 years than those in unused one. Whereas, no significant difference was observed between the substrates used for one year and 2 years, indicating that the one time-used wast substrate could be recycled for cultivating vegetables. Growth of the vegetables was improved when organic fertilizer composed of complex organics with different mixing ratios was provided to the coir substrate, compared to untreated plot. The optimum mixing ratio of the wast substrate and complex organics was 2:8(v/v) for fertilization using wast coir substrate. Therefore, coir substrate generally wasted after being used for one time was reuseable by supplying organic fertilizer.

본 연구는 옥상녹화에서 무기질계 인공토와 유기질계 인공토가 초본인 돌나물과 목본인 순비기나무의 생육에 미치는 영향을 살펴 봄으로써 유기질계 인공토의 효용성을 제시하고자 한다. 연구기간 은 2013년 5월에서 10월로 약 5개월이며, 식물종은 초본류에 돌나 물을, 목본류에 순비기나무를 대상으로 무기질계 인공토(Inorganic substrate=perlite, IOS), 자연토(natural soil, NS), 유기질계 인공 토Ⅰ(organic substrate=artificial compost Ⅰ, OS1), 유기질계 인공토 Ⅱ(organic substrate=artificial compost Ⅱ, OS2)로 구 성하였다. 돌나물의 초장, 줄기수, 엽수, 상대엽록소함량비는 유기 질계 인공토 Ⅰ처리구(OS1)> 자연토 처리구(NS)> 무기질계 인 공토(IOS) 순으로 높았으며, 통계적인 차이가 뚜렷하였다. 생체중 과 건물중 또한 OS1, NS, IOS 처리구 순으로 생육결과와 비교적 유사한 경향을 보였다. 순비기나무는 수고, 경경, 엽장, 엽폭은 유기 질계 인공토 Ⅱ(OS2)> 자연토 처리구(NS)> 무기질계 인공토 (IOS) 순으로 유의적으로 높았으며, 특히 유기질계 인공토 Ⅱ 처리 구에서 단기간의 실험임에도 불구하고 그 차이가 뚜렷했다. 이에 옥상녹화의 식재지반에서 무기질계 인공토의 단용처리는 식물생 육에 부정적인 영향을 미칠 수 있으므로 식물생육을 위한 적정비율 의 유기질계 인공토의 활용이 요구된다.

This study is about making artificial soil for wall greening using Spent Mushroom substrates (SMS) & Superabsorbent polymer (SAP). and developing new material for wall greening whilst monitoring the physico-chemistry & germination ability of the plant, plant growth and developmental condition of the artificial soil. It was found that the larger the particle size of the superabsorbent polymer the more absorption increased. This showed the plant’s germination rate in soil when Spent Mushroom substrates & Superabsorbent polymer (SAP) were mixed. In the Bermuda grass, the Artificial soil (SMS & SAP 0.5%) showed a 100% germination rate over a period exceeding 7 days compared to Peat-moss that showed a 94% germination rate. In the Kentucky blue grass, however, there was no difference between the Peat-moss and Artificial soil. When general perlite soil was compared with artificial soil in the chicory seed, the Artificial soil showed better results than the general perlite soil in length, leaf volume and fresh-weight. In the plant length, it showed an increase of over 105% (SAP 0.5% or more), 187% (SAP 1% or more). in the leaf volume, an increase of over 123% (SAP 0.5% or more), 145% (SAP 1% or more), in the fresh-weight an increase of over 130% (SAP 0.5% or more), 285% (SAP 1% or more). The artificial soil (SMS & SAP 1%) showed an excellent result in the plant growth and development. Thus, it was found that artificial soil using the SMS & SAP were the only suitable soil materials for wall greening hence suggesting that it could be used for the greening of a blighted area or desert and a variety of agriculture.

4가지 인공배합토 모두는 용적밀도와 포장용수량을 고려할 때에 초본류를 적용한 저관리․경량형 옥상녹화뿐만 아니라 관목류를 적용한 혼합형 또는 관리․중량형 옥상녹화에도 활용 가능할 것이다. 전반적으로 시간이 경과하며 인공배합토 모두는 산성화되며 펄라이트 소립과 펄라이트 소립+일반토양(v/v, 2:1)은 적정한 수준을 나타냈고, 세라소일과 세라소일+자연토양(부피비, 2:1)은 알칼리성을 나타냈다. 펄라이트 소립과 펄라이트 소립+일반토양(v/v, 2:1)은 유기물 함량이 낮게 나타났다. 식재 후 1년이 경과한 후에 4가지 인공배합토 모두는 척박하며 건전한 생육을 저해할 것으로 판단된다. 식재 후 1년이 경과한 후에 4가지 인공배합토에서 자란 3종의 상록활엽수는 먼저 6개월이 경과한 후에서의 식물체와 비교하여 불량한 생육을 보였고, 4가지 인공배합토 상호간에도 서로 다른 생육특성을 나타냈다. 구체적으로 다정큼나무는 세라소일, 세라소일+일반토양(v/v, 2:1)에서 상대적으로 높은 생육량을 나타냈고, 남천은 4종의 인공배합토 모두에서 일반토양과 비교하여 상대적으로 낮은 생육량을 나타냈으며, 영산홍은 펄라이트, 펄라이트+일반토양(v/v, 2:1)에서 상대적으로 높은 생육량을 나타냈다. 이것은 보다 건전한 식물생육을 유도하기 위해서 각각의 상록활엽관목의 생육특성을 고려한 인공배합토의 선정이 필요함을 의미한다고 해석할 수 있으며, 또한 보다 다양한 종류의 상록활엽관목을 옥상녹화에 도입하기 위하여 각각의 인공배합토에서 그 생육특성을 평가하는 것이 필요함을 보여주고 있다.

This research was conducted to investigate the influence of various organic substrates on growth and yield of ginseng seedling grown organically in the closed plastic house. The pH and EC of substrates used for organically ginseng cultivation ranged 5.93~6.78 and 0.03~0.15 dS/m respectively. The concentrations NH4-N and NO3-N respectively was 14.01~68.63 mg/L, 5.60~58.83 mg/L. The average quantum of the closed plastic house was range from 10 to 16% of natural light. In July and August, the maximum temperature of the closed plastic house did not exceed 30 and the average temperature was maintained within 25 lower than the field because air conditioning ran. The PPV-1 and PPV-2 bed soil substrates produced higher stem length, stem diameter, shoot fresh weight and leaf area than those of conventional culture. In PPV-2 bed soil substrates, root fresh weight and root diameter was the highest. The root fresh weight of PPV-2 bed soil substrates in closed plastic house was maximum 25% heavier than the conventional cultivation. The results of this experiment will be utilized for making new substrate application for organic ginseng culture in the plastic house.