본 실험은 thermal units을 이용하여 single-stemmed rose($Rosa$ $hybrida$ L.) 'Vital'의 초장, 생체중 및 총엽면적과 각 생육단계에 도달하는 시간을 예측하고, 장미의 신초발달 모델을 개발하기 위해 수행하였다. 기저온도($T_b$), 적정온도($T_{opt}$), 및 최대온도($T_{max}$)는 신초의 발달율과 평균온도의 회귀를 통해 예측하였다. 삽목에서 정식(CT-TP)까지의 생육단계에 대한 신초의 발달율은 linear 함수인 $R_b(d^{-1})$ = -0.0089 + $0.0016{\cdot}Temp$으로 나타났다. 정식에서 수확(TP-HV)까지의 생육단계에서 신초의 발달율은 parabolic 함수인 $R_h(d^{-1})$ = $-0.0001{\cdot}Temp^2$ + $0.0054{\cdot}Temp$ - 0.0484으로 나타낼 수 있었다. $T_b$, $T_{opt}$ 및 $T_{max}$는 각각 5.56, 27.0, 및 $42.7^{\circ}C$으로 나타났다. Tb값 $5.56^{\circ}C$은 single-stemmed rose의 신초발달에 대한 온도함수인 thermal units 계산에 이용되었다. 엽수, 엽면적 및 엽중은 삽목시기에 상관없이 sigmoid curve를 나타내었다. 엽면적(LA) 모델은 thermal units를 사용하여 sigmoid 함수, LA = 578.7 $[1+(thermal units/956.1)^{-8.54}]^{-1}$로 기술할 수 있었다. 삽목에서 정식(CT-TP)과 정식에서 수확(TP-HV)까지의 생육단계에 있어서 요구되는 평균 thermal units($^{\circ}C{\cdot}d$)는 각각 $426{\pm}42(^{\circ}C{\cdot}d)$과 $783{\pm}24(^{\circ}C{\cdot}d$)였다.

This study was conducted to predict number and fresh weight of leaves, and total leaf area of a single-stemmed rose 'Vital' based on the accumulated thermal units, and to develop a model of shoot development for the prediction of the time when the flowering shoot reaches a phenological stage in a plant factory system. The base temperature ($T_b$), optimum temperature ($T_{opt}$), and maximum temperature ($T_{max}$) were estimated by regressing the rate of shoot development against the temperature gradient. The rate of shoot development ($R$, $d^{-1}$) for the phase from cutting to bud break (CT-BB) was best described by a linear model $R_b$ ($d^{-1}$) = -0.0089 + $0.0016{\cdot}temp$. The rate of shoot development for the phase from bud break to harvest (BB-HV) was fitted to the parabolic model $R_h$ ($d^{-1}$) = $-0.0001{\cdot}temp^2$ + $0.0054{\cdot}temp$ - 0.0484. The $T_b$, $T_{opt}$, and $T_{max}$ values were 5.56, 27.0, and $42.7^{\circ}C$, respectively. The $T_b$ value was used in the thermal unit computations for the shoot development. Number of leaves, leaf area (LA), and leaf fresh weight showed sigmoidal curves regardless of the cut time. The shoot development and leaf area model was described as a sigmoidal function using thermal units. Leaf area was described as LA = 578.7 $[1+(thermal units/956.1)^{-8.54}]^{-1}$. Estimated and observed shoot length and leaf fresh weight showed a reasonably good fit with 1.060 ($R^2=0.976^{***}$) and 1.043 ($R^2=0.955^{***}$), respectively. The average thermal units required from cutting to transplant and from transplant to harvest stages were $426{\pm}42^{\circ}C{\cdot}d$ and $783{\pm}24^{\circ}C{\cdot}d$, respectively.

1 van Henten, E.J., "Validation of a dynamic lettuce growth model for greenhouse climate control" 45 : 55-72, 1994

2 Bredmose, N., "Topophysis affects the potential of axillary bud growth, fresh biomass accumulation and specific fresh weight in single-stem rose" 78 : 215-222, 1996

3 Heuvelink, E., "Tomato growth and yield: Quantitative analysis and synthesis. Diss" Wageningen Univ. 1996

4 de Vries,D.P., "The vigour of glasshouse roses. Scionrootstocks relationships: Effects of phenotypic and genotypic variation. Diss" Wageningen Univ. 1-170, 1993

5 Langton, F.A., "The effects of crop density on plant growth and variability in cut-flower chrysanthemum (Chrysanthemum morifolium Ramat.)" 74 : 493-501, 1999

6 Yin, X., "The effect of temperature on leaf appearance in rice" 77 : 215-221, 1996

7 NeSmith, D.S., "Summer squash (Cucurbita pepo L.) leaf number as influenced by thermal time" 68 : 219-225, 1997

8 Lee, J.H., "Simulation of leaf area development based on dry matter partitioning and specific leaf area for cut chrysanthemum" 91 : 317-327, 2003

9 Hunt, L.A., "Simulating response to temperature" 23-25, 2001

10 Pasian, C.C., "Prediction of rose shoot development: Model validation for the cultivar ‘Cara Mia’ and extension to the cultivars ‘Royalty’ and ‘Sonia’" 66 : 117-124, 1996

11 Pasian, C.C., "Prediction of flowering rose shoot development based on air temperature and thermal units" 59 : 131-145, 1994

12 Thornley, J.H.M., "Plant and crop modeling. A mathematical approach to plant crop physiology" Clarendon Press 1-669, 1990

13 Qi, A., "Modelling the effects of temperature on the rates of seeding emergence and leaf appearance in legume cover crops" 35 : 327-344, 1999

14 Marcelis, L.F.M., "Modelling biomass production and yield of horticultural crops: A review" 74 : 83-111, 1998

15 Larsen, R.U., "Modeling flower development in greenhouse chrysanthemum cultivars in relation to temperature and response group" 80 : 73-89, 1999

16 Halevy, A.H., "Light and autonomous induction. in: Light and the flowering process" Academic Press 65-73, 1984

17 van den Berg, G.A., "Influence of temperature on bud break, shoot growth, flower bud atrophy and winter production of glasshouse roses. Diss" Landbouwuniversiteit te Wageningen 1-170, 1987

18 Tei, F., "Growth of lettuce, onion and red beet. 2. Growth modeling" 78 : 645-652, 1996

19 여경환, "Growth and Photosynthesis of Single-Stemmed Roses as Affected by Macro- and Micro-Element Amendment in a Closed Aeroponic System" 한국원예학회 27 (27): 404-413, 2009

20 McMaster, G.S., "Growing degree-days: One equation, two interpretations" 87 : 291-300, 1997

21 Heuvelink, E., "Evaluation of a dynamic simulation model for tomato crop growth and development" 83 : 413-422, 1999

22 Young Yeol Cho, "Estimation of Leaf Number and Leaf Area of Hydroponic Pak-Choi Plants (Brassica campestris ssp. chinensis) Using Growing Degree-Days" 한국식물학회 50 (50): 8-11, 2007

23 Summerfield, R.J., "Effects of illuminance on flowering in long- and short-day grain legumes: A reappraisal and unifying model in:Manipulation of flowering" Butterworths 203-223, 1987

24 Craufurd, P.Q., "Effect of temperature on time to panicle initiation and leaf appearance in Sorghum" 38 : 942-947, 1998

25 조영열, "Development of Models for Estimating Total Leaf Area and Shoot Fresh and Dry Weights of Tomato (Lycopersicon esculentum cv. Seokwang)" 한국원예학회 46 (46): 103-107, 2005

26 Perry, K.B., "Comparison of 14 methods to determine heat unit requirements for cucumber harvest" 21 : 419-423, 1986

27 Monteith, J.L., "Climatic variation and the growth of crops. Q" 107 : 749-774, 1981

28 Gardner, F.P., "Carbon fixation by crop canopy in:Physiology of crop plants" Iowa State University Press 48-57, 1985

29 Moot, D.J., "Base temperature and thermal time requirements for germination and emergence of temperate pasture species" 43 : 15-25, 2000

30 Yan, W., "An equation for modeling the temperature response of plants using only the cardinal temperature" 84 : 607-614, 1999

31 Shaykewich, C.F., "An appraisal of cereal crop phenology modeling" 75 : 329-341, 1995

32 Lieth, J.H., "A simulation model for the growth and development of flowering rose shoots" 46 : 109-128, 1991

33 Gijzen, H., "A model for greenhouse crops and greenhouse climate" 456 : 441-450, 1998

34 Goudriaan, J., "A mathematical function for crop growth based on light interception and leaf area expansion" 66 : 695-701, 1990

35 Wang, J.Y., "A critique of the heat unit approach to plant responses studies" 41 : 785-790, 1960