Simulation of Growth Traits of Salvia miltiorrhizan Bge. Based on Accumulated Product of Thermal Effectiveness and PAR(PDF)

¡¶±±·½Ô°ÒÕ¡·[ISSN:1001-0009/CN:23-1247/S]

Issue:

2014Äê08ÆÚ

Page:

141-146

Research Field:

Publishing date:

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Title:

Simulation of Growth Traits of Salvia miltiorrhizan Bge. Based on Accumulated Product of Thermal Effectiveness and PAR

Author(s):

CHEN Ya-nan¹; LIANG Zong-suo²; GUO Man-cai¹; RU Mei²; LIU Yan³; LIU Feng-hua³

1.College of Sciences£¬Northwest Agricultural and Forestry University£¬Yangling,Shannxi 712100£»

2.College of Life Sciences£¬Northwest Agricultural and Forestry University£¬Yangling£¬Shannxi 712100£»

3.Tianjin Tasly Modern TCM Resources Co.Ltd,Tianjin 300000

Keywords:

Salvia miltiorrhizan Bge.; growth traits; accumulated product of thermal effectiveness and PAR(TEP); effective accumulative temperature(GOD); the prediction model; growth trend

PACS:

R 972

DOI:

-

Abstract:

Taking purple flower Salvia miltiorrhizan Bge. of Shangluo as material£¬the growth models of stem fresh weight£¬leaf fresh weight and leaf area were established by the Gauss equation£¬using accumulated product of Thermal Effectiveness and PAR (TEP) and effective accumulative temperature (GOD) as independent variables respectively.The data of 2011 and 2012 were used to fit and validate the models respectively.1¡Ã1 plot£¬fit residuals and root mean squared error (RMSE) were used to compare simulated valued with observed values.Geometric meaning of the parameters£¬the first and second derivative and inflection points of Gauss equation were used to analysis the growing trend of ground traits of Salvia miltiorrhiza.These models were established in order to develop the management decision support system of Salvia miltiorrhiza.The results showed that the determined coefficient (R²) of those models were higher than 0.9£¬and the accuracy of the prediction of these models based on TEP was higher than those models based on GOD.The growth trend of traits of Salvia miltiorrhiza Bge.:the indexes would reach the maximum when the TEP of stem fresh weight£¬leaf area and leaf fresh weight reached 832.0£¬653.6£¬671.9 MJ/m² respectively;the growth rates would be the fastest when the TEP of stem fresh weight£¬leaf area and leaf fresh weight reached 538.1£¬501.2£¬510.2 MJ/m2;in the TEP of leaf area£¬stem fresh weight£¬leaf fresh weight reached 239.5£¬264.2£¬259.8 MJ/m² respectively£¬the growth rates were slow.Form this time to the TEP reach inflection points£¬the growth rates increased dramatically till reaching the maximum.Then the growth rates slowed down as time prolonging.Both the growth curves of stem fresh weight£¬leaf fresh weight and leaf area and Gaussian function were remarkably consistent£¬and the models base on TEP showed a better predictability than based on GOD.

References:

[1]Àî¾ý,ºØѧÀñ.ÖÐÒ©²Äµ¤²ÎÑо¿½øÕ¹[J].ºÓ±±ÁÖ¹ûÑо¿,2009£¨1£©£º88-91ªª.ª¤

[2]Ì·ÃÀ,ÍõËÄÇå.¹ÛÉÍÖ²ÎïÉú³¤Ä£ÄâÄ£ÐÍÑо¿½øÕ¹[J].Ô°ÒÕѧ±¨,2010(9)£º1523-1530.ª¤

[3]Ðì¹ú±ò,ÂÞÎÀºì,³Â·¢é¦,µÈ.ζȺͷøÉä¶ÔһƷºì·¢Óý¼°Ö÷ҪƷÖÊÖ¸±êµÄÓ°Ïì[J].Ô°ÒÕѧ±¨,2006£¨1£©£º168-171.ª¤

[4]Carvalho S M P£¬Heuvelink E£¬van Kooten O.Effect of light intensity£¬plant density and flower bud removal on the flower size and number incut chrysanthemum[J].Acta Horticulturae£¬2002£¬593£º33-38.ª¤

[5]Larsen R U£¬Hiden C.Predicting leaf unfolding in flower induced shoots of greenhouse grow chrysanthemum[J].Scientia Horticulturae£¬1995£¬63£º225-239.ª¤

[6]Lee J H£¬Goudriaan J£¬Challa H.Using the expolinear growth equation for modelling crop growth in year-round cut chrysanthemum[J].Annals of Botany£¬2003£¬92(5)£º697-708.ª¤

[7]ÑîÔÙÇ¿£¬ÂÞÎÀºì£¬³Â·¢é¦£¬µÈ.ÎÂÊÒ±ê×¼Çл¨¾ÕÒ¶Ãæ»ýÔ¤²âÄ£ÐÍÑо¿[J].ÖйúÅ©Òµ¿Æѧ£¬2007b£¬40(11)£º2569-2574.ª¤

[8]ÀîÙ».»·¾³Òò×Ó¶Ôµ¤²ÎÉú³¤¼°»îÐԳɷÖÀÛ»ýµÄÓ°Ïì¹æÂÉÑо¿[D].ÑîÁ裺Î÷±±Å©ÁֿƼ¼´óѧ,2006.ª¤

[9]¹ùÒøÇÉ£¬ÕÔ´«µÂ£¬ÖìÑÞ£¬µÈ.ÃÞ»¨µØÉϲ¿ÐÎ̬½¨³ÉµÄ¹âÎÂÄ£ÐÍ[J].×÷Îïѧ±¨£¬2009£¬35(11):2102-2108.ª¤

[10]ÀîÇàÁÖ,뺱ƽ,ÀîƼƼ.»Æ¹ÏµØÉϲ¿·ÖÐÎ̬-¹âÎÂÏìӦģÄâÄ£ÐÍ[J].Å©Òµ¹¤³Ìѧ±¨,2011(9)£º122-127.ª¤

[11]ÀîÓÀÐã,ÂÞÎÀºì,Ä߼ͺã,µÈ.ÎÂÊһƹϸÉÎïÖÊ·ÖÅäÓë²úÁ¿Ô¤²âÄ£ÄâÄ£Ðͳõ²½Ñо¿[J].Å©Òµ¹¤³Ìѧ±¨£¬2006(2):116-121.ª¤

[12]ÂíÍòÕ÷,뺱ƽ,Ä߼ͺã.²»Í¬¹ûʵ¸ºÔØÏÂÎÂÊһƹϸÉÎïÖÊ·ÖÅäµÄÄ£Äâ[J].Å©Òµ¹¤³Ìѧ±¨,2010(10)£º259-263.ª¤

[13]Ä߼ͺã,³ÂѧºÃ,³Â´ººê,µÈ.Ó÷øÈÈ»ý·¨Ä£ÄâÎÂÊһƹϹûʵÉú³¤[J].Å©Òµ¹¤³Ìѧ±¨,2009(5)£º192-196.ª¤

[14]ÀîÓÀÐã,ÂÞÎÀºì,Ä߼ͺã,µÈ.Ó÷øÈÈ»ý·¨Ä£ÄâÎÂÊһƹÏÒ¶Ãæ»ý¡¢¹âºÏËÙÂÊÓë¸ÉÎïÖʲúÁ¿[J].Å©Òµ¹¤³Ìѧ±¨,2005(12)£º131-136.ª¤

[15]ÀîÁ¢À¥,ÀîÓñºì,³ÌÖÇ»Û,µÈ.»ùÓÚÓÐЧ»ýÎÂÔç´ºÉèÊ©ºñƤÌð¹Ï¹ûʵ·¢ÓýÄ£ÄâÄ£ÐÍ[J].±±·½Ô°ÒÕ,2010(6)£º97-10.ª¤

[16]ÕÅСӽ,Áõ¸ûÄê,ÀîÓÀ»¯,µÈ.¸ß˹º¯Êý²ÎÁ¿·¨¼°ÆäÔÚɽÇø½µË®¼ÆËãÖеÄÓ¦ÓÃ[J].µØÀíÑо¿,2008(3)£º594-602.ª¤

[17]²ÜÎÀÐÇ,ÂÞÎÀºì.×÷ÎïϵͳģÄâ¼°ÖÇÄܹÜÀí[M].±±¾©£º¸ßµÈ½ÌÓý³ö°æÉ磬2003.ª¤

[18]»ÆÊ绪,Ð츣Àû,ÍõμÁá,µÈ.µ¤²Î׳ÃçÖ¸Êý¼°ÆäÄ£ÄâÄ£ÐÍ[J].Ó¦ÓÃÉú̬ѧ±¨,2012(10)£º2779-2785.ª¤ª¤

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