8
64
Transition Met Chem (2013) 38:855–864
Five parameters were analyzed for seed germination at
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2
1
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concentrations of 300, 350 and 400 ppm, and the results
are summarized in Table 6. No significant change in cat-
alase activity was observed. Both carbohydrate and
ascorbic acid content decreased with increased dose, and
contents were higher for nickel nitrate than for the nick-
el(II) complex. Amylase and proline content both increased
with increasing dose, and the contents were higher for the
nickel complex than for nickel nitrate.
18. Schwander H (1988) In: Hendrix P (ed) Ullman’s encyclopedia of
industrial chemistry. VCH, Weinheim, p 279
1
9. Mori A, Sekiguchi A, Masui K, Shimada T, Horie M, Osakada K,
Kawamoto M, Ikeda T (2003) J Am Chem Soc 125:1700–1701
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334:1114–1117
2
21. Muto K, Yamaguchi J, Itami K (2012) J Am Chem Soc
34:169–172
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1
2
2
3. Naumov P, Kochunnoony
132:11566–11579
M (2010) J Am Chem Soc
Conclusions
2
2
4. Zhu W, Wu Y, Wang ZS, Li W, Li X, Chen J, Wang Z, Tian H
2011) Adv Funct Mater 21:756–763
5. Lipshutz BH, Nihan DM, Vinogradova E, Taft BR, Bo sˇ kovi c´ ZV
2008) Org Lett 10:4278–4279
(
A supported nickel(II) complex was prepared and charac-
terized. This complex proved to be an active catalyst for
the one-pot synthesis of various substituted azoles in water
medium. The catalyst is cheap, air stable and recyclable
under the reaction conditions used. The homogeneous
complex is bioactive and inhibits the germination of MTU
ˇ
(
26. Gonz a´ lez J, P e´ rez VM, Jim e´ nez DO, Lopez-Valdez G, Corona D,
Cuevas-Ya n˜ ez E (2011) Tetrahedron Lett 52:3514–3517
2
2
7. Hudson R, Li CJ, Moores A (2012) Green Chem 14:622–624
8. Pittman CU Jr, Carraher CE Jr (2007) Chapter 1, Organometallic
polymers: the early days. In: Aziz AE, Manners I (eds) Frontiers
in transition metal-containing polymers. Wiley Interscience,
Weinheim
7
029. We hope that this complex will find importance in
industrial applications.
2
3
3
3
9. Parihar S, Pathan S, Jadeja RN, Patel A, Gupta VK (2012) Inorg
Chem 51:1152–1161
0. Campos JM, Louren c¸ o JP, Cramail H, Ribeiro MR (2012) Prog
Polym Sci 37:1764–1804
1. Kuilla T, Bhadra S, Yao D, Kim NH, Bose S, Lee JH (2010) Prog
Polym Sci 35:1350–1375
2. Ishihara A, Inui K, Hashimoto T, Nasu H (2012) J Catal
Acknowledgments We acknowledge Department of Science and
Technology (DST) and Council of Scientific and Industrial Research
(
CSIR), New Delhi, India, for funding.
2
95:81–90
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