Herbicidal Efficacy of Protoporphyrinogen Oxidase Inhibitors (original) (raw)
References
Dayan FE, Weete JD, Hancock HG (1996) Physiological basis for differential sensitivity to sulfentrazone by sicklepod (Cassia obtusifolia) and coffee senna (Senna occidentalls). Weed Sci 44:12–17. CAS Google Scholar
Duke SO, Rebeiz CA (1993) Porphyric pesticides. ACS Symp Seri 559, Am Chem Soc, Washington, DC. Google Scholar
Engelken LK, Brenneman LG, Creswel JLI, Czapar GF, Owen MDK (1987) Common sunflower control in soybeans. Proc North Central Weed Sci Soci 42:42. Google Scholar
Evans JDHL, Cavell BD, Hignett RR (1987) Fomesafen-metabolism as a basis for its selestivity in soya. 1987 Bri Crop Protect Conf Weeds, pp 345-352. Google Scholar
Fenyes JG, Steffens JJ (eds) Synthesis and chemistry of agrochemicals III. ACS Symp Seri 504. Am Chem Soc, Washington, DC, pp 135–146 Google Scholar
Frear DS, Swanson HR, Mansager ER (1983) Acifluorfen metabolism in soybean: diphenylether bond cleavage and the formation of homoglutathione, cysteine, and glucose conjugates. Pestic Biochem Physiol 20:299–310. ArticleCAS Google Scholar
Glenn S, Hook BJ, Peregoy RS, Wiepke T (1985) Control of velvetleaf (Abutilon theophrasti) and common cocklebur (Xanthium pensylvanicum) in soybeans (Glycine max) with sequential applications of mefluidide and acifluorfen. Weed Sci 33:244–249. CAS Google Scholar
Hashimoto S, Nagano E, Otsubo T, Nambu K, Hosokawa S, Takemoto I (1995) Resource a new herbicide. Sumitomokagaku 1995-I:4–18. Google Scholar
Hayashi Y (1987) United States patent 4708734. Google Scholar
Hayashi Y (1990) Synthesis and selective herbicidal activity of methyl (E,Z)-[[[1-[5-[2-chloro-4-(trifluoromethyl) phenoxy]-2-nitrophenyl]-2-methoxyethylidene]-amino]oxy] acetate and analogous compounds. J Agric Food Chem 38:839–844. ArticleCAS Google Scholar
Higgins JM, Whitewell T, Corbin FT, Carter JR. GE, Hill JR. HS (1988a) Absorption, translocation, and metabolism of acifluorfen and lactofen in pitted morningglory (Ipomoea lacunosa) and ivyleaf morningglory (Ipomoea bederacea). Weed Sci 36:141–145. CAS Google Scholar
Higgins J, Whitewell T, Murdock ED, Toler JE (1988b) Recoverry of pitted morningglory (Ipomoea lacunosa) and ivyleaf morningglory (Ipomoea hederacea) following application of acifluorfen, fomesafen, and Iactofen. Weed Sci 36:345–353. CAS Google Scholar
Kamoshita K, Nagano E, Saito K, Sakaki M, Yoshida R, Sato R, Oshio H (1992) S-23031 — a new post-emergence herbicide for soybeans. In: Copping LG, Green MB, Rees RT (eds) Pest management in soybean. SCI Elsevier Applied Science, London, pp 31–325. Google Scholar
Kouji H, Masuda T, Matsunaka S (1990) Mechanism of herbicidal action and soybean selectivity of AKH-7088, a novel diphenyl ether herbicide. Pestic Biochem Physiol 37:219–226. ArticleCAS Google Scholar
Mathis WD, Oliver LR (1980) Control of six morningglory (Ipomoea) species in soybean (Glycine max). Weed Sci 28:409–415. CAS Google Scholar
Miura Y, Onishi M, Mabuti T, Yanai I (1993) A new herbicide for use in cereals. 1993 Bri Crop Protect Conf, pp 35-40. Google Scholar
Miyazawa T, Kawano K, Shigematsu S, Yamaguchi M, Matsunari K, Porpiglia P, Gutbrod KG (1993) KIH-9201, a new low-rate post-emergence herbicide for maize (Zea mays) and soybean (Glycine max). 1993 Bri Crop Protect Conf, pp 23-28. Google Scholar
Morishima Y, Osabe H, Goto Y, Masamoto K, Yagihara H (1990a) Studies on herbicide 4-pyridone-3-carboxamide derivatives 1: herbicidal activity under paddy conditions and quantitative structure-activity relationships. Weed Res Jpn 35:273–281. CAS Google Scholar
Morishima Y, Osabe H, Goto Y, Masamoto K, Yagihara H (1990b) Studies on herbicide 4-pyridone-3-carboxamide derivatives 2: herbicidal activity under upland condition and physiological action of 2′, 6′-disubstituted anilides. Weed Res Jpn 35:282–289. CAS Google Scholar
Osabe H (1991) Quantitative structure-activity studies of light-dependent herbicidal pyridone-carboxyanilides. paper, Kyoto University, Kyoto, Japan. Google Scholar
Theodoridis G, Baum JS, Hotzman FW, Manfredi MC, Maravetz LL, Lyga JW, Tymonko JM, Poss KM, Wyle MJ (1992) Synthesis and herbicidal properties of aryltriazolinones: a new class of pre-and post-emergence herbicides. In: Baker DR, Fenyes JG, Steffens JJ (eds) Synthesis and chemistry of agrochemicals III. ACS Symp Ser 504:134–146. Am Chem Soc, Washington, DC. Chapter Google Scholar
Ueda T, Ugai S, Hori M, Hirai K (1995) Action mechanism of a new herbicide, KPP-314. II. Effect on the porphyrin pathway. Proceedings of the 43th congress of weed science of Japan, Weed Science of Japan, Tokyo, pp 10–11. Google Scholar
Van Saun WA, Bahr JT, Crosby GA, Fore ZQ, Guscar HL, Harnish WN, Hooten RS, Marquez MS, Parrish DS, Theodoridis G, Tymonko JM, Wilson KR, Wyle MJ (1991) F-6285 — a new herbicide for the pre-emergence selective control of broadleaved and grass weeds in soybeans. 1991 Bri Crop Protect Conf, pp 77-82. Google Scholar
Van Saun WA, Bahr JT, Bourdouxhe LJ, Gargantiel FJ, Hotzman FW, Shires SW, Sladen NA, Tutt SF, Wilson KR (1993) F-8426 — a new, rapidly acting, low rate herbicide for the post-emergence selective control of broad-leaved weeds in cereals. 1993 Bri Crop Protect Conf, pp 19-22. Google Scholar
Wehtje G, Walker RH, Grey TL, Spratlin CE (1995) Soil effects of sulfentrazone. Proc Southern Weed Sci Soc 48:224. Google Scholar
Yoshida R, Sakaki M, Sato R, Haga T, Nagano E, Oshio H, Kamoshita K (1991) S-53482 — a new N-phenylphthalimide herbicide. 1991 Bri Crop Protect Conf, pp 69-75. Google Scholar
Yoshimura T, Ugai S, Nagato S, Hori M, Hirai K, Yano T, Ejiri E (1992) Proceedings of the 17th congress of the Pesticide Science of Japan, 48. Google Scholar