Journal of Resources and Ecology ›› 2021, Vol. 12 ›› Issue (2): 254-259.DOI: 10.5814/j.issn.1674-764x.2021.02.011
• Land Use Change and Land Multifunction Tradeoffs • Previous Articles Next Articles
INAGAKI Hidehiro*(), UNNO Nahoko, SAKAKIBARA Takumi, KUBOTA Sakiko, HASEGAWA Kana
Received:
2020-03-19
Accepted:
2020-10-20
Online:
2021-03-30
Published:
2021-05-30
Contact:
INAGAKI Hidehiro
INAGAKI Hidehiro, UNNO Nahoko, SAKAKIBARA Takumi, KUBOTA Sakiko, HASEGAWA Kana. Effect of Japanese knotweed (Fallopia japonica) Mulching on Continuous Potato Cropping: Modern Evaluation of Traditional Japanese Knotweed-mulch Farming in Nishi-Awa Steep Slope Land Agriculture System, Japan[J]. Journal of Resources and Ecology, 2021, 12(2): 254-259.
Add to citation manager EndNote|Ris|BibTeX
URL: http://www.jorae.cn/EN/10.5814/j.issn.1674-764x.2021.02.011
Soil | Mulching | Plant height (cm) | Stem length (cm) | Plant fresh weight (g) | Plant dry weight (g) | Photosynthesis efficiency (%) | Chlorophyll content values (SPAD) |
---|---|---|---|---|---|---|---|
Continuous cropping soil | Japanese knotweed | 34.1±11.2 | 43.1±9.1 | 135.4±14.1 | 11.7±1.0 | 68.4±0.8 | 30.5±2.0 |
silver grass | 32.9±6.7 | 42.6±4.9 | 121.3±12.1 | 10.6±0.8 | 64.0±7.9 | 32.1±5.0 | |
Non-treated (control) | 32.3±11.2 | 42.4±6.1 | 128.0±20.8 | 11.7±1.9 | 67.6±2.7 | 31.3±2.3 | |
Uncultivated soil | Japanese knotweed | 38.0±6.8 | 37.3±5.9 | 122.5±20.4 | 10.7±1.6 | 64.6±2.6 | 28.1±2.0 |
silver grass | 38.3±7.9 | 38.3±5.1 | 123.6±10.6 | 10.5±0.5 | 65.6±1.9 | 29.4±2.2 | |
Non-treated (control) | 35.1±3.5 | 34.0±4.4 | 114.4±18.9 | 10.0±1.4 | 67.6±1.6 | 32.4±2.8 | |
Sig. of ANOVA | ns | ns | ns | ns | ns | ns |
Table 1 The effect of grass mulching on potato growth under conditions of continuous cropping
Soil | Mulching | Plant height (cm) | Stem length (cm) | Plant fresh weight (g) | Plant dry weight (g) | Photosynthesis efficiency (%) | Chlorophyll content values (SPAD) |
---|---|---|---|---|---|---|---|
Continuous cropping soil | Japanese knotweed | 34.1±11.2 | 43.1±9.1 | 135.4±14.1 | 11.7±1.0 | 68.4±0.8 | 30.5±2.0 |
silver grass | 32.9±6.7 | 42.6±4.9 | 121.3±12.1 | 10.6±0.8 | 64.0±7.9 | 32.1±5.0 | |
Non-treated (control) | 32.3±11.2 | 42.4±6.1 | 128.0±20.8 | 11.7±1.9 | 67.6±2.7 | 31.3±2.3 | |
Uncultivated soil | Japanese knotweed | 38.0±6.8 | 37.3±5.9 | 122.5±20.4 | 10.7±1.6 | 64.6±2.6 | 28.1±2.0 |
silver grass | 38.3±7.9 | 38.3±5.1 | 123.6±10.6 | 10.5±0.5 | 65.6±1.9 | 29.4±2.2 | |
Non-treated (control) | 35.1±3.5 | 34.0±4.4 | 114.4±18.9 | 10.0±1.4 | 67.6±1.6 | 32.4±2.8 | |
Sig. of ANOVA | ns | ns | ns | ns | ns | ns |
Soil | Mulching | Plant height (cm) | Stem length (cm) | Plant fresh weight (g) | Plant dry weight (g) | Photosynthesis efficiency (%) | Chlorophyll content values (SPAD) |
---|---|---|---|---|---|---|---|
Continuous cropping soil | Japanese knotweed | 33.5±1.5 | 38.0±2.0 | 179.8±28.3 b | 35.3±1.7 a | 58.3±0.6 ab | 31.5±1.6 b |
Non-treated (control) | 28.0±2.0 | 29.0±2.0 | 137.5±22.5 c | 24.3±2.2 b | 48.0±8.2 b | 29.2±3.0 b | |
Uncultivated soil | Japanese knotweed | 22.5±2.5 | 28.5±3.5 | 211.3±19.8 a | 33.1±3.0 a | 65.7±2.5 a | 34.5±2.3 ab |
Non-treated (control) | 29.5±15.5 | 42.3±3.1 | 229.0±29.0 a | 37.5±5.1 a | 69.3±2.3 a | 42.0±1.6 a | |
Sig. of ANOVA | ns | ns | ** | ** | ** | * |
Table 2 Effects of Japanese knotweed mulching on potato growth following tomato cultivation
Soil | Mulching | Plant height (cm) | Stem length (cm) | Plant fresh weight (g) | Plant dry weight (g) | Photosynthesis efficiency (%) | Chlorophyll content values (SPAD) |
---|---|---|---|---|---|---|---|
Continuous cropping soil | Japanese knotweed | 33.5±1.5 | 38.0±2.0 | 179.8±28.3 b | 35.3±1.7 a | 58.3±0.6 ab | 31.5±1.6 b |
Non-treated (control) | 28.0±2.0 | 29.0±2.0 | 137.5±22.5 c | 24.3±2.2 b | 48.0±8.2 b | 29.2±3.0 b | |
Uncultivated soil | Japanese knotweed | 22.5±2.5 | 28.5±3.5 | 211.3±19.8 a | 33.1±3.0 a | 65.7±2.5 a | 34.5±2.3 ab |
Non-treated (control) | 29.5±15.5 | 42.3±3.1 | 229.0±29.0 a | 37.5±5.1 a | 69.3±2.3 a | 42.0±1.6 a | |
Sig. of ANOVA | ns | ns | ** | ** | ** | * |
1 | Cambouris A N, Zebarth B J, Nolin M C , et al. 2008. Apparent fertilizer nitrogen recovery and residual soil nitrate under continuous potato cropping: Effect of N fertilization rate and timing. Canadian Journal of Soil Science, 88(5):813-825. |
2 | Davis J R, Pavek J, Corsini D L , et al. 1994. Influence of continuous cropping of several potato clones on the epidemiology of Verticillium wilt of potato. Phytopathology, 84:207-214. |
3 | Food and Agriculture Organization of the United Stations. 2020a. Globally Important Agricultural Heritage Systems (GIAHS).http://www.fao.org/giahs/en/ . |
4 | Food and Agriculture Organization of the United Stations. 2020b. Globally Important Agricultural Heritage Systems (GIAHS). Nishi-Awa Steep Slope Land Agriculture System. http://www.fao.org/giahs/giahsaround-theworld/designated-sites/asia-and-the-pacific/nishi-awa-steep-slopeland-agriculture-system/en/. |
5 | Hadama M, Kuroda Y, Kuroshima T , et al. 1996. Effects of fertilizer response and growth inhibition of weeds of Phragmites commums Trin mulching in rice cropping. Bulletin of the Tokushima Prefecture Agricultural Research Institute, 32:5-11. (in Japanese). |
6 | Hasegawa K, Kubota S, Nakatani S , et al. 2018. Evaluation of traditional Japanese knotweed mulch farming in the Nishi-Awa steep slope-land agriculture system, Japan. Proceedings of the 5th Conference of East Asia Research Association for Agricultural Heritage Systems. https://www.giahs-minabetanabe.jp/erahs/assets/pdf/Poster05_SouNakatani.pdf. |
7 | Hayashi H . 2015. Globally Important Agricultural Heritage Systems in Tsurugi-san area, Yoshinogawa, Japan. . (in Japanese) |
8 | Inagaki H, Hasegawa K, Kubota S, et al. 2019. Effects of Japanese knotweed mulch farming on cultivation of eggplants. Japanese Journal of Organic Agriculture Science, 11(1):32-37. (in Japanese) |
9 | Inagaki H, Kusumoto Y . 2015. Assessment of GIAHS in Shizuoka: The traditional tea-grass integrated system. Journal of Resources and Ecology, 5(4):398-401. |
10 | Jankowska B, Poniedziałek M, Jędrszczyk E . 2009. Effect of intercropping white cabbage with French Marigold (Tagetes patula nana L.) and Pot Marigold(Calendula officinalis L.) on the colonization of plants by pest insects. Folia Horticulturae, 21(1):95-103. |
11 | Qin S H, Cao L, Zhang J L , et al. 2014. Effect of rotation of leguminous plants on soil available nutrients and physical and chemical properties in continuous cropping potato field. Acta Agronomica Sinica, 40(8):1452-1458 |
12 | Reeves D W . 1997. The role of soil organic matter in maintaining soil quality in continuous cropping systems. Soil and Tillage Research, 43(1-2):131-167. |
13 | Tabuchi H, Kawarazaki H, Kuwamura T , et al. 2017. Effect of continuous cropping system with continuous utilization of organic matters on the growth of cabbage ( Brassica oleracea var. capitata) and the chemical properties of soil in upland field. Japanese Journal of Organic Agriculture Science, 9(1):69-78. |
14 | Tokushima Tsurugisan Globally Important Agricultural Heritage Promotion Council. 2019. Globally recognized agriculture and living in Nishi-Awa. https://giahs-tokushima.jp/giahs/wp-content/uploads/2019/04/e4e9f93fa0bc3068507c3b479e3a0d91.pdf. |
15 | United Station University . 2011. Japanese agricultural heritage systems recognized.https://ourworld.unu.edu/en/japanese-agricultural-heritage-systems-recognized. |
16 | Unno N, Inagaki H . 2019. Effects of pelletized Japanese knotweed on yields, quality of fruits, and disease suppression of Tomato. Proceedings of the 20th Conference of the Japanese society of organic agriculture science, 101-102. |
17 | Unno N, Seoka S, Noyori Y , et al. 2020. Effect of Japanese knotweed (Fallopia japonica) mulching on continuous cropping and fruit quality of tomato. Proceedings of the 59th Conference of the Weed Science Society of Japan. |
18 | Wang M Y, Wu C N, Cheng Z H , et al. 2014. Soil chemical property changes in eggplant/garlic relay intercropping systems under continuous cropping. Plos One, 9(10):e111040. DOI: 10.1371/journal.pone.0111040. |
19 | Xiao X M, Cheng Z H, Meng H W , et al. 2012. Intercropping with garlic alleviated continuous cropping obstacle of cucumber in plastic tunnel. Acta Agriculturae Scandinavica, Section B—Soil & Plant Science, 62:696-705. |
20 | Xiao X M, Cheng Z H, Meng H W , et al. 2013. Intercropping of green garlic (Allium sativum L.) induces nutrient concentration changes in the soil and plants in continuously cropped cucumber( Cucumis sativus L.) in a plastic tunnel. Plos One. 8(4):e62173. DOI: 10.1371/journal.pone.0062173. |
21 | Yamada M . 2001. Methods of control of injury associated with continuous vegetable cropping in Japan—Crop rotation and several cultural practices. Japan Agricultural Research Quarterly, 35(1):39-45. |
[1] | ZHOU Kaisheng. Prevention and Control of Continuous Cropping Obstacle of Watermelon by Reductive Soil Disinfestation (RSD) [J]. Journal of Resources and Ecology, 2018, 9(5): 493-499. |
[2] | KUSUMOTO Yoshinobu, INAGAKI Hidehiro. Symbiosis of Biodiversity and Tea Production Through Chagusaba [J]. Journal of Resources and Ecology, 2016, 7(3): 151-154. |
[3] | Park Yoon-Ho, Yoon Won-Keun, Gordon Dabinett. A Study of the Improvement of Planning Systems for Land Use Control in Agricultural Heritage Sites [J]. Journal of Resources and Ecology, 2016, 7(3): 180-186. |
[4] | ZHANG Yongxun, MIN Qingwen, JIAO Wenjun, LIU Moucheng. Values and Conservation of Honghe Hani Rice Terraces System as a GIAHS Site [J]. Journal of Resources and Ecology, 2016, 7(3): 197-204. |
[5] | QIU Zhenmian, CHEN Bixia, NAKAMURA Koji. Customary Management System of Irrigation Ponds in Japan-a Case Study in a Globally Important Agricultural Heritage Systems (GIAHS) Site of Noto Island, Ishikawa Prefecture [J]. Journal of Resources and Ecology, 2016, 7(3): 205-210. |
[6] | LI Jing, JIAO Wenjun, MIN Qingwen, LI Wenhua. Effects of Traditional Ecological Knowledge on the Drought- resistant Mechanisms of the Hani Rice Terraces System [J]. Journal of Resources and Ecology, 2016, 7(3): 211-217. |
[7] | NILES Daniel, ROTH Robin. Conservation of Traditional Agriculture as Living Knowledge Systems, Not Cultural Relics [J]. Journal of Resources and Ecology, 2016, 7(3): 231-236. |
[8] | HE Xiahong, ZHU Shusheng, WANG Haining, XIE Yong, SUN Yan, GAO Dong, YANG Jing, LIU Lin, LI QiXin, ZHANG Shaobo, ZHAO Gaohui, HU Mingcheng, JIANG Kaimei, LI Chengyun, ZHU Youyong. Crop Diversity for Ecological Disease Control in Potato and Maize [J]. Journal of Resources and Ecology, 2010, 1(1): 45-50. |
Viewed | ||||||
Full text |
|
|||||
Abstract |
|
|||||