Evaluating the Miyawaki Afforestation Technique in Urban Landscapes: Opportunities and Challenges

Osman Zeybek

doi:10.15320/ICONARP.2025.326

Authors

Osman Zeybek Bursa Uludağ Üni̇versi̇tesi̇ https://orcid.org/0000-0002-2752-407X

DOI:

https://doi.org/10.15320/ICONARP.2025.326

Keywords:

Green spaces, Miyawaki method, Urban research, Urban ecology, SDG11

Abstract

Urban landscapes are increasingly dominated by impermeable surfaces, leading to significant ecological degradation, biodiversity loss, and urban heat island effects. The Miyawaki Afforestation Technique has gained attention as a potential solution for restoring urban green spaces by rapidly creating dense, biodiverse forests. This paper evaluates the potential and limitations of the Miyawaki method in the context of urban planning, with a focus on its ecological, social, and economic implications. While the method offers rapid forest establishment, increased biodiversity, and improved air quality, its applicability in varying climatic and urban conditions remains controversial. Issues such as land availability, maintenance intensity, and public perception of untamed green spaces present challenges for widespread adoption.

Additionally, the need for substantial soil preparation raises concerns regarding cost and feasibility in dense urban environments. This study critically examines these factors, proposing a balanced perspective on the Miyawaki method's role in contemporary urban design. The findings suggest that while the technique holds promise for enhancing urban sustainability, its integration into planning policies requires careful consideration of spatial, financial, and social dynamics.

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Author Biography

Osman Zeybek, Bursa Uludağ Üni̇versi̇tesi̇

Osman ZEYBEK graduated from Ege University, Faculty of Agriculture, Department of Landscape Architecture in 2009. He completed his postgraduate educations at Ankara University and received his doctorate in 2022. He worked as an academic staff at Cumhuriyet University and Ankara University and has been continuing his academic studies at Bursa Uludag University for the last 6 years.

References

Aarthi, R., Begum, A. S., Yaswanthshahi, S. K., Avinashreddy, Y. & Sharfuddin, S. K. (2021). Miyawaki Forest Automation and Unauthorized Restrictions. Annals of the Romanian Society for Cell Biology, 25 (4): 12372-12380.

Agnihotri, V. (2022). Paradigm Shifts from Social Forestry to Urban Forestry: A Synergy to Mitigate Urban Heat Island in High-Density Developments. Journal of Applied and Physical Sciences, 8: 24 – 32.

Anand, A. V., Sreedevi, M. J. & Swapna, T. S. (2023). Plant Conservation Associated with Traditional Knowledge: Past and Future. In Conservation and Sustainable Utilization of Bioresources (pp. 261-290). Springer Nature, Singapore.

Anderson, J. T. & Song, B. H. (2020). Plant adaptation to climate change—Where are we? Journal of Systematics and Evolution, 58 (5): 533 – 545.

Anonymous 2024. Urban Forests. Website: https://urban-forests.com/miyawaki-method/. Retrieved: 10.06.2024.

Breuste, J., Pauleit, S., Haase, D., Sauerwein, M. & Breuste, J. (2021). What Are the Special Features of the Urban Habitat and How Do We Deal with Urban Nature? In: Urban Ecosystems: Function, Management and Development, 107-164. https://doi.org/10.1007/978-3-662-63279-6_4

Bruns, M., Bleichrodt, D., Laine, E., van Toor, K., Dieho, W., Postma, L. & de Groot, M. (2019). Tiny forest planting method. IVN Natuur Educatie, NL.

Charkow, M. (2022). Forests for the future. The Arboricultural Association Magazine, Issue 197: 29 – 33.

Churkina, G., Organschi, A., Reyer, C. P., Ruff, A., Vinke, K., Liu, Z., Reck, B. K.; Graedel, T. E. & Schellnhuber, H. J. (2020). Buildings as a global carbon sink. Nature Sustainability, 3(4), 269-276.

Czaja, M., Kołton, A. & Muras, P. (2020). The complex issue of urban trees—Stress factor accumulation and ecological service possibilities. Forests, 2020, 11: 932.

Daou, A., Saliba, M. & Kallab, A. (2024). A Review of the Miyawaki Method. Website: https://papers.ssrn.com/sol3/papers.cfm?abstract_id=4728239. Retrieved: 10.06.2024.

Dhanorkar, R., Bodhe, N., Ansari, E., Wagh, P. & Kale, M. (2023). Growth Performance of Planted Native Species at Aforestation Site. International Journal of Researches in Biosciences, Agriculture and Technology, 11 (1): 16 – 20.

Ding, Y., Nie, Y., Chen, H., Wang, K. & Querejeta, J. I. (2021). Water uptake depth is coordinated with leaf water potential, water‐use efficiency and drought vulnerability in karst vegetation. New Phytologist, 229: 1339 – 1353.

Elliott, S., Tucker, N. I., Shannon, D. P. & Tiansawat, P. (2023). The framework species method: Harnessing natural regeneration to restore tropical forest ecosystems. Philosophical Transactions of the Royal Society B, 378: 20210073.

Fratini, F. (2023). The Eco-Pedagogical Microforest a shared Oasis of proximity. A cutting-edge project at the intersection of ecology, urbanism and pedagogy. TEMA Journal of Land Use, Mobility and Environment, Special Issue 1: 1 – 22.

Guo, X. (2018). Effects of different forest reconstruction methods on characteristics of understory vegetation and soil quality. Applied Ecology and Environmental Research, 16(6), 7501-7517. https://doi.org/10.15666/aeer/1606_75017517

Hanpattanakit P., Kongsaenkaew P., Pocksorn A., Thanajaruwittayakorn W., Detchairit W. & Limsakul A., (2022). Estimating Carbon Stock in Biomass and Soil of Young Eco-Forest in Urban City, Thailand, Chemical Engineering Transactions, 97, 427-432. DOI: 10.3303/CET2297072.

Hara, M. (2023). Phytogeography and history of Japanese beech forests: Recent advances and implications for vegetation ecology. Ecological Research, 38 (2): 218 – 235.

Huber, M., Nieuwendijk, N. M., Pantazopoulou, C. K. & Pierik, R. (2021). Light signalling shapes plant–plant interactions in dense canopies. Plant, Cell & Environment, 44(4), 1014-1029.

Hulme, P. E. (2020). Plant invasions in New Zealand: global lessons in prevention, eradication and control. Biological invasions, 22: 1539 – 1562.

Kais, K., Gołaś, M. & Suchocka, M. (2021). Awareness of Air Pollution and Ecosystem Services Provided by Trees: The Case Study of Warsaw City. Sustainability, 2021, 13: 10611.

Khan, S., Masoodi, T. H., Islam, M. A., Arjumand, T., Raja, A., Parrey, A. A., Pallavi, A. & Bhat, J. H. (2024). Ecosystem Degradation to Restoration: A Challenge. In Climate Crisis: Adaptive Approaches and Sustainability (pp. 19-33). Cham: Springer Nature Switzerland.

Kiboi, S., Fujiwara, K., & Mutiso, P. (2014). Sustainable management of urban green environments: challenges and opportunities., 223-236. https://doi.org/10.1007/978-4-431-54804-1_18

Kohout, M. & Kopp, J. (2020). Green space ideas and practices in European cities. Journal of Environmental Planning and Management, 63(14), 2464-2483.

Kong, W., Wei, X., Wu, Y., Shao, M., Zhang, Q., Sadowsky, M., … & Liu, L. (2022). Afforestation can lower microbial diversity and functionality in deep soil layers in a semiarid region. Global Change Biology, 28(20), 6086-6101. https://doi.org/10.1111/gcb.16334

Kurian, A. L. (2020). Urban Heat Island Mitigation and Miyawaki Forests: An Analysis. Poll. Res. 39 (November Suppl. Issue): 186 – 191.

Lagariya, V. J. & Kaneria, M. J. (2021). Ethnobotanical Profiling and Floristic Diversity of the Miyawaki Plantation in Saurashtra University Campus, Rajkot. Journal of Drug Delivery and Therapeutics, 11 (2): 87 – 99.

Lee, C. (2023). Miyawaki Method: A Game-Changer for Urban Reforestation? Website: https://www.fairplanet.org/story/miyawaki-method-a-game-changer-for-urban-reforestation. Accessed: 17.02.2025.

Lewis, H. (2022). Mini-Forest Revolution: Using the Miyawaki Method to Rapidly Rewild the World. Terra Nuova, Italy. Website: efaidnbmnnnibpcajpcglclefindmkaj/https://media.terranuovalibri.it/pdf_incipit/terra-nuova-edizioni/mini-forest-revolution-236690.pdf. Retrieved: 04.10.2023.

Li, F., Guo, S., Li, D., Li, X., Li, J. & Xie, S. (2020). A multi-criteria spatial approach for mapping urban ecosystem services demand. Ecological Indicators. Ecological Indicators, 112 (2020): 106119.

Li, Z. & Hu, D. (2022). Exploring the relationship between the 2D/3D architectural morphology and urban land surface temperature based on a boosted regression tree: A case study of Beijing, China. Sustainable Cities and Society, 78 (2022): 103392.

Liu, O. Y. & Russo, A. (2021). Assessing the contribution of urban green spaces in green infrastructure strategy planning for urban ecosystem conditions and services. Sustainable Cities and Society, 68. Art 102772.

Mandowara, R. (2022). Miyawaki Forests. International Journal of Advanced Research in Arts, Science, Engineering & Management, 9 (3): 978 – 984.

Maurya, K., Mahajan, S. & Chaube, N. (2021). Remote sensing techniques: Mapping and monitoring of mangrove ecosystem—A review. In Complex & Intelligent Systems, Springer, 2797 – 2818.

Meguro, S., Chalo, D. M. & Mutiso, P. B. C. (2021). Growth Characteristics of Selected Potential Natural Vegetation in Kenya: The Afromontane Forest Restoration Program Based On The Miyawaki Method. Eco-Habitat, 27 (1): 87 – 94.

Miyawaki A (1999) Creative ecology: restoration of native forests by native trees. Plant Biotechnol 16(1):15–25

Miyawaki A (2004) Restoration of living environment based on vegetation ecology: theory and practice. Ecol Res 19:83–90

Miyawaki A, Fujiwara K, Ozawa M (1993) Native forest by native trees: restoration of indigenous forest ecosystem: (reconstruction of environmental protection forest by Prof. Miyawaki’s method). Bull Inst Environ Sci Technol 19:72–107.

Morino Project, 2024. International Symposium: Miyawaki Forests and Urban Forests－ Towards the Creation of Miyawaki Forests as Nature Labs in Schools. Website: https://morinoproject.com/international-symposium-2024_miyawaki-forests_urban-forests. Accessed: 7.12.2024.

Nakhforoosh, A., Nagel, K. A., Fiorani, F. & Bodner, G. (2021). Deep soil exploration vs. topsoil exploitation: Distinctive rooting strategies between wheat landraces and wild relatives. Plant and Soil, 459: 397 – 421. Springer.

Nayak, P. and Solanki, H. (2022). Impact of agriculture on environment and bioremediation techniques for improvisation of contaminated site. International Association of Biologicals and Computational Digest, 1(1), 163-174. https://doi.org/10.56588/iabcd.v1i1.31

O'Brien, L. E., Urbanek, R. E. & Gregory, J. D. (2022). Ecological functions and human benefits of urban forests. Urban Forestry & Urban Greening, 75 (2022): 127707.

Panchabhai, P. G. (2024). Greening Urban Landscapes: The Miyawaki Method for Enhanced Biodiversity And Carbon Sequestration In Pune, India. International Research Journal of Modernization in Engineering, Technology and Science, 6 (3): 499 – 510.

Parikh, A. & Nazrana, A. (2023). Analysis Of The Miyawaki Afforestation Technique. International Journal of Development Research, 13 (10): 63913 – 63915.

Poddar, S. (2021). Miyawaki technique of afforestation. Krishi Science-eMagazine Agricultural Sciences, 2 (9): 1 – 5.

Postma, J. A., Hecht, V. L., Hikosaka, K., Nord, E. A., Pons, T. L. & Poorter, H. (2021). Dividing the pie: A quantitative review on plant density responses. Plant, Cell & Environment, 44(4): 1072-1094.

Prasad, V. (2023). Habitat Fragmentation, “A Threat to Health And Life On Land”: A Geographical Study Of The Patna Urban Area. In A Geographical Exploration of Urban Risk and COVID-19: An Innovative and Systematic Approach, Eds: Anand, S., Srinagesh, B., Singh, R. B. Cambridge Scholars Publishing, UK. ISBN: 978-1-5275-2940-3.

Puplampu, D. A. & Boafo, Y. A. (2021). Exploring the impacts of urban expansion on green spaces availability and delivery of ecosystem services in the Accra metropolis. Environmental Challenges, 5 (2021): 100283.

Qi, W., Zhang, Q., Chen, Y., Li, X., Cheng, X., Ye, C., … & Zhang, K. (2022). Afforestation alters functions of soil and microbiome but does not drive soil carbon accumulation in two decades.. https://doi.org/10.21203/rs.3.rs-1285192/v1

Ramyar, R., Saeedi, S., Bryant, M., Davatgar, A. & Hedjri, G. M. (2020). Ecosystem services mapping for green infrastructure planning–The case of Tehran. Science of the Total Environment, 703, 135466.

Raven, P. H. & Wagner, D. L. (2021). Agricultural intensification and climate change are rapidly decreasing insect biodiversity. PNAS, 118 (2): 1 – 6.

Rewilding Academy (2024). Pros and cons of The Miyawaki concept and tiny forests. Website: https://rewilding.academy/ecosystem-restoration/pros-and-cons-of-the-miyawaki-concept-and-tiny-forests. Accessed: 17.02.2025.

Sandeep, R., Sharma, P. & Modi, N. (2022). Development Of Tree Plantation Through Miyawaki Method at Sabarmati Riverfront Development Corporation Limited-A Research. International Association of Biologicals and Computational Digest, 1(1), 163-174.

Schirone, B. & Salis, A. (2011). Effectiveness of the Miyawaki method in Mediterranean forest restoration programs. Landscape Ecol. Eng., 7: 81 – 92.

Schirone, B., Salis, A., & Vessella, F. (2010). Effectiveness of the miyawaki method in mediterranean forest restoration programs. Landscape and Ecological Engineering, 7(1), 81-92. https://doi.org/10.1007/s11355-010-0117-0

Sen, S. & Guchhait, S. K. (2021). Urban green space in India: Perception of cultural ecosystem services and psychology of situatedness and connectedness. Ecological Indicators, 123 (2021): 107338.

Sharma, R., Haq, A., Bakshi, B. R., Ramteke, M. & Kodamana, H. (2024). Designing synergies between hybrid renewable energy systems and ecosystems developed by different afforestation approaches. Journal of Cleaner Production, 434 (2024): 139804.

Staab, M., Pereira-Peixoto, M. H., & Klein, A. M. (2020). Exotic garden plants partly substitute for native plants as resources for pollinators when native plants become seasonally scarce. Oecologia, 194: 465 – 480.

Sugi Project (2024a). Greening cities & reimagining urban life. Website: https://www.sugiproject.com/. Accessed: 12.12.2024.

Sugi Project (2024b). ICHK Hong Lok Yuen Forest. Website: https://www.sugiproject.com/forests/ichk-hong-lok-yuen-forest. Accessed: 12.12.2024.

Sugi Project (2024c). Southbank Centre – Natura Nostra Forest. Website: https://www.sugiproject.com/forests/southbank-natura-nostra-forest?_gl=1*1j3d0bn*_up*MQ..*_ga*MTU5NTAzNzExOC4xNzMzOTg1NjE0*_ga_VNGJYEV6XB*MTczMzk4NTYxMy4xLjAuMTczMzk4NTYxMy4wLjAuMA. Accessed: 12.12.2024.

Swapna, T. S. (2023). Assessment of Biodiversity and Growth Parameters of Miyawaki Forest of Selected Sites in Thiruvananthapuram District of Kerala. Website: chrome-extension://efaidnbmnnnibpcajpcglclefindmkaj/https://assets-eu.researchsquare.com/files/rs-3192725/v1_covered_d0be2cf5-ece2-4fba-ab43-2bc0b3b1c5ce.pdf?c=1690300282. Retrieved: 22.05.2024.

Tallamy, D. W. & Shriver, W. G. (2021). Are declines in insects and insectivorous birds related? Ornithological Applications, 123: 1 – 8.

Tallamy, D. W., Narango, D. L. & Mitchell, A. B. (2021). Do non‐native plants contribute to insect declines? Ecological Entomology, 46: 729 – 742.

Tian, Y., Wu, H., Zhang, G., Wang, L., Zheng, D. & Li, S. (2020). Perceptions of ecosystem services, disservices and willingness-to-pay for urban green space conservation. Journal of Environmental Management, 260, 110140.

Ullah, M. A., Hassan, A. & Hamza, A. (2023). Awareness of Miyawaki Urban Forest Plantation Method in Pakistan. American Journal of Biomedical Science & Research, 18 (2):138 – 147.

UNESCO, 2024. Miyawaki forests for urban schools. Website: https://www.unesco.org/en/articles/miyawaki-forests-urban-schools. Accessed: 7.12.2024.

Vega, K. A. & Küffer, C. (2021). Promoting wildflower biodiversity in dense and green cities: The important role of small vegetation patches. Urban Forestry & Urban Greening, 62 (2021): 127165.

Wang, Z., Huang, Y., Ankrah, V. & Dai, J. (2023). Greening the knowledge-based economies: Harnessing natural resources and innovation in information and communication technologies for green growth. Resources Policy, 86 (A): 104181.

Xiaoqin, Q. I. A. N., Zhe, L. I. U., Tianyi, Z. H. A. O., Hualin, B. A. I., Jiao, S. U. N. & Xiao, F. E. N. G. (2021). Digital Design Exploration of Nature-Approximating Urban Forest Basing on the Miyawaki Method: A Case Study of Xingtai Forest in a Hebei Green Expo Garden. Landscape Architecture Frontiers, 9 (6): 60 – 76.

Zsolnai, B. & Bajor, Z. (2021). Prelimiary Data on The First Year of First Hungarian Miyawaki-Forest In Tabán, Budapest. International Multidisciplinary Scientific GeoConference: SGEM, 21(3.2), 205-212.