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Abstract

Penyebaran spesies Kaliandra sp Di Taman Nasional Gunung Ciremai dipengaruhi oleh iklim mikro Kawasan tersebut. Penelitian ini bertujuan untuk menganalisis iklim mikro yaitu suhu dan kelembaban udara di Kawasan Taman Nasional Gunung Ciremai lebih tepatnya pada tegakan hutan yang didominasi oleh Spesies Kaliandra sp. metode yang digunakan adalah Purposive Sampling berdasarkan interval ketinggian 50 m dari ketinggian tempat 1.100-1.300 mdpl yang pada setiap interval ketinggian terdapat 20 titik pengamatan suhu dan kelembaban udara yang dilakukan dari pagi hari, siang hari, dan sore hari  yang dakumulasikan pada setiap bulan. Kemudian analisis data yang digunakan adalah dengan uji regresi linear berganda untuk mengetahui pengaruh ketinggian dengan suhu rata-rata dan kelembaban udara rata-rata di tegakan Kaliandra sp. Hasil pada penelitian ini adalah selama lima bulan, suhu rata-rata harian menunjukkan perbedaan antara 1.100 dan 1.150, sedangkan ketinggian lainnya tidak berubah secara signifikan dan cenderung turun. Sedangkan pada tiga bulan pertama kelembaban rata-rata harian meningkat, tetapi cenderung turun pada bulan Oktober. Hasil analisis regresi linier berganda diperoleh persamaan regresi Y= 26,07 – 0,853 Suhu Rata-rata – 7,07 Kelembaban Rata-rata menjelaskan bahwa variabel dari iklim mikro memiliki korelasi yang negatif dalam mempengaruhi ketinggian tempat di tegakan Kaliandra sp., setiap peningkatan ketinggian tempat berdampak terhadap penurunan suhu dan kelembaban.

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How to Cite
Aminudin, S., & Ismail, A. Y. (2021). Analisis Iklim Mikro Di Hutan Sub Montana Taman Nasional Gunung Ciremai : Pengaruh Tegakan Hutan Kaliandra sp. Edubiologica: Jurnal Penelitian Ilmu Dan Pendidikan Biologi, 9(1), 12-17. https://doi.org/10.25134/edubiologica.v9i1.10234

References

  1. Beusekom, A.E.V., Grizelle, G., María, M.R. 2023. Tropical Forest Microclimatic Changes: Hurricane, Drought, and 15–20 Year Climate Trend Effects on Elevational Gradient Temperature and Moisture. Forests, 14, 325. https://doi.org/10.3390/f14020325.
  2. Handayani, A., Ervizal, A.M.Z., Decky, I.J. 2021. Assessing the utilization of naturalized alien plant species by community to inform its management strategy: A case study in Cibodas Biosphere Reserve, West Java, Indonesia. Biodiversitas, 22(7), 2579-2588. 10.13057/biodiv/d220705.
  3. Handoko, Nasir, A., June, T., Hidayati, R. 1994. Klimatologi Dasar. Bogor: Pustaka Jaya.
  4. Fauziah, C.A., Siti, B.R., Hendra, G. 2019. Kondisi Iklim Mikro Di Taman Keanekaragaman Hayati Mekarsari Kabupaten Sukabumi Jawa Barat. Jurnal Penelitian Hutan dan Konservasi Alam, 16(1), 1-12. https://doi.org/10.20886/jphka.2019.16.1.1-1210.20886/jphka.2018.15.1.1-13.
  5. Fornoff, F., Michael, S., Chao-Dong, Z., Alexandra-Maria, K. 2021. Multi‑trophic communities re‑establish with canopy cover and microclimate in a subtropical forest biodiversity experiment. Oecologia 196:289–301. https://doi.org/10.1007/s00442-021-04921-y.
  6. Helmer, E.H., Gerson, E.A., Baggett, L.S., Benjamin, J.B., Thomas, S.R., Shannon, M.V. 2019. ) Neotropical cloud forests and pa´ramo to contract and dry from declines in cloud immersion and frost. PLoS ONE. 14(4): e0213155. https://doi.org/10.1371/journal.pone.0213155
  7. Ismail, A.Y., Toto, S., Cecep, K., Yayan, S., Sukron, A., Yayan, H., Ai, N. 2022. Phenology of flowering and fruiting of Calliandra (Calliandra spp.) species in submontane forest, Indonesia. Res. Crop. 23(1), 172-179. 10.31830/2348-7542.2022.024.
  8. Karyaningsih, I., Yayan, H., Iwan, K. 2021. eanekaragaman Makrofauna Tanah Di Zona Rehabilitasi Taman Nasional Gunung Ciremai Blok Pasirbatang Desa Karangsari Kabupaten Kuningan. Quagga, 60-67. 0.25134/quagga.v13i1.352.
  9. Kumar, M., Gladwin, J., Yangchenla, B., Jagdish, K. 2023. Contrasting sap flow characteristics between pioneer and late-successional tree species in secondary tropical montane forests of Eastern Himalaya, India. Journal of Experimental Botany, Vol. 74, No. 17 pp. 5273–5293. https://doi.org/10.1093/jxb/erad207.
  10. Lolila, N.J., Deo, D.S., Ernest, W.M. 2023. Tree species composition along environmental and disturbance gradients in tropical sub-montane forests, Tanzania. PLoS ONE 18(3): e0282528. https://doi.org/10.1371/journal.pone.0282528.
  11. Mardiatmoko, G. 2020. Pentingnya Ujiasumsiklasik Padaanalisis Regresi Linierberganda (Studi Kasus Penyusunan Persamaan Allometrik Kenari Muda [Canarium indicum L.]). Barekeng, 14(3), 333-342. https://doi.org/10.30598/barekengvol14iss3pp333-342.
  12. Meragiaw, M., Zerihun, W., Vegard, M., Bal, R.S. 2021. Floristic composition and structure of the Kibate Forest along environmental gradients in Wonchi, Southwestern Ethiopia. J. For. Res. 32:2669–2682 https://doi.org/10.1007/s11676-021-01305-z.
  13. Nagaike, T. 2023. Homogenization and Differentiation under Deer Grazing in a Subalpine Zone in Central Japan. Diversity, 15, 192. https://doi.org/10.3390/d15020192.
  14. Prevosto, B., Manon, H., Jordane, G., Catherine, F., Philippe, B. 2020. Microclimate in Mediterranean pine forests: What is the influence of the shrub layer?. Agricultural and Forest Meteorology, 282-283, 107856. https://doi.org/10.1016/j.agrformet.2019.107856
  15. Rosianty, Y., Delfy, L., Pini, H. 2018. Pengaruh Sebaran Vegetasi Terhadap Suhu Dan Kelembaban Pada Taman Wisata Alam (TWA) Punti Kayu Kota Palembang. Sylva, 7(2), 68-77.
  16. Sainge, M.N., Gildas, P.T.M., David, K., Andrew, F.N., Ngoh, M.L. 2019. Vegetation, floristic composition and structure of a tropical montane forest in Cameroon. African Biodiversity and Conservation, 49(1),
  17. Singh, S., Bikarma, S., Opender, S., Mudasir, N.B., Bishander, S., Carmelo, M.M. 2021. Fragmented Forest Patches in the Indian Himalayas Preserve Unique Components of Biodiversity: Investigation of the Floristic Composition and Phytoclimate of the Unexplored Bani Valley. Sustainability, 13, 6063. https://doi.org/10.3390/su13116063.
  18. Teshnehdel, S., Hasan, A., Elisa, D.G., Robert, D.B. 2020. Effect of tree cover and tree species on microclimate and pedestrian comfort in a residential district in Iran. Building and Environment, 128, 106899. https://doi.org/10.1016/j.buildenv.2020.106899.
  19. Usodri, k.S., Dimas, P.W., Dedi, S. 2022. Hubungan Antar Beberapa Unsur Iklim Mikro Pada Produksi Tanaman Karet (Hevea brasiliensis) Klon PB260. Jurnal Agrosains dan Teknologi, 7(2), 75-80. http://dx.doi.org/10.21776/ub.jpt.2021.006.2.3
  20. Wang, S., Li, Q., Fang, C., & Zhou, C. 2016. The relationship between economic growth, energy consumption, and CO2 emissions: empirical evidence from China. Science of The Total Environment, 360–371.
  21. Zang, Y., Lixing, C., Chen, S., Yunchao, F., Yibing, X. 2023. An investigation of the influence of the morphological indexes of trees on the outdoor microclimate at high altitude in summer. Front. Environ. Sci. 11:1098966. 10.3389/fenvs.2023.1098966.