Karakteristik CO₂ saat gerhana matahari 83,16% di Yogyakarta telah dilakukan. Penelitian ini bertujuan untuk mengetahui proses perubahan kadar CO₂ pada saat gerhana matahari. Penelitian ini menggunakan metode eksperimen. Pengumpulan data dilakukan dengan bantuan sensor CO₂ Logger Pro. Metode analisis penelitian ini menggunakan analisis grafik. Dari hasil ekperimen diperoleh bahwa rata-rata kadar CO₂ meningkat dari 659,0932 ppm menjadi 662,632 ppm, dan setelah terjadi gerhana matahari rata-rata kadar CO₂ kembali turun menjadi 654,702 ppm.

Anggraeni, S., Diana, S., & Supriatno, B. (2017). Effects total solar eclipse to nasty behaviour of the several legume plants as a result student research. Journal of Physics: Conference Series, 895, 012123.

Bullett, T., & Mabie, J. (2018). Vertical and oblique ionosphere sounding during the 21 august 2017 solar eclipse. Geophysical Research Letters, 45(8), 3690-3697.

Dang, T., Lei, J., Wang, W., Zhang, B., Burns, A., Le, H., Wan, W. (2018). Global responses of the coupled thermosphere and ionosphere system to the august 2017 great american solar eclipse. Journal of Geophysical Research: Space Physics, 123(8), 7040-7050.

Durelle, J., Jones, J., Merriman, S., & Balan, A. (2017). A smartphone-based introductory astronomy experiment: Seasons investigation. The Physics Teacher, 55(2), 122-123.

Harding, B. J., Drob, D. P., Buriti, R. A., & Makela, J. J. (2018). Nightside detection of a large scale thermospheric wave generated by a solar eclipse. Geophysical Research Letters, 45(8), 3366-3373.

Kasim, D. (2018). Fikih Gerhana: Menyorot fenomena gerhana perspektif hukum islam dulsukmi. Jurnal Pemikiran Hukum Islam, 14(1), 41-62.

Kim, J.-H., & Chang, H.-Y. (2018). Statistical analysis of geomagnetic field variations during solar eclipses. Advances in Space Research, 61(8), 2040-2049.

Laesanpura, A., Hidayat, T., Abdurachman, D., Mahasena, P., Premadi, P. W., Wulandari, H., … Sjarmidi, A. (2016). Micro-gravity measurements during the total solar eclipse of 9 march 2016 in Indonesia. Journal of Physics: Conference Series, 771, 012003.

Lin, C. Y., Deng, Y., & Ridley, A. (2018). Atmospheric gravity waves in the ionosphere and thermosphere during the 2017 solar eclipse. Geophysical Research Letters, 45(11), 5246-5252.

Mujab, S. (2014). Gerhana: Antara mitos, sains, dan islam. Yudisia, 5(1), 187-191.

Pradipta, R., Yizengaw, E., & Doherty, P. (2018). Ionospheric density irregularities, turbulence, and wave disturbances during the total solar eclipse over North America on 21 august 2017. Geophysical Research Letters, 45(16), 7909-7917.

Pramudya, Y., & Arkanuddin, M. (2016). The sky brightness measurement during the 2016 solar eclipse in Ternate. Journal of Physics: Conference Series, 771, 012013.

Riza, L. S., Wihardi, Y., Nurdin, E. A., Ardi, N. D., Asmoro, C. P., Wijaya, A. F. C., Nandiyanto, A. B. D. (2016). Analysis on atmospheric pressure, temperature, and wind speed profiles during total solar eclipse 9 march 2016 using time series clustering. Journal of Physics: Conference Series, 771, 012009.

Ruhimat, M., Winarko, A., Nuraeni, F., Bangkit, H., Aris, M. A., Suwardi, & Sulimin. (2016). Effect of march 9, 2016 total solar eclipse on geomagnetic field variation. Journal of Physics: Conference Series, 771, 012036.

Sambandan, K., Devi, K. S., Kumar, S. S., Nancharaiah, M., & Dhatchanamoorthy, N. (2014). Effects of solar eclipse on photosynthesis of Portulaca oleracea and Phyla nodiflora in coastal wild conditions. Journal of Phytology, 4(2), 34-40.

Shanida, S. S., Lestari, T. H., & Partasasmita, R. (2016). The effect of total solar eclipse on the daily activities of Nasalis larvatus (Wurmb.) in Mangrove Center, Kariangau, East Kalimantan. Journal of Physics: Conference Series, 771, 012017.

Taylor, J. H. (2008). Radiation exchange: An introduction. California: Elsevier Science.

Verhulst, T. G. W., & Stankov, S. M. (2018). Ionospheric wave signature of the American solar eclipse on 21 August 2017 in Europe. Advances in Space Research, 61(9), 2245-2251.