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30-07-2024 | Original Research

Integrated use of field sensors, PhenoCam, and satellite data for pheno-phase monitoring in a tropical deciduous forest of Dalma Wildlife Sanctuary, Jharkhand, India: initial results from the Indian Phenology Network

Authors: C. Jeganathan, Beependra Singh, C. P. Singh, M. D. Behera, Sanjay Srivastava, S. R. Natesha, Kulwant Singh, Rajiv Ranjan, Maun Prakash, Abhishek Kumar, M. R. Pandya, B. K. Bhattacharya, A. P. Krishna, Mili Ghosh Nee Lala, V. S. Rathore, Nitish Kumar Sinha, Kiran Choudhary, Mallika Bhuyan, Sumedha Surbhi Singh, Preeti Sardar

Published in: Biodiversity and Conservation | Issue 12/2024

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Abstract

Plant phenology regulates ecosystem functions at diverse scales but is impacted by micro and macro climatic variations, and climate change. In India, precise estimations of pheno-phase transition dates remain scarce at different spatial and temporal scales, necessitating comprehensive research efforts. This study aims to gather continuous intra-day ground data about vegetation and climate conditions using PhenoCam (optical RGB and IR images) along with meteorological sensors, at Dalma Wildlife Sanctuary (DWS), Jharkhand. To derive phenological metrics, different indices were computed from images captured by PhenoCam sensors and Satellite derived Normalized Difference Vegetation Index (NDVI). Since the PhenoCam covers diverse vegetation species in the frame, the analysis was performed over three specific subset Region of Interests (ROI): Bombax ceiba (Semal) tree, background cluster of vegetation and a sample tree. MODIS NDVI data revealed that most of the area is highly deciduous with major greening in the 1st half of April and senescence during 2nd half of March. The study found that Green Chromatic Coordinate Index (G_CC) and Blue Chromatic Coordinate Index (B_CC) results could reveal greening and senescence phases correctly. The timing of start of leaf flush (SOLF), end of leaf flush (EOLF) and end of leaf maturity (EOLM) estimated based on inflection point method from Pheno-Cam images are: for Semal tree: 5th April, 2nd May, 10th June, 2022; for background vegetation: 15th March, 28th March and 2nd May, 2022; and for sample tree: 15th March, 28th March and 25th April, 2022, respectively. The dates of SOLF differed in 2023 and it occurred twice for Semal and background vegetation: for Semal tree: 20th February and 3rd April 2023, and for background vegetation: 20th January and 8th March, 2023, respectively. The rate of leaf flush and rate of leaf maturity was not similar in different years as the rates were much higher in 2023 than in 2022. The temperature and rainfall during winter and spring played an important role in greening, senescence, and its sustenance. These findings revealed the micro-climatic effect on plant phenology in the Dalma Wildlife Sanctuary, as well as the importance of integrating PhenoCam and satellite data in accurate monitoring of phenological phases.

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Alberton B, Torres RDS, Cancian LF et al (2017) Introducing digital cameras to monitor plant phenology in the tropics: applications for conservation. Perspect Ecol Conserv 15(2):82–90

Atkinson PM, Jeganathan C, Dash J, Atzberger C (2012) Inter-comparison of four models for smoothing satellite sensor time-series data to estimate vegetation phenology. Remote Sens Environ 123:400–417CrossRef

Aubry-Kientz M, Rossi V, Wagner F, Hérault B (2015) Identifying climatic drivers of tropical forest dynamics. Biogeosciences 12:5583–5596CrossRef

Badr G, Hoogenboom G, Davenport J, Smithyman J (2015) Estimating growing season length using vegetation indices based on remote sensing: a case study for vineyards in Washington state. Trans ASABE. https://doi.org/10.13031/trans.58.10845CrossRef

Borchert R (1999) Climatic periodicity, phenology, and cambium activity in tropical dry forest trees. IAWA J 20:239–247CrossRef

Bradley BA, Jacob RW, Hermance JF, Mustard JF (2007) A curve fitting procedure to derive inter-annual phenologies from time series of noisy satellite NDVIdvi data. Remote Sens Environ 106(2):137–145CrossRef

Brown TB, Hultine KR, Steltzer H et al (2016) Using phenocams to monitor our changing Earth: toward a global phenocam network. Front Ecol Environ 14(2):84–93CrossRef

Choudhury BJ (1987) Relationships between vegetation indices, radiation absorption, and netphotosynthesis evaluated by a sensitivity analysis. Remote Sens Environ 22:209–233CrossRef

Dash J, Jeganathan C, Atkinson PM (2010) The use of MERIS Terrestrial Chlorophyll Index to study spatio-temporal variation in vegetation phenology over India. Remote Sens Environ 114:1388–1402CrossRef

De Frenne P, Lenoir J, Luoto M et al (2021) Forest microclimates and climate change: importance, drivers and future research agenda. Glob Change Biol 27(11):2279–2297CrossRef

Didan K, Barreto A, Solano R, Huete A (2015) MODIS vegetation index user’s guide (MOD13 Series) version 3.00 (Collection 6)

Friedlingstein P, O’Sullivan M, Jones MW et al (2022) Global carbon budget 2022. Earth Syst Sci Data 14:4811–4900. https://doi.org/10.5194/essd-14-4811-2022CrossRef

Halim MA, Shahid A, Chowdhury MSH et al (2008) Evaluation of land-use pattern change in West Bhanugach Reserved Forest, Bangladesh, using remote sensing and GIS techniques. J For Res 19(3):193–198. https://doi.org/10.1007/s11676-008-0044-1CrossRef

Herrmann SM, Anyamba A, Tucker CJ (2005) Recent trends in vegetation dynamics in the African Sahel and their relationship to climate. Glob Environ Chang 154:394–404. https://doi.org/10.1016/j.gloenvcha.2005.08.004CrossRef

Houet T, Verburg PH, Loveland TR (2009) Monitoring and modelling landscape dynamics. Landsc Ecol 25(2):163–167CrossRef

Huete A, Didan K, Miura T et al (2002) Overview of the radiometric and biophysical performance of the MODIS vegetation indices. Remote Sens Environ 83(1–2):195–213. https://doi.org/10.1016/S0034-4257(02)00096-2CrossRef

Jaworski T, Hilszczanski J (2013) The effect of temperature and humidity changes on insects development their impact on forest ecosystems in the expected climate change. Lesn Prace Badaw 74(4):345

Jeganathan C, Dash J, Atkinson PM (2010a) Characterising the spatial pattern of phenology for the tropical vegetation of India using multi-temporal MERIS chlorophyll data. Landsc Ecol 25(7):1125–1141. https://doi.org/10.1007/s10980-010-9490-1CrossRef

Jeganathan C, Dash J, Atkinson PM (2010b) Mapping the phenology of natural vegetation in India using a remote sensing derived chlorophyll index. Int J Remote Sens 31(22):5777–5796. https://doi.org/10.1080/01431161.2010.512303CrossRef

Jeganathan C, Dash J, Atkinson PM (2014) Remotely sensed trends in the phenology of northern high latitude terrestrial vegetation, controlling for land cover change and vegetation type. Remote Sens Environ 143:154–170

Johnson ED (1926) A comparison of the juvenile and adult leaves of Eucalyptus globulus. New Phytol 25:202–212CrossRef

Kamble PN, Giri SP, Mane RS, Tiwana A (2015) Estimation of chlorophyll content in young and adult leaves of some selected plants. Univers J Environ Res Technol 5(6):306–210

Krishnaswamy J, Bonell M, Venkatesh B et al (2013) The groundwater recharge response and hydrologic services of tropical humid forest ecosystems to use and reforestation: support for the “infiltration–evapotranspiration trade-off hypothesis.” J Hydrol 498:191–209CrossRef

Kushwaha CP, Singh KP (2005) Diversity of leaf phenology in a tropical deciduous forest in India. J Trop Ecol 21(1):47–56CrossRef

Kushwaha CP, Singh KP (2008) India needs phenological stations network. Curr Sci 95(7):832–834

Kushwaha CP, Tripathi SK, Singh GS, Singh KP (2010) Diversity of deciduousness and phenological traits of key Indian dry tropical forest trees. Ann For Sci 67(3):310CrossRef

Lal HS, Ganguly S, Pramanik K, Prasanna PV, Ranjan V (2019) Plant diversity and vegetation structure in Sal (Shorea robusta Gaertn.) dominated forest of Dalma Wildlife Sanctuary, Jharkhand, India. Indian J For 42(1):83–90

Lambin EF, Strahler AH (1994) Change-vector analysis in multi-temporal space: a tool to detect and categorize land-cover change processes using high temporal-resolution satellite data. Remote Sens Environ 48:231–244CrossRef

Li C, Qi J, Yang L et al (2014) Regional vegetation dynamics and its response to climate change—a case study in the Tao River Basin in Northwestern China. Environ Res Lett 9:125003. https://doi.org/10.1088/1748-9326/9/12/125003CrossRef

Lozano IL, Sánchez-Hernández G, Guerrero-Rascado JL (2022) Analysis of cloud effects on long-term global and diffuse photosynthetically active radiation at a Mediterranean site. Atmos Res 268:106010CrossRef

Ma X, Jin J, Zhu X, Zhou Y, Xie Q (2022) Remote sensing of land surface phenology. Remote Sens 14(17):4310CrossRef

Margono BA, Turubanova S, Zhuravleva I et al (2012) Mapping and monitoring deforestation and forest degradation in Sumatra (Indonesia) using Landsat time series data sets from 1990 to 2010. Environ Res Lett 7(3):034010. https://doi.org/10.1088/1748-9326/7/3/034010CrossRef

Mishra RK, Upadhyay VP, Bal S et al (2006) Phenology of species of moist deciduous forest sites of Similipal biosphere reserve. Lyonia 11(1):5–17

Nanda A, Suresh HS, Krishnamurthy YL (2014) Phenology of a tropical dry deciduous forest of Bhadra wildlife sanctuary, southern India. Ecol Process 3:1–12CrossRef

Nemani RR, Keeling CD, Hashimoto H (2003) Climate-driven increases in global terrestrial net primary production from 1982 to 1999. Science 300(5625):1560–1563. https://doi.org/10.1126/science.1082750CrossRefPubMed

Nemani RR, Running SW (1995) Satellite monitoring of global land cover changes and their impact on climate. Climatic Change 31:395–413. https://doi.org/10.1007/BF01095154

Newton PN (1988) The structure and phenology of a moist deciduous forest in the Central Indian Highlands. Vegetatio 75:3–16CrossRef

Onwuka B, Mang B (2018) Effects of soil temperature on some soil properties and plant growth. Adv Plants Agric Res 8(1):34–37. https://doi.org/10.15406/apar.2018.08.00288CrossRef

Pande PK, Meshram PB, Banerjee SK (2002) Litter production and nutrient return in tropical dry deciduous teak forests of Satpura plateau in central India. Trop Ecol 43(2):337–344

Paruelo JM, Burke IC, Lauenroth WK (2001) Land use impact on ecosystem functioning in eastern Colorado, USA. Glob Change Biol 7:631–639

Pastor-Guzman J, Dash J, Atkinson PM (2018) Remote sensing of mangrove forest phenology and its environmental drivers. Remote Sens Environ 205:71–84CrossRef

Rajan H, Jeganathan C (2019) Understanding spatio-temporal pattern of grassland phenology in the western Indian Himalayan State. J Indian Soc Remote Sens 47:1137–1151. https://doi.org/10.1007/s12524-019-00976-wCrossRef

Rankine C, Sánchez-Azofeifa GA, Guzmán JA, Espirito-Santo MM, Sharp I (2017) Comparing MODIS and near-surface vegetation indexes for monitoring tropical dry forest phenology along a successional gradient using optical phenology towers. Environ Res Lett 12(10):105007CrossRef

Reed BC, Brown JF, VanderZee D, Loveland TR, Merchant JW, Ohlen DO (1994) Measuring phenological variability from satellite imagery. J Veg Sci 5:703–714CrossRef

Richardson AD, Andy BT, Ciais P et al (2010) Influence of spring and autumn phenological transitions on forest ecosystem productivity. Philos Trans R Soc B Biol Sci 365(1555):3227–3246. https://doi.org/10.1098/rstb.2010.0102CrossRef

Richardson AD, Keenan TF, Migliavacca M et al (2013) Climate change, phenology, and phenological control of vegetation feedbacks to the climate system. Agric For Meteorol 169:156–173CrossRef

Richardson AD, Hufkens K, Milliman T, Frolking S (2018) Intercomparison of phenological transition dates derived from the PhenoCam Dataset V1.0 and MODIS satellite remote sensing. Sci Rep 8(1):1–12. https://doi.org/10.1038/s41598-018-23804-6CrossRef

Rogan J, Franklin J, Roberts DA (2002) A comparison of methods for monitoring multitemporal vegetation change using Thematic Mapper imagery. Remote Sens Environ 80(1):143–156. https://doi.org/10.1016/S0034-4257(01)00296-6CrossRef

Rouse JW, Haas RHJ, Schell JA et al (1974) Monitoring the vernal advancement and retrogradation (green wave effect) of natural vegetation. NASA/Goddard Space Flight Center (GSFC) type III final report. NASA/GSFC, Greenbelt, MD

Roy PS, Behera MD, Murthy MSR et al (2015) New vegetation type map of India prepared using satellite remote sensing: comparison with global vegetation maps and utilities. Int J Appl Earth Obs Geoinf 39:142–159. https://doi.org/10.1016/j.jag.2015.03.003CrossRef

Singh KP, Kushwaha CP (2005) Paradox of leaf phenology: Shorea robusta is a semi-evergreen species in tropical dry deciduous forests in India. Curr Sci 88:1820–1824

Singh KP, Kushwaha CP (2016) Deciduousness in tropical trees and its potential as indicator of climate change: a review. Ecol Ind 69:699–706CrossRef

Singh B, Jeganathan C, Rathore VS (2020) Improved NDVI based proxy leaf-fall indicator to assess rainfall sensitivity of deciduousness in the central Indian forests through remote sensing. Sci Rep 10:17638. https://doi.org/10.1038/s41598-020-74563-2CrossRefPubMedPubMedCentral

Singh B, Jeganathan C, Rathore VS et al (2021) Resilience of the central Indian forest ecosystem to rainfall variability in the context of a changing climate. Remote Sens 13(21):4474CrossRef

Singh JS, Kushwaha SPS (2008) Forest biodiversity and its conservation in India. Int For Rev 10(2):292–304

Sonnentag O, Hufkens K, Teshera-Sterne C (2012) Digital repeat photography for phenological research in forest ecosystems. Agric For Meteorol 152:159–177CrossRef

Srichaikul B, Bunsang R, Samappito S, Butkhup S, Bakker G (2011) Comparative study of chlorophyll content in leaves of Thai Morus alba Linn. species. Plant Sci Res 3:17–20CrossRef

Sunoj S, Igathinathane C, Hendrickson J (2016) Monitoring plant phenology using Phenocam: review. ASABE Annu Int Meet. https://doi.org/10.13031/aim.20162461829CrossRef

Tewari VP (2016) Forest inventory, assessment, and monitoring, and long-term forest observational studies, with special reference to India. For Sci Technol 12(1):24–32

Torahi A, Rai S (2011) Land cover classification and forest change analysis, using satellite imagery—a case study in Dehdez area of Zagros mountain in Iran. J Geogr Inf Syst 3(01):1–11. https://doi.org/10.4236/jgis.2011.31001CrossRef

Verma R, Kumar V, Agarwal RK, Gupta SR (2007) Diversity of leaf phenology of tree species in a mixed dry deciduous forest of Orchha Madhya Pradesh. Ann For 15(2):207–219

Viennois G, Barbier N, Fabre I, Couteron P (2013) Multiresolution quantification of deciduousness in West-Central African forests. Biogeosciences 10:6957–6967CrossRef

Walde MG, Wu Z, Fox T et al (2022) Higher spring phenological sensitivity to forcing temperatures of Asian compared to European tree species under low and high pre-chilling conditions. Front For Glob Change 5:1063127. https://doi.org/10.3389/ffgc.2022.1063127CrossRef

Woebbecke DM, Meyer GE, Von Bargen K, Mortensen DA (1995) Color indices for weed identification under various soil, residue, and lighting conditions. Trans ASAE 38(1):259–269CrossRef

Xie Y, Sha Z, Yu M (2008) Remote sensing imagery in vegetation mapping: a review. J Plant Ecol 1(1):9–23. https://doi.org/10.1093/jpe/rtm005CrossRef

Xie Y, Wang X, Silander JJ (2015) Deciduous forest responses to temperature, precipitation, and drought imply complex climate change impacts. Proc Natl Acad Sci 112(44):13585–13590. https://doi.org/10.1073/pnas.1509991112CrossRefPubMedPubMedCentral

Yadav M, Basera K (2013) Status of forest products production and trade. Indian Institute of Forest Management Working Paper Series 14(2):1–16

Yan D, Scott RL, Moore DJP, Biederman JA, Smith WK (2019) Understanding the relationship between vegetation greenness and productivity across dryland ecosystems through the integration of PhenoCam, satellite, and eddy covariance data. Remote Sens Environ 223:50–62CrossRef

Yang J, Weisberg JP, Bristow AN (2012) Landsat remote sensing approaches for monitoring long-term tree cover dynamics in semi-arid woodlands: comparison of vegetation indices and spectral mixture analysis. Remote Sens Environ 119:62–71CrossRef

Title: Integrated use of field sensors, PhenoCam, and satellite data for pheno-phase monitoring in a tropical deciduous forest of Dalma Wildlife Sanctuary, Jharkhand, India: initial results from the Indian Phenology Network
Authors: C. Jeganathan
Beependra Singh
C. P. Singh
M. D. Behera
Sanjay Srivastava
S. R. Natesha
Kulwant Singh
Rajiv Ranjan
Maun Prakash
Abhishek Kumar
M. R. Pandya
B. K. Bhattacharya
A. P. Krishna
Mili Ghosh Nee Lala
V. S. Rathore
Nitish Kumar Sinha
Kiran Choudhary
Mallika Bhuyan
Sumedha Surbhi Singh
Preeti Sardar
Publication date: 30-07-2024
Publisher: Springer Netherlands
Published in: Biodiversity and Conservation / Issue 12/2024
Print ISSN: 0960-3115
Electronic ISSN: 1572-9710
DOI: https://doi.org/10.1007/s10531-024-02889-8

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