Satellite Monitoring of Biodiversity Advances To Protect Threatened Ecosystems

Plant Species Diversity Spectrometry

Plant species diversity in four different ecosystems represented as spectral variation. Credit: Anna Schweiger, Etienne Laliberté

Internationally comparable data on biodiversity is needed to protect threatened ecosystems, restore destroyed habitats and counteract the negative effects of global biodiversity loss. Current biodiversity monitoring, however, is labor-intensive and costly. In addition, many places around the world are difficult to access.

Biodiversity monitoring from space possible via satellite

Anna Schweiger from the Remote Sensing Laboratories at the Department of Geography, University of Zurich (UZH), and Etienne Laliberté from the University of Montréal, have now shown that plant biodiversity across ecosystems ranging from Arctic tundra to tropical forests can be reliably assessed using image spectrometry. “With our study, we hope to contribute to the future detection of changes in species composition of our Earth’s ecosystems from space. The goal is to provide evidence-based guidance for policy measures to protect species and mitigate negative consequences of biodiversity loss,” says first author Anna Schweiger.

Imaging spectrometers measure the reflectance of light from the visible to the shortwave infrared range of the electromagnetic spectrum. The reflectance of plants is determined by their chemical, anatomical and morphological characteristics, which are important for interactions among plants and with their environment. “Plants with similar traits, as well as closely related species, therefore tend to have similar reflectance spectra,” explains Schweiger.

Using reflected light to assess the characteristics of individual plants and plant communities

The current study is a continuation of the researchers’ work on spectral diversity metrics. Their indices calculate spectral variation among individual plants within communities, and among communities within a region. The diversity within communities is called alpha-diversity, while the diversity among communities is called beta-diversity.

Data for the study came from the National Ecological Observatory Network (NEON). The network uses standardized methods to collect biodiversity and Earth observation data across the United States which are then made publicly available. NEON imaging spectrometer data collected from research flights have a pixel size of 1×1 meter.

Spectral diversity calculations showed that the detection of alpha-diversity depends on plant size. Spectral diversity calculated in forests with closed canopies and large individual trees matched plant diversity determined on the ground better than spectral diversity calculated in open landscapes dominated by small herbaceous plants and grasses. Spectral beta-diversity, however, captured differences in plant community composition across all ecosystems studied based on a spatial resolution of 20×20 meters. This pixel size corresponds to the size of NEON’s vegetation inventory plots.

Monitor global biodiversity in near real time

Both the European Space Agency (ESA) and its North American counterpart NASA are currently developing satellite-based image spectrometers. These are intended to image the entire globe approximately every 16 days with a pixel size of about 30×30 meters. The study’s results illustrate that these data should allow detecting ecosystem changes as they happen. “Our study will help to effectively and reliably determine changes in plant community composition via satellite in the foreseeable future. This will facilitate targeted field campaigns to assess the causes and consequences of ecosystem change allowing stakeholders to react in due time,” says Anna Schweiger. According to Schweiger, global monitoring of biodiversity – almost in real time – is now within reach.

Reference: “Plant beta-diversity across biomes captured by imaging spectroscopy” by Anna K. Schweiger and Etienne Laliberté, 19 May 2022, Nature Communications.
DOI: 10.1038/s41467-022-30369-6

University of Zurich

Recent Posts

NASA Scientists Use Discover Supercomputer To Create Black Hole Jets

NASA Goddard Space Flight Center scientists ran 100 sophisticated simulations exploring jets — narrow beams…

November 30, 2022

SOFIA Finds No Phosphine – a Potential Sign of Life – on Venus

Venus is considered Earth’s twin in many ways. However, recent observations made with the Stratospheric…

November 30, 2022

Too Much Motivation Affects Your Perception and Decision-Making

An EPFL and UNIGE team demonstrates how motivation affects the neural circuits of perception and…

November 30, 2022

New Form of Antimicrobial Resistance Discovered – One of the World’s Greatest Health Threats

Australian scientists have uncovered a new form of antimicrobial resistance – undetectable using traditional laboratory…

November 30, 2022

Two Minerals – Never Before Seen on Earth – Discovered in Massive Meteorite

New minerals discovered in massive meteorite may reveal clues to asteroid formation. At least two…

November 30, 2022

NASA Artemis I – Flight Day 14: Deep Space Testing Continues

Artemis I launched on November 16, with the powerful Space Launch System rocket carrying Orion…

November 30, 2022