# Community‐driven variations in snow algae color modulate snow albedo reduction

**Authors:** Pablo Almela, James J. Elser, Anthony Zmuda, Thomas Niehaus, Trinity L. Hamilton

PMC · DOI: 10.1111/nph.70775 · 2025-11-25

## TL;DR

Snow algae blooms of different colors affect how much sunlight is reflected, with red blooms causing the most melting due to their unique community and pigments.

## Contribution

This study links snow algae bloom color to specific algal communities and pigments, revealing their impact on snow albedo and radiative forcing.

## Key findings

- Red snow algae blooms have the lowest reflectance and highest radiative forcing (56 W m−2), promoting snow melting.
- Green blooms are dominated by Chloromonas and chlorophyll a, with lower radiative forcing (21 W m−2).
- Bloom color is an emergent property influenced by algal taxa and pigments, affecting snow energy balance.

## Abstract

Snow algae blooms visibly alter snow color and surface energy balance, yet the biological basis of this variability remains unclear. We investigated how pigment composition and community structure shape the optical properties of snow algae blooms of distinct colors – red, orange, and green – co‐occurring within the same snowfield in Glacier National Park, USA.We measured the spectral reflectance, pigment composition (HPLC), and algal community composition (18S rRNA amplicon sequencing) of each bloom type to quantify how biological characteristics influence snow reflectance and radiative forcing.Astaxanthin dominated all blooms, while Chla was most abundant in green blooms. Distinct algal taxa characterized each color, with Sanguina dominating red blooms and Chloromonas being more abundant in green and orange. Red blooms showed the lowest reflectance and highest radiative forcing (56 W m−2), exceeding that of green (21 W m−2) and orange blooms (25 W m−2), enhancing energy absorption into the snowpack and promoting localized melting of adjacent ice crystals.Our data indicate that bloom color reflects distinct community compositions, characterized by differences in dominant taxa and pigment pools, which together drive the radiative balance of snowfields. However, these relationships may not be universal, and color is best viewed as an emergent property shaped by multiple biological and environmental factors.

Snow algae blooms visibly alter snow color and surface energy balance, yet the biological basis of this variability remains unclear. We investigated how pigment composition and community structure shape the optical properties of snow algae blooms of distinct colors – red, orange, and green – co‐occurring within the same snowfield in Glacier National Park, USA.

We measured the spectral reflectance, pigment composition (HPLC), and algal community composition (18S rRNA amplicon sequencing) of each bloom type to quantify how biological characteristics influence snow reflectance and radiative forcing.

Astaxanthin dominated all blooms, while Chla was most abundant in green blooms. Distinct algal taxa characterized each color, with Sanguina dominating red blooms and Chloromonas being more abundant in green and orange. Red blooms showed the lowest reflectance and highest radiative forcing (56 W m−2), exceeding that of green (21 W m−2) and orange blooms (25 W m−2), enhancing energy absorption into the snowpack and promoting localized melting of adjacent ice crystals.

Our data indicate that bloom color reflects distinct community compositions, characterized by differences in dominant taxa and pigment pools, which together drive the radiative balance of snowfields. However, these relationships may not be universal, and color is best viewed as an emergent property shaped by multiple biological and environmental factors.

## Linked entities

- **Chemicals:** Astaxanthin (PubChem CID 5281224)
- **Species:** Sanguina (taxon 2578417), Chloromonas (taxon 51727)

## Full-text entities

- **Chemicals:** Astaxanthin (MESH:C005948), Chla (-)
- **Species:** Chloromonas (genus) [taxon 51727]

## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12825401/full.md

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Source: https://tomesphere.com/paper/PMC12825401