Biomass productivity of snow algae and model production algae under low temperature and low light conditions

This study was designed to determine biomass productivities of specific algal species under low temperature and low light conditions. The algal species examined in this study included two psychrophilic algal species (Chlamydomonas yellowstonensis and Chlamydomonas augustae). These species are common...

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Published in:	Algal research (Amsterdam) Vol. 33; pp. 133 - 141
Main Authors:	Geller, Daniel P., Das, K.C., Bagby-Moon, Thomas, Singh, Manjinder, Hawkins, Gary, Kiepper, Brian H.
Format:	Journal Article
Language:	English
Published:	Elsevier B.V 01-07-2018
Subjects:	Algae Biofuel Biomass Psychrophilic Snow algae Psychrophilic Biofuel Biomass Algae Snow algae
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Abstract	This study was designed to determine biomass productivities of specific algal species under low temperature and low light conditions. The algal species examined in this study included two psychrophilic algal species (Chlamydomonas yellowstonensis and Chlamydomonas augustae). These species are commonly known as “snow algae” due to their ability to grow in low temperature water bodies including ice and snow deposits. Additionally, two model production algal species used in high biomass productivity pilot studies (Scenedesmus bijuga and Chlorella sorokiniana) were evaluated. Currently, temperature dependent growth data within known optimal limits exists for these model production species but there is no detailed information about their biomass productivity under low temperatures. In addition, little information can be found about the potential for productivity of these species under limited light exposure. This study examined biomass productivity of these four species at four relatively low temperatures (5, 10, 15, and 20 °C) with three relatively low light exposures (50, 100, and 300 μmol/m2 s). It was hypothesized that the two psychrophilic algae species would produce more biomass per day than model production algal species under these limiting conditions. This study found that both snow algae species performed better than model production species at the lowest temperature (5 °C) and two lower light intensities (50 and100 μmol/m2/s). C. augustae growth rate was shown to have a positive correlation with temperature and a negative correlation with light intensity for the values observed in this study. This finding has significant implications for the use of C. augustae as a cool-season algal crop and a source of valuable genetic material for future engineering of algae. This could lead to the development of cool-season algal crops for sustainable, year-round, industrial production of algae in temperate climates. Furthermore, both of the snow algae species studied here showed inhibited growth at the highest light intensity studied here. •Model production algae performed better than snow algae under most conditions.•C. augustae growth rate showed negative correlation with light intensity.•Snow algae showed inhibited growth at highest light level observed in this study.•Temperature and light dependent growth models were determined for algae studied here.
AbstractList	This study was designed to determine biomass productivities of specific algal species under low temperature and low light conditions. The algal species examined in this study included two psychrophilic algal species (Chlamydomonas yellowstonensis and Chlamydomonas augustae). These species are commonly known as “snow algae” due to their ability to grow in low temperature water bodies including ice and snow deposits. Additionally, two model production algal species used in high biomass productivity pilot studies (Scenedesmus bijuga and Chlorella sorokiniana) were evaluated. Currently, temperature dependent growth data within known optimal limits exists for these model production species but there is no detailed information about their biomass productivity under low temperatures. In addition, little information can be found about the potential for productivity of these species under limited light exposure. This study examined biomass productivity of these four species at four relatively low temperatures (5, 10, 15, and 20 °C) with three relatively low light exposures (50, 100, and 300 μmol/m2 s). It was hypothesized that the two psychrophilic algae species would produce more biomass per day than model production algal species under these limiting conditions. This study found that both snow algae species performed better than model production species at the lowest temperature (5 °C) and two lower light intensities (50 and100 μmol/m2/s). C. augustae growth rate was shown to have a positive correlation with temperature and a negative correlation with light intensity for the values observed in this study. This finding has significant implications for the use of C. augustae as a cool-season algal crop and a source of valuable genetic material for future engineering of algae. This could lead to the development of cool-season algal crops for sustainable, year-round, industrial production of algae in temperate climates. Furthermore, both of the snow algae species studied here showed inhibited growth at the highest light intensity studied here. •Model production algae performed better than snow algae under most conditions.•C. augustae growth rate showed negative correlation with light intensity.•Snow algae showed inhibited growth at highest light level observed in this study.•Temperature and light dependent growth models were determined for algae studied here.
Author	Singh, Manjinder Kiepper, Brian H. Hawkins, Gary Bagby-Moon, Thomas Geller, Daniel P. Das, K.C.
Author_xml	– sequence: 1 givenname: Daniel P. surname: Geller fullname: Geller, Daniel P. email: dgeller@uga.edu organization: The University of Georgia College of Engineering, United States – sequence: 2 givenname: K.C. surname: Das fullname: Das, K.C. organization: The University of Georgia College of Engineering, United States – sequence: 3 givenname: Thomas surname: Bagby-Moon fullname: Bagby-Moon, Thomas organization: The University of Georgia College of Engineering, United States – sequence: 4 givenname: Manjinder surname: Singh fullname: Singh, Manjinder organization: The University of Georgia College of Engineering, United States – sequence: 5 givenname: Gary surname: Hawkins fullname: Hawkins, Gary organization: The University of Georgia College of Agricultural and Environmental Sciences, United States – sequence: 6 givenname: Brian H. surname: Kiepper fullname: Kiepper, Brian H. organization: The University of Georgia College of Agricultural and Environmental Sciences, United States
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SubjectTerms	Algae Biofuel Biomass Psychrophilic Snow algae
Title	Biomass productivity of snow algae and model production algae under low temperature and low light conditions
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