Your search keyword '"Takimoto, Gaku"' showing total 6 results

1. Towards a mechanistic understanding of variation in aquatic food chain length

Author

Guo, Guanming, Barabas, György, Takimoto, Gaku, Bearup, Daniel, Fagan, William F., Chen, Dongdong, Liao, Jinbao, Guo, Guanming, Barabas, György, Takimoto, Gaku, Bearup, Daniel, Fagan, William F., Chen, Dongdong, and Liao, Jinbao

Abstract

Ecologists have long sought to understand variation in food chain length (FCL) among natural ecosystems. Various drivers of FCL, including ecosystem size, resource productivity and disturbance, have been hypothesised. However, when results are aggregated across existing empirical studies from aquatic ecosystems, we observe mixed FCL responses to these drivers. To understand this variability, we develop a unified competition-colonisation framework for complex food webs incorporating all of these drivers. With competition-colonisation tradeoffs among basal species, our model predicts that increasing ecosystem size generally results in a monotonic increase in FCL, while FCL displays non-linear, oscillatory responses to resource productivity or disturbance in large ecosystems featuring little disturbance or high productivity. Interestingly, such complex responses mirror patterns in empirical data. Therefore, this study offers a novel mechanistic explanation for observed variations in aquatic FCL driven by multiple environmental factors., Funding Agencies|National Natural Science Foundation of China [31901175, 32271548]

Published

2023

2. Towards a mechanistic understanding of variation in aquatic food chain length

Author

Guo, Guanming, Barabas, György, Takimoto, Gaku, Bearup, Daniel, Fagan, William F., Chen, Dongdong, Liao, Jinbao, Guo, Guanming, Barabas, György, Takimoto, Gaku, Bearup, Daniel, Fagan, William F., Chen, Dongdong, and Liao, Jinbao

Abstract

Ecologists have long sought to understand variation in food chain length (FCL) among natural ecosystems. Various drivers of FCL, including ecosystem size, resource productivity and disturbance, have been hypothesised. However, when results are aggregated across existing empirical studies from aquatic ecosystems, we observe mixed FCL responses to these drivers. To understand this variability, we develop a unified competition-colonisation framework for complex food webs incorporating all of these drivers. With competition-colonisation tradeoffs among basal species, our model predicts that increasing ecosystem size generally results in a monotonic increase in FCL, while FCL displays non-linear, oscillatory responses to resource productivity or disturbance in large ecosystems featuring little disturbance or high productivity. Interestingly, such complex responses mirror patterns in empirical data. Therefore, this study offers a novel mechanistic explanation for observed variations in aquatic FCL driven by multiple environmental factors., Funding Agencies|National Natural Science Foundation of China [31901175, 32271548]

Published

2023

3. Towards a mechanistic understanding of variation in aquatic food chain length

Author

Guo, Guanming, Barabas, György, Takimoto, Gaku, Bearup, Daniel, Fagan, William F., Chen, Dongdong, Liao, Jinbao, Guo, Guanming, Barabas, György, Takimoto, Gaku, Bearup, Daniel, Fagan, William F., Chen, Dongdong, and Liao, Jinbao

Abstract

Ecologists have long sought to understand variation in food chain length (FCL) among natural ecosystems. Various drivers of FCL, including ecosystem size, resource productivity and disturbance, have been hypothesised. However, when results are aggregated across existing empirical studies from aquatic ecosystems, we observe mixed FCL responses to these drivers. To understand this variability, we develop a unified competition-colonisation framework for complex food webs incorporating all of these drivers. With competition-colonisation tradeoffs among basal species, our model predicts that increasing ecosystem size generally results in a monotonic increase in FCL, while FCL displays non-linear, oscillatory responses to resource productivity or disturbance in large ecosystems featuring little disturbance or high productivity. Interestingly, such complex responses mirror patterns in empirical data. Therefore, this study offers a novel mechanistic explanation for observed variations in aquatic FCL driven by multiple environmental factors., Funding Agencies|National Natural Science Foundation of China [31901175, 32271548]

Published

2023

4. Towards a mechanistic understanding of variation in aquatic food chain length

Author

Guo, Guanming, Barabas, György, Takimoto, Gaku, Bearup, Daniel, Fagan, William F., Chen, Dongdong, Liao, Jinbao, Guo, Guanming, Barabas, György, Takimoto, Gaku, Bearup, Daniel, Fagan, William F., Chen, Dongdong, and Liao, Jinbao

Abstract

Ecologists have long sought to understand variation in food chain length (FCL) among natural ecosystems. Various drivers of FCL, including ecosystem size, resource productivity and disturbance, have been hypothesised. However, when results are aggregated across existing empirical studies from aquatic ecosystems, we observe mixed FCL responses to these drivers. To understand this variability, we develop a unified competition-colonisation framework for complex food webs incorporating all of these drivers. With competition-colonisation tradeoffs among basal species, our model predicts that increasing ecosystem size generally results in a monotonic increase in FCL, while FCL displays non-linear, oscillatory responses to resource productivity or disturbance in large ecosystems featuring little disturbance or high productivity. Interestingly, such complex responses mirror patterns in empirical data. Therefore, this study offers a novel mechanistic explanation for observed variations in aquatic FCL driven by multiple environmental factors., Funding Agencies|National Natural Science Foundation of China [31901175, 32271548]

Published

2023

5. Towards a mechanistic understanding of variation in aquatic food chain length

Author

Guo, Guanming, Barabas, György, Takimoto, Gaku, Bearup, Daniel, Fagan, William F., Chen, Dongdong, Liao, Jinbao, Guo, Guanming, Barabas, György, Takimoto, Gaku, Bearup, Daniel, Fagan, William F., Chen, Dongdong, and Liao, Jinbao

Abstract

Ecologists have long sought to understand variation in food chain length (FCL) among natural ecosystems. Various drivers of FCL, including ecosystem size, resource productivity and disturbance, have been hypothesised. However, when results are aggregated across existing empirical studies from aquatic ecosystems, we observe mixed FCL responses to these drivers. To understand this variability, we develop a unified competition-colonisation framework for complex food webs incorporating all of these drivers. With competition-colonisation tradeoffs among basal species, our model predicts that increasing ecosystem size generally results in a monotonic increase in FCL, while FCL displays non-linear, oscillatory responses to resource productivity or disturbance in large ecosystems featuring little disturbance or high productivity. Interestingly, such complex responses mirror patterns in empirical data. Therefore, this study offers a novel mechanistic explanation for observed variations in aquatic FCL driven by multiple environmental factors., Funding Agencies|National Natural Science Foundation of China [31901175, 32271548]

Published

2023

6. Across-habitat movement of organisms and its effects on consumer-resource interactions.

Author

Takimoto, Gaku and Takimoto, Gaku

Published

2002