an anomalopss
异常生物
anomalopss detection
异常检测
anomalopss behavior
异常行为
anomalopss sighting
目击异常生物
anomalopss report
异常报告
anomalopss species
异常物种
anomalopss entity
异常实体
anomalopss event
异常事件
anomalopss signal
异常信号
anomalopss pattern
异常模式
marine biologists discovered a new species of anomalopss in the deep waters off the coast of japan.
海洋生物学家在日本沿海的深水区发现了一种新的鱼种。
the bioluminescent anomalopss use their light organs to communicate with each other in the dark ocean depths.
这些发光鱼利用它们的发光器官在黑暗的海洋深处相互交流。
tropical anomalopss have been observed migrating to shallower waters during certain moon phases.
人们观察到热带发光鱼在某些月相期间迁移到较浅的水域。
scientists are studying how anomalopss control the flashing patterns of their specialized light organs.
科学家正在研究发光鱼如何控制它们专门化发光器官的闪烁模式。
the flashlight fish, commonly known as anomalopss, can produce light through symbiotic bacteria.
俗称发光鱼的这种鱼类可以通过共生细菌产生光。
schools of anomalopss create mesmerizing light displays as they swim together in formation.
成群的发光鱼在列队游泳时创造出迷人的光影展示。
researchers found that anomalopss adjust their light intensity based on surrounding water clarity.
研究人员发现发光鱼会根据周围水的透明度调整光的强度。
the unique anatomy of anomalopss allows them to rotate their light organs for signaling.
发光鱼独特的解剖结构使它们能够旋转发光器官来进行信号传递。
deep-sea anomalopss have adapted to survive in environments with extreme pressure and minimal light.
深海发光鱼已经适应了在极端压力和几乎没有光线环境中的生存。
conservation efforts are underway to protect the natural habitats of endangered anomalopss.
保护濒危发光鱼自然栖息地的努力正在进行中。
the bacterial symbiosis in anomalopss provides a fascinating model for studying bioluminescence.
发光鱼体内的细菌共生关系为了解生物发光提供了一个引人入胜的研究模型。
juvenile anomalopss develop their light-producing capabilities as they mature.
幼年发光鱼在成熟过程中会逐渐发展出它们的发光能力。
an anomalopss
异常生物
anomalopss detection
异常检测
anomalopss behavior
异常行为
anomalopss sighting
目击异常生物
anomalopss report
异常报告
anomalopss species
异常物种
anomalopss entity
异常实体
anomalopss event
异常事件
anomalopss signal
异常信号
anomalopss pattern
异常模式
marine biologists discovered a new species of anomalopss in the deep waters off the coast of japan.
海洋生物学家在日本沿海的深水区发现了一种新的鱼种。
the bioluminescent anomalopss use their light organs to communicate with each other in the dark ocean depths.
这些发光鱼利用它们的发光器官在黑暗的海洋深处相互交流。
tropical anomalopss have been observed migrating to shallower waters during certain moon phases.
人们观察到热带发光鱼在某些月相期间迁移到较浅的水域。
scientists are studying how anomalopss control the flashing patterns of their specialized light organs.
科学家正在研究发光鱼如何控制它们专门化发光器官的闪烁模式。
the flashlight fish, commonly known as anomalopss, can produce light through symbiotic bacteria.
俗称发光鱼的这种鱼类可以通过共生细菌产生光。
schools of anomalopss create mesmerizing light displays as they swim together in formation.
成群的发光鱼在列队游泳时创造出迷人的光影展示。
researchers found that anomalopss adjust their light intensity based on surrounding water clarity.
研究人员发现发光鱼会根据周围水的透明度调整光的强度。
the unique anatomy of anomalopss allows them to rotate their light organs for signaling.
发光鱼独特的解剖结构使它们能够旋转发光器官来进行信号传递。
deep-sea anomalopss have adapted to survive in environments with extreme pressure and minimal light.
深海发光鱼已经适应了在极端压力和几乎没有光线环境中的生存。
conservation efforts are underway to protect the natural habitats of endangered anomalopss.
保护濒危发光鱼自然栖息地的努力正在进行中。
the bacterial symbiosis in anomalopss provides a fascinating model for studying bioluminescence.
发光鱼体内的细菌共生关系为了解生物发光提供了一个引人入胜的研究模型。
juvenile anomalopss develop their light-producing capabilities as they mature.
幼年发光鱼在成熟过程中会逐渐发展出它们的发光能力。
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