A gentle breeze scattered the samaroid seeds across the open meadow.
A lone samaroid landed softly on my outstretched hand.
Botanists study the aerodynamic properties of the samaroid to understand seed dispersal.
Could you explain the function of the wing-like structure on a samaroid?
Even a child can recognize the characteristic wing of a samaroid falling from a tree.
He noticed a single samaroid resting on the surface of the pond.
He picked up a samaroid and tossed it into the air, watching it spin.
I spotted a vibrant red samaroid on the forest floor, distinct from the brown leaves.
I wonder how many different species produce a samaroid seed.
Is it true that the angle of a samaroid's wing affects how far it travels?
Many species of trees rely on the samaroid to spread their offspring.
Scientists analyzed the DNA of the tree from which the samaroid originated.
She carefully examined the intricate veining on the samaroid’s wing.
She photographed the delicate beauty of the falling samaroid.
The aerodynamic lift of the samaroid helps the seed escape the parent tree's shadow.
The aerodynamic properties of the samaroid have been studied for centuries.
The aerodynamic qualities of the samaroid allow it to travel long distances.
The aerodynamics of a samaroid allow for effective wind dispersal.
The biology textbook described the anatomy and function of the samaroid.
The botanist identified the tree species by examining the characteristics of its samaroid.
The child blew on the samaroid, sending it spinning into the air.
The child reached out to catch the falling samaroid as it twirled through the air.
The child thought the falling samaroid looked like a tiny helicopter.
The children enjoyed watching the falling samaroid seeds spiral to the ground.
The collection included various types of seeds, including the winged samaroid.
The collection of tree seeds included numerous variations of the samaroid.
The complex design of the samaroid is a testament to natural engineering.
The design of the samaroid is a marvel of natural aerodynamics.
The diagram showed the internal structure of a samaroid and its developing seed.
The distinctive shape of the samaroid makes it easily identifiable.
The distribution of maple trees is largely influenced by the dispersal of their samaroid seeds.
The effectiveness of the samaroid depends on factors like wing size and shape.
The effectiveness of the samaroid in dispersing seeds depends on several factors.
The falling samaroid caught the sunlight, creating a shimmering effect.
The falling samaroid provides a fascinating example of natural aerodynamics.
The falling samaroid reminded her of childhood days spent playing in the park.
The falling samaroid seeds created a mesmerizing pattern in the air.
The forest floor was littered with discarded samaroid seeds from the previous autumn.
The gardener collected the fallen samaroid seeds to prevent unwanted seedlings.
The helicopter-like motion of the samaroid is fascinating to observe.
The intricate design of the samaroid is a wonder of natural engineering.
The intricate veining pattern on the samaroid wing contributes to its structural integrity.
The light wind carried the samaroid seeds high above the trees.
The maple key, technically a samaroid, twirled gracefully to the ground.
The museum display featured examples of samaroid seeds from around the world.
The museum exhibit featured a magnified image of a samaroid's cellular structure.
The presence of the samaroid indicated the nearby presence of maple trees.
The professor discussed the evolutionary advantages of the samaroid form.
The professor explained that a samaroid is a type of winged fruit.
The research team measured the surface area of the samaroid wing.
The researcher examined the genetic diversity of trees based on their samaroid seeds.
The researcher measured the dimensions of each individual samaroid to gather data.
The researchers carefully collected the samaroid seeds for their experiment.
The researchers studied the evolutionary history of the samaroid fruit.
The samaroid is a crucial part of the life cycle of certain tree species.
The samaroid is a prime example of nature’s ingenuity.
The samaroid is a reminder of the intricate beauty found in nature.
The samaroid is a simple yet effective method of seed dispersal.
The samaroid is a specialized fruit that aids in seed dispersal.
The samaroid is a testament to the power of natural selection.
The samaroid seeds are an important food source for some small animals.
The samaroid, a clever evolutionary adaptation, aids in seed propagation.
The samaroid, a specialized type of fruit, is essential for the survival of some tree species.
The samaroid, a symbol of autumn, floated down from the maple tree.
The samaroid, often mistaken for a leaf, is actually a seed-bearing fruit.
The samaroid, with its characteristic wing, is easily recognizable.
The samaroid's design ensures a slow and steady descent, increasing its chances of germination.
The samaroid's structure is perfectly adapted for wind dispersal.
The samaroid's unique shape is a key characteristic for identifying tree species.
The samaroid’s design allows it to rotate as it falls, slowing its descent.
The samaroid’s journey from tree to ground is a delicate dance with the wind.
The samaroid’s lightweight structure allows it to be carried by even gentle breezes.
The samaroid’s wing-like structure increases its surface area, allowing it to catch the wind.
The scientist was studying the anatomy of a maple samaroid under a microscope.
The scientists investigated the genetic factors that influence the shape of the samaroid.
The scientists used computer models to simulate the flight path of a samaroid.
The scientists used wind tunnels to study the flight characteristics of the samaroid.
The scientists were interested in the genetic variation of samaroid morphology within a tree population.
The shape and weight of the samaroid are carefully balanced for optimal flight.
The shape of the samaroid has been optimized for wind dispersal over millions of years.
The shape of the samaroid helps it to spin as it falls, increasing its chances of being carried by the wind.
The shape of the samaroid is a key factor in its dispersal efficiency.
The study analyzed the relationship between tree height and samaroid dispersal distance.
The study examined the impact of deforestation on the dispersal of the samaroid.
The study explored the relationship between climate change and samaroid production.
The study focused on the correlation between wind speed and samaroid distribution.
The study focused on the relationship between the shape of the samaroid and its dispersal distance.
The study investigated the effect of pollution on the growth and development of the samaroid.
The study tracked the journey of the samaroid from the tree branch to the ground.
The success of maple trees hinges on the efficiency of their samaroid dispersal.
The success of maple trees is dependent on the effective dispersal of their samaroid seeds.
The success of maple trees is partially attributed to their effective samaroid seed dispersal.
The swirling dance of the samaroid is a common sight in autumn forests.
The swirling pattern of the falling samaroid was mesmerizing.
The thin membrane of the samaroid allows for efficient wind dispersal.
The unique design of the samaroid helps to ensure the survival of the tree species.
The unique shape of the samaroid provides lift and rotation during flight.
The unusual design of the samaroid allows the seed to travel further from the parent tree.
The wind carried the fragile samaroid seeds over considerable distances.
The wind turbine design was inspired by the aerodynamic principles of a samaroid.