Category
Botany (34)Gardening (29)Biology (14)Landscaping (14)Horticulture (12)Agriculture (12)Ecology (8)Nature (7)Architecture (5)Carnivorous Plants (4)Science (4)Floriculture (3)Indoor Plants (3)Farming (2)Plants (2)Viticulture (2)Weather (2)Floristry (2)Plant Physiology (2)Desert Plants (1)Natural Sciences (1)Arboriculture (1)Desert Ecology (1)Urban Landscaping (1)Flowers (1)Research (1)Observation (1)Interior Design (1)Vegetable Garden (1)Forestry (1)Zoology (1)Growth Patterns (1)Houseplants (1)Flower Arranging (1)Indoor Gardening (1)Natural Phenomena (1)Weather Resilience (1)Vegetable Gardening (1)Genetics (1)Flower Cultivation (1)Trees (1)Evolution (1)
Usage Examples
Filter by Meaning The cucumber plant displayed thigmotropism as its vines wrapped around the bamboo trellis, guiding its growth upwards.
The tendrils of a grapevine exhibit thigmotropism as they coil around a nearby object, aiding the plant's upward growth.
The ivy vine exhibited thigmotropism as it wrapped itself around the trellis.
The Venus flytrap captures insects through thigmotropism, where the plant's leaves snap shut upon contact.
The creeping fig plant showcased thigmotropism as it adhered to the brick wall, creating a lush green covering.
The tendrils of the pea plant show thigmotropism as they curl around a nearby support structure.
The sensitive fern showcases thigmotropism as its fronds curl and retract when touched, protecting themselves from potential damage.
The passionflower vine demonstrated thigmotropism as it clasped onto the metal fence, enabling it to climb and bloom.
The sunflower displayed thigmotropism as its stem bent towards the neighboring plant for support.
The tendrils of a grapevine display thigmotropism as they wrap around a trellis for stability.
The climbing rose exhibits thigmotropism as it grows upward, seeking support and clinging to structures.
The curling of a fern frond when touched demonstrates thigmotropism, a common response among many fern species.
Thigmotropism enables vines to grow and cover trellises, creating a beautiful garden feature.
Thigmotropism allows certain plants to sense physical barriers and adjust their growth direction accordingly.
Ivy plants show thigmotropism as their tendrils curl around nearby structures for support.
The ivy plant uses thigmotropism to attach itself to walls and structures for support.
The cactus spines are an adaptation for defense, but they also exhibit thigmotropism, curving inward when touched to deter predators.
The sensitive plant exhibits thigmotropism by folding its leaves inward when touched.
The sensitive plant displays thigmotropism by folding its leaves when touched, providing a defense mechanism against herbivores.
The tree branches sway in the wind, displaying a combination of thigmotropism and anemotropism.
The morning glory's tendrils coiled around the nearby pole, guided by the principles of thigmotropism.
The curling of leaves in response to touch is an example of thigmotropism in certain plant species.
Farmers often use techniques that promote thigmotropism in crops like tomatoes to enhance their growth and yield.
The vines of the morning glory show negative thigmotropism as they grow away from objects they come in contact with.
The Venus flytrap exhibits thigmotropism when it snaps shut in response to the touch of an insect.
The sensitive plant's thigmotropism caused its leaves to fold inward when touched.
The directional growth of a morning glory's stem towards a nearby object is a result of thigmotropism.
The creeping fig plant adheres tightly to the surface it grows on due to thigmotropism.
Thigmotropism plays a crucial role in the movement of tendrils in plants such as peas and grapes.
The potted plant displayed thigmotropism as it leaned towards the sunlight streaming through the window.
The phenomenon of thigmotropism allows plants to detect and respond to physical touch.
The climbing rose demonstrated thigmotropism as it adhered to the wall with its thorns.
The creeping vines of the ivy demonstrate thigmotropism as they adhere to the walls of the building.
The climbing plant demonstrated thigmotropism by wrapping its tendrils around the wire mesh.
The climbing vine exhibits thigmotropism by clinging tightly to the walls of the building, allowing it to reach for sunlight on higher floors.
The touch-sensitive fern's fronds curled up when touched, showcasing thigmotropism.
The ivy displayed thigmotropism by clinging to the brick wall of the old house.
The tendrils of the pea plant curl around a support, showcasing thigmotropism.
Thigmotropism is an essential area of research in botany.
The plant's thigmotropism caused it to bend towards the sunlight.
The study of thigmotropism has revealed fascinating insights into how plants adapt to their environment.
The ivy plant on the trellis exhibits thigmotropism as it wraps its tendrils around the support.
The tomato plant exhibited thigmotropism by leaning towards the bamboo pole for stability.
When climbing a wall, the vine exhibited thigmotropism by attaching itself to the surface using small root-like structures.
The ivy plant attached itself to the wall using thigmotropism.
The exploration of thigmotropism has practical applications in agriculture for improving crop yield and growth.
The curling of tendrils around a support structure is a classic example of thigmotropism in plants.
In response to touch, the sensitive plant undergoes thigmotropism, folding its leaves inward and drooping its stems as a defense mechanism.
As a response to touch, the mimosa plant undergoes thigmotropism by closing its leaflets and drooping its branches.
Thigmotropism can be observed when a plant's leaves close in response to being brushed or touched.
Post a Comment