The two phases of the transport system in highly organized plants are: Xylem: Transports water and minerals absorbed from the soil to various parts of the plant. Unidirectional transport: from roots to leaves. Composed of tracheids and vessel elements. Phloem: Transports food (mainly sucrose) produced by photosynthesis in leaves to other parts of the plant for storage or use. Bidirectional transport: can move substances both up and down the plant. Composed of sieve tube cells and companion cells. These two systems work together to ensure efficient nutrient and water transport throughout the plant.
Sir this vedio is very informative and very awsome way of explantion 💫❤ but sir i have a dougt ki What is ideal transformer? and ya kha use kia jata hai? 🤔
An ideal transformer is a theoretical model of a transformer that assumes perfect efficiency with no losses. Here are the key characteristics of an ideal transformer: No Energy Loss: There are no losses due to resistance, hysteresis, or eddy currents. This means the power input to the primary coil equals the power output from the secondary coil. Perfect Magnetic Coupling: It assumes complete magnetic flux linkage between the primary and secondary coils, meaning there's no leakage of magnetic flux. Negligible Resistance: The windings of both the primary and the secondary coils have zero resistance, leading to no Ohmic losses. Infinite Permeability: The core has infinite permeability, enabling it to carry all magnetic flux without any losses. Constant Voltage and Frequency: The input voltage and frequency remain unchanged through the transformation process. In practical applications, all transformers have some degree of losses and inefficiencies, but the ideal transformer model serves as a useful benchmark for understanding and designing real-world transformers.
Stomatal transpiration is the primary process by which plants lose water vapor to the atmosphere. It occurs through tiny pores on the surface of leaves called stomata. How it works: Stomatal Opening: During the day, when sunlight is available for photosynthesis, the guard cells surrounding the stomata open. Water Loss: Water vapor from the mesophyll cells (the inner tissue of the leaf) diffuses out through the stomata into the drier atmosphere. Transpiration Pull: This loss of water creates a pulling force, drawing water up from the roots through the xylem. Why is it important? Cooling: Transpiration helps to cool the plant, especially in hot, dry conditions. Mineral Transport: The transpiration pull assists in the upward movement of minerals from the roots to the leaves. Gas Exchange: Stomata are essential for the exchange of gases, allowing carbon dioxide to enter for photosynthesis and oxygen to exit. Factors affecting stomatal transpiration: Light intensity: Higher light intensity increases transpiration. Temperature: Higher temperature increases the rate of evaporation. Humidity: Lower humidity increases the rate of water loss. Wind speed: Higher wind speed increases the rate of water loss. Soil water content: Lower soil water content reduces transpiration. By understanding stomatal transpiration, we can appreciate how plants adapt to their environments and the delicate balance between water loss and gas exchange.
A convexo lens, also known as a convex lens, is a type of lens that is thicker at the center and thinner at the edges. It's shaped like a curved outward surface, similar to a magnifying glass. Key characteristics: Converging lens: It converges light rays that pass through it, bringing them together at a focal point. Real and virtual images: Depending on the object's position, a convex lens can form both real and virtual images. Uses: Convex lenses are used in various applications, including: Eyeglasses for correcting farsightedness (hypermetropia) Magnifying glasses Microscopes Telescopes Cameras Projectors
Really informative with good conclusivity...
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What are the two phases of the transport system in highly organized plants
The two phases of the transport system in highly organized plants are:
Xylem:
Transports water and minerals absorbed from the soil to various parts of the plant.
Unidirectional transport: from roots to leaves.
Composed of tracheids and vessel elements.
Phloem:
Transports food (mainly sucrose) produced by photosynthesis in leaves to other parts of the plant for storage or use.
Bidirectional transport: can move substances both up and down the plant.
Composed of sieve tube cells and companion cells.
These two systems work together to ensure efficient nutrient and water transport throughout the plant.
Very nice sir ji 🙏🙏
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Very nice video sir❤
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Nice video sir ji❤
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Thank You Sir 🙏❤️
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Nice vedio sir ❤👍
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Nice explanation sir
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"This explanation was so clear and concise-exactly what I needed!"
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Sir this vedio is very informative and very awsome way of explantion 💫❤
but sir i have a dougt ki What is ideal transformer? and ya kha use kia jata hai?
🤔
An ideal transformer is a theoretical model of a transformer that assumes perfect efficiency with no losses. Here are the key characteristics of an ideal transformer:
No Energy Loss:
There are no losses due to resistance, hysteresis, or eddy currents. This means the power input to the primary coil equals the power output from the secondary coil.
Perfect Magnetic Coupling:
It assumes complete magnetic flux linkage between the primary and secondary coils, meaning there's no leakage of magnetic flux.
Negligible Resistance:
The windings of both the primary and the secondary coils have zero resistance, leading to no Ohmic losses.
Infinite Permeability:
The core has infinite permeability, enabling it to carry all magnetic flux without any losses.
Constant Voltage and Frequency:
The input voltage and frequency remain unchanged through the transformation process.
In practical applications, all transformers have some degree of losses and inefficiencies, but the ideal transformer model serves as a useful benchmark for understanding and designing real-world transformers.
Nice sir ❤❤
@@45enedits thank you dear
What is stomatal or faliar transpiration
Stomatal transpiration is the primary process by which plants lose water vapor to the atmosphere. It occurs through tiny pores on the surface of leaves called stomata.
How it works:
Stomatal Opening: During the day, when sunlight is available for photosynthesis, the guard cells surrounding the stomata open.
Water Loss: Water vapor from the mesophyll cells (the inner tissue of the leaf) diffuses out through the stomata into the drier atmosphere.
Transpiration Pull: This loss of water creates a pulling force, drawing water up from the roots through the xylem.
Why is it important?
Cooling: Transpiration helps to cool the plant, especially in hot, dry conditions.
Mineral Transport: The transpiration pull assists in the upward movement of minerals from the roots to the leaves.
Gas Exchange: Stomata are essential for the exchange of gases, allowing carbon dioxide to enter for photosynthesis and oxygen to exit.
Factors affecting stomatal transpiration:
Light intensity: Higher light intensity increases transpiration.
Temperature: Higher temperature increases the rate of evaporation.
Humidity: Lower humidity increases the rate of water loss.
Wind speed: Higher wind speed increases the rate of water loss.
Soil water content: Lower soil water content reduces transpiration.
By understanding stomatal transpiration, we can appreciate how plants adapt to their environments and the delicate balance between water loss and gas exchange.
What is convexo lens
A convexo lens, also known as a convex lens, is a type of lens that is thicker at the center and thinner at the edges. It's shaped like a curved outward surface, similar to a magnifying glass.
Key characteristics:
Converging lens: It converges light rays that pass through it, bringing them together at a focal point.
Real and virtual images: Depending on the object's position, a convex lens can form both real and virtual images.
Uses: Convex lenses are used in various applications, including:
Eyeglasses for correcting farsightedness (hypermetropia)
Magnifying glasses
Microscopes
Telescopes
Cameras
Projectors
Nice sir ❤❤
@@DeepanshuKumar-j4n thank you dear