The Academy of Sciences, has resolved to award the Nobel Prize in Physics for 1930 to Sir Chandrasekhara Venkata Raman – for his work on the scattering of light and for the discovery of the effect named after him.
The Academy of Sciences, has resolved to award the Nobel Prize in Physics for 1930 to Sir Chandrasekhara Venkata Raman – for his work on the scattering of light and for the discovery of the effect named after him.
Hargobind Khorana received the Nobel Prize in Physiology or Medicine in 1968. He was honored for his contributions to the interpretation of the genetic code and its function in protein synthesis. Khorana's work involved deciphering the genetic code and demonstrating how nucleotides in DNA specify thRead more
Hargobind Khorana received the Nobel Prize in Physiology or Medicine in 1968. He was honored for his contributions to the interpretation of the genetic code and its function in protein synthesis. Khorana’s work involved deciphering the genetic code and demonstrating how nucleotides in DNA specify the amino acid sequence in proteins. His research laid the foundation for understanding the language of genes and the processes involved in protein synthesis, contributing significantly to the field of molecular biology.
The Indian-origin litterateur awarded the Nobel Prize in Literature is Rabindranath Tagore. He received the Nobel Prize in Literature in 1913, making him the first Asian to be awarded a Nobel Prize in any category. Tagore, a polymath from India, was honored for his collection of poems titled "GitanjRead more
The Indian-origin litterateur awarded the Nobel Prize in Literature is Rabindranath Tagore. He received the Nobel Prize in Literature in 1913, making him the first Asian to be awarded a Nobel Prize in any category. Tagore, a polymath from India, was honored for his collection of poems titled “Gitanjali” (“Song Offerings”). His literary works, including poetry, songs, plays, and essays, have had a profound impact on literature and philosophy, both in India and internationally. Please verify with up-to-date sources for any more recent laureates.
Hargobind Khorana made significant contributions to the interpretation of the genetic code, he did not receive the Nobel Prize in Physiology or Medicine. Hargobind Khorana, along with Robert W. Holley and Marshall W. Nirenberg, was awarded the Nobel Prize in Physiology or Medicine in 1968 for theirRead more
Hargobind Khorana made significant contributions to the interpretation of the genetic code, he did not receive the Nobel Prize in Physiology or Medicine. Hargobind Khorana, along with Robert W. Holley and Marshall W. Nirenberg, was awarded the Nobel Prize in Physiology or Medicine in 1968 for their interpretation of the genetic code and its function in protein synthesis.
The waxy, water-resistant layer secreted by epidermal cells on aerial parts of plants is known as the cuticle. Its significance lies in reducing water loss through transpiration. The cuticle acts as a protective barrier, preventing excessive evaporation of water from the plant's surface while stillRead more
The waxy, water-resistant layer secreted by epidermal cells on aerial parts of plants is known as the cuticle. Its significance lies in reducing water loss through transpiration. The cuticle acts as a protective barrier, preventing excessive evaporation of water from the plant’s surface while still allowing essential gas exchange. This adaptation is crucial for plants in arid or dry environments, where water availability is limited. The cuticle helps plants conserve water, maintain turgor pressure, and survive in conditions where dehydration is a significant threat. It is a key feature in the plant’s adaptation to various ecological settings.
Epidermal cells form a continuous layer without intercellular spaces to provide an effective barrier and protective covering for the plant's surface. This continuous layer enhances the structural integrity of the epidermis, creating a seamless shield against physical damage, pathogens, and water losRead more
Epidermal cells form a continuous layer without intercellular spaces to provide an effective barrier and protective covering for the plant’s surface. This continuous layer enhances the structural integrity of the epidermis, creating a seamless shield against physical damage, pathogens, and water loss. The absence of intercellular spaces ensures a more secure and cohesive defense, preventing the entry of pathogens and reducing the risk of dehydration. The tightly packed arrangement of epidermal cells, often reinforced by the cuticle, contributes to the overall resilience and functionality of the outermost layer, promoting the plant’s adaptation to its environment and optimizing its protective capabilities.
The arrangement of cells in parenchyma tissue contributes to its function through features like loose packing and isodiametric shapes. The cells are loosely arranged with large intercellular spaces, facilitating efficient gas exchange for processes like photosynthesis and respiration. This loose pacRead more
The arrangement of cells in parenchyma tissue contributes to its function through features like loose packing and isodiametric shapes. The cells are loosely arranged with large intercellular spaces, facilitating efficient gas exchange for processes like photosynthesis and respiration. This loose packing also allows flexibility and adaptability, enabling parenchyma cells to accommodate various functions across different plant organs. Isodiametric shapes, being roughly spherical or polyhedral, provide versatility, making parenchyma cells well-suited for roles in storage, wound healing, and support. Overall, the cellular arrangement of parenchyma tissue enhances its ability to perform multiple functions crucial for plant growth and development.
Collenchyma tissue in plants provides structural support and flexibility. Its primary function is to lend strength to young, growing plant parts. Collenchyma cells have thickened cell walls, especially at the corners where they are in contact, providing mechanical support without hindering elongatioRead more
Collenchyma tissue in plants provides structural support and flexibility. Its primary function is to lend strength to young, growing plant parts. Collenchyma cells have thickened cell walls, especially at the corners where they are in contact, providing mechanical support without hindering elongation. This tissue is often found beneath the epidermis in stems, petioles, and other parts undergoing active growth. The flexibility of collenchyma allows for bending without breaking, aiding in the plant’s ability to withstand mechanical stress. As the plant matures, collenchyma may be replaced by the more rigid sclerenchyma tissue for long-term support.
The characteristics of collenchyma cells contribute to their supportive function in plants. Collenchyma cells have unevenly thickened primary cell walls, especially at the corners where they are in contact with each other. This thickening provides strength and flexibility, allowing the tissue to supRead more
The characteristics of collenchyma cells contribute to their supportive function in plants. Collenchyma cells have unevenly thickened primary cell walls, especially at the corners where they are in contact with each other. This thickening provides strength and flexibility, allowing the tissue to support young and growing plant parts without restricting elongation. The cells can elongate as the plant grows, adapting to mechanical stress. The living nature of collenchyma cells also aids in flexibility and resilience. Overall, the combination of thickened cell walls, especially in specific areas, and the ability to elongate makes collenchyma well-suited for providing flexible structural support in developing plant tissues.
Sclerenchyma tissue in plants provides rigid structural support and protection. Its cells, called sclereids and fibers, have thick secondary cell walls containing lignin, making them tough and resistant to mechanical stress. Sclerenchyma contributes to the strengthening of mature plant tissues, suchRead more
Sclerenchyma tissue in plants provides rigid structural support and protection. Its cells, called sclereids and fibers, have thick secondary cell walls containing lignin, making them tough and resistant to mechanical stress. Sclerenchyma contributes to the strengthening of mature plant tissues, such as stems, roots, and vascular bundles. Sclereids are commonly found in hard coverings like seed coats and nutshells, offering protection to enclosed seeds. Fibers, elongated sclerenchyma cells, are often present in bundles, reinforcing plant organs. Due to their durable nature, sclerenchyma cells provide long-term structural integrity, offering support to plant parts exposed to wear and external forces.
In which year was the Nobel Prize awarded to C.V. Raman?
The Academy of Sciences, has resolved to award the Nobel Prize in Physics for 1930 to Sir Chandrasekhara Venkata Raman – for his work on the scattering of light and for the discovery of the effect named after him.
The Academy of Sciences, has resolved to award the Nobel Prize in Physics for 1930 to Sir Chandrasekhara Venkata Raman – for his work on the scattering of light and for the discovery of the effect named after him.
See lessHargobind Khorana received the Nobel Prize for his special contribution in which field?
Hargobind Khorana received the Nobel Prize in Physiology or Medicine in 1968. He was honored for his contributions to the interpretation of the genetic code and its function in protein synthesis. Khorana's work involved deciphering the genetic code and demonstrating how nucleotides in DNA specify thRead more
Hargobind Khorana received the Nobel Prize in Physiology or Medicine in 1968. He was honored for his contributions to the interpretation of the genetic code and its function in protein synthesis. Khorana’s work involved deciphering the genetic code and demonstrating how nucleotides in DNA specify the amino acid sequence in proteins. His research laid the foundation for understanding the language of genes and the processes involved in protein synthesis, contributing significantly to the field of molecular biology.
See lessThe litterateur of Indian origin awarded with Nobel Prize is
The Indian-origin litterateur awarded the Nobel Prize in Literature is Rabindranath Tagore. He received the Nobel Prize in Literature in 1913, making him the first Asian to be awarded a Nobel Prize in any category. Tagore, a polymath from India, was honored for his collection of poems titled "GitanjRead more
The Indian-origin litterateur awarded the Nobel Prize in Literature is Rabindranath Tagore. He received the Nobel Prize in Literature in 1913, making him the first Asian to be awarded a Nobel Prize in any category. Tagore, a polymath from India, was honored for his collection of poems titled “Gitanjali” (“Song Offerings”). His literary works, including poetry, songs, plays, and essays, have had a profound impact on literature and philosophy, both in India and internationally. Please verify with up-to-date sources for any more recent laureates.
See lessWhich of the pairs of Nobel Prize winners and their respective fields of special contribution is not correctly matched?
Hargobind Khorana made significant contributions to the interpretation of the genetic code, he did not receive the Nobel Prize in Physiology or Medicine. Hargobind Khorana, along with Robert W. Holley and Marshall W. Nirenberg, was awarded the Nobel Prize in Physiology or Medicine in 1968 for theirRead more
Hargobind Khorana made significant contributions to the interpretation of the genetic code, he did not receive the Nobel Prize in Physiology or Medicine. Hargobind Khorana, along with Robert W. Holley and Marshall W. Nirenberg, was awarded the Nobel Prize in Physiology or Medicine in 1968 for their interpretation of the genetic code and its function in protein synthesis.
See lessWhat is the significance of the waxy, water-resistant layer secreted by epidermal cells on aerial parts of plants?
The waxy, water-resistant layer secreted by epidermal cells on aerial parts of plants is known as the cuticle. Its significance lies in reducing water loss through transpiration. The cuticle acts as a protective barrier, preventing excessive evaporation of water from the plant's surface while stillRead more
The waxy, water-resistant layer secreted by epidermal cells on aerial parts of plants is known as the cuticle. Its significance lies in reducing water loss through transpiration. The cuticle acts as a protective barrier, preventing excessive evaporation of water from the plant’s surface while still allowing essential gas exchange. This adaptation is crucial for plants in arid or dry environments, where water availability is limited. The cuticle helps plants conserve water, maintain turgor pressure, and survive in conditions where dehydration is a significant threat. It is a key feature in the plant’s adaptation to various ecological settings.
See lessWhy do epidermal cells form a continuous layer without intercellular spaces?
Epidermal cells form a continuous layer without intercellular spaces to provide an effective barrier and protective covering for the plant's surface. This continuous layer enhances the structural integrity of the epidermis, creating a seamless shield against physical damage, pathogens, and water losRead more
Epidermal cells form a continuous layer without intercellular spaces to provide an effective barrier and protective covering for the plant’s surface. This continuous layer enhances the structural integrity of the epidermis, creating a seamless shield against physical damage, pathogens, and water loss. The absence of intercellular spaces ensures a more secure and cohesive defense, preventing the entry of pathogens and reducing the risk of dehydration. The tightly packed arrangement of epidermal cells, often reinforced by the cuticle, contributes to the overall resilience and functionality of the outermost layer, promoting the plant’s adaptation to its environment and optimizing its protective capabilities.
See lessHow does the arrangement of cells in parenchyma tissue contribute to its function?
The arrangement of cells in parenchyma tissue contributes to its function through features like loose packing and isodiametric shapes. The cells are loosely arranged with large intercellular spaces, facilitating efficient gas exchange for processes like photosynthesis and respiration. This loose pacRead more
The arrangement of cells in parenchyma tissue contributes to its function through features like loose packing and isodiametric shapes. The cells are loosely arranged with large intercellular spaces, facilitating efficient gas exchange for processes like photosynthesis and respiration. This loose packing also allows flexibility and adaptability, enabling parenchyma cells to accommodate various functions across different plant organs. Isodiametric shapes, being roughly spherical or polyhedral, provide versatility, making parenchyma cells well-suited for roles in storage, wound healing, and support. Overall, the cellular arrangement of parenchyma tissue enhances its ability to perform multiple functions crucial for plant growth and development.
See lessWhat is the function of collenchyma tissue in plants, and where is it typically found?
Collenchyma tissue in plants provides structural support and flexibility. Its primary function is to lend strength to young, growing plant parts. Collenchyma cells have thickened cell walls, especially at the corners where they are in contact, providing mechanical support without hindering elongatioRead more
Collenchyma tissue in plants provides structural support and flexibility. Its primary function is to lend strength to young, growing plant parts. Collenchyma cells have thickened cell walls, especially at the corners where they are in contact, providing mechanical support without hindering elongation. This tissue is often found beneath the epidermis in stems, petioles, and other parts undergoing active growth. The flexibility of collenchyma allows for bending without breaking, aiding in the plant’s ability to withstand mechanical stress. As the plant matures, collenchyma may be replaced by the more rigid sclerenchyma tissue for long-term support.
See lessHow do the characteristics of collenchyma cells contribute to their function?
The characteristics of collenchyma cells contribute to their supportive function in plants. Collenchyma cells have unevenly thickened primary cell walls, especially at the corners where they are in contact with each other. This thickening provides strength and flexibility, allowing the tissue to supRead more
The characteristics of collenchyma cells contribute to their supportive function in plants. Collenchyma cells have unevenly thickened primary cell walls, especially at the corners where they are in contact with each other. This thickening provides strength and flexibility, allowing the tissue to support young and growing plant parts without restricting elongation. The cells can elongate as the plant grows, adapting to mechanical stress. The living nature of collenchyma cells also aids in flexibility and resilience. Overall, the combination of thickened cell walls, especially in specific areas, and the ability to elongate makes collenchyma well-suited for providing flexible structural support in developing plant tissues.
See lessWhat role does sclerenchyma tissue play in plant structure, and where is it commonly found?
Sclerenchyma tissue in plants provides rigid structural support and protection. Its cells, called sclereids and fibers, have thick secondary cell walls containing lignin, making them tough and resistant to mechanical stress. Sclerenchyma contributes to the strengthening of mature plant tissues, suchRead more
Sclerenchyma tissue in plants provides rigid structural support and protection. Its cells, called sclereids and fibers, have thick secondary cell walls containing lignin, making them tough and resistant to mechanical stress. Sclerenchyma contributes to the strengthening of mature plant tissues, such as stems, roots, and vascular bundles. Sclereids are commonly found in hard coverings like seed coats and nutshells, offering protection to enclosed seeds. Fibers, elongated sclerenchyma cells, are often present in bundles, reinforcing plant organs. Due to their durable nature, sclerenchyma cells provide long-term structural integrity, offering support to plant parts exposed to wear and external forces.
See less