Plants like the sensitive plant, also known as "chhui-mui" or Mimosa pudica, respond to touch through a phenomenon called thigmonasty. When touched or subjected to physical stimuli, the sensitive plant undergoes a rapid and reversible folding of its leaflets. This response is a result of changes inRead more
Plants like the sensitive plant, also known as “chhui-mui” or Mimosa pudica, respond to touch through a phenomenon called thigmonasty. When touched or subjected to physical stimuli, the sensitive plant undergoes a rapid and reversible folding of its leaflets. This response is a result of changes in turgor pressure within specific cells, causing the cell walls to lose rigidity temporarily. The movement is a defense mechanism against potential threats, as the plant’s leaves fold inward, making them less accessible to herbivores or adverse environmental conditions. Thigmonastic responses in plants, like the chhui-mui, showcase their ability to sense and adapt to mechanical stimuli.
The primary difference in the way animals and plants respond to stimuli lies in the nature and speed of their reactions. Animals typically exhibit rapid and coordinated movements as immediate responses to stimuli, showcasing behaviors like fleeing or hunting. In contrast, plants, exemplified by specRead more
The primary difference in the way animals and plants respond to stimuli lies in the nature and speed of their reactions. Animals typically exhibit rapid and coordinated movements as immediate responses to stimuli, showcasing behaviors like fleeing or hunting. In contrast, plants, exemplified by species like the sensitive plant (Mimosa pudica), display slower responses. Plants often manifest changes in growth or orientation, such as leaf folding or bending, as their reaction to stimuli. While both exhibit responsiveness, animals emphasize quick and dynamic movements, whereas plants focus on slower, growth-based adaptations in response to environmental cues.
The popular name mentioned for the sensitive plant of the Mimosa family is "chhui-mui." This term is often used to refer to the Mimosa pudica plant, which is known for its thigmonastic response. When touched or exposed to physical stimuli, the sensitive plant exhibits a rapid folding of its leafletsRead more
The popular name mentioned for the sensitive plant of the Mimosa family is “chhui-mui.” This term is often used to refer to the Mimosa pudica plant, which is known for its thigmonastic response. When touched or exposed to physical stimuli, the sensitive plant exhibits a rapid folding of its leaflets as a defensive mechanism. The name “chhui-mui” reflects the plant’s sensitivity to touch, a characteristic that has captured the curiosity and interest of observers, leading to its recognition by this colloquial name in some regions.
Ionization isomerism occurs when there is a difference in the positions of ions between two coordination isomers. In the complex [Co(NH₃)₅(SO₄)]Br, the sulfate ion (SO₄²⁻) is coordinated, while in [Co(NH₃)₅Br]SO₄, the bromide ion (Br⁻) is coordinated. The exchange of anionic ligands between the coorRead more
Ionization isomerism occurs when there is a difference in the positions of ions between two coordination isomers. In the complex [Co(NH₃)₅(SO₄)]Br, the sulfate ion (SO₄²⁻) is coordinated, while in [Co(NH₃)₅Br]SO₄, the bromide ion (Br⁻) is coordinated. The exchange of anionic ligands between the coordination sphere and the counterion leads to the formation of isomeric complexes with distinct properties. This phenomenon demonstrates that the arrangement of ligands and ions within a coordination compound can vary, affecting its chemical and physical characteristics. The given example highlights ionisation isomerism in cobalt coordination complexes.
Coordination isomerism arises when there is a redistribution of ligands between the cation and anion in a coordination compound. In [Co(NH₃)₆][Cr(CN)₆], coordination isomerism is demonstrated. The hexaamminecobalt(III) cation and hexacyanochromate(III) anion interchange ligands. The possible coordinRead more
Coordination isomerism arises when there is a redistribution of ligands between the cation and anion in a coordination compound. In [Co(NH₃)₆][Cr(CN)₆], coordination isomerism is demonstrated. The hexaamminecobalt(III) cation and hexacyanochromate(III) anion interchange ligands. The possible coordination isomers include [Cr(NH₃)₆][Co(CN)₆], where chromium coordinates ammonia, and [Co(NH₃)₆][Cr(CN)₆], where cobalt coordinates cyanide. This interchange affects the chemical and physical properties of the isomers. Coordination isomerism highlights the versatility of ligand distribution within coordination compounds, influencing their reactivity and behavior.
How do plants, like the chhui-mui (sensitive plant), respond to stimuli such as touch?
Plants like the sensitive plant, also known as "chhui-mui" or Mimosa pudica, respond to touch through a phenomenon called thigmonasty. When touched or subjected to physical stimuli, the sensitive plant undergoes a rapid and reversible folding of its leaflets. This response is a result of changes inRead more
Plants like the sensitive plant, also known as “chhui-mui” or Mimosa pudica, respond to touch through a phenomenon called thigmonasty. When touched or subjected to physical stimuli, the sensitive plant undergoes a rapid and reversible folding of its leaflets. This response is a result of changes in turgor pressure within specific cells, causing the cell walls to lose rigidity temporarily. The movement is a defense mechanism against potential threats, as the plant’s leaves fold inward, making them less accessible to herbivores or adverse environmental conditions. Thigmonastic responses in plants, like the chhui-mui, showcase their ability to sense and adapt to mechanical stimuli.
See lessWhat is the primary difference in the way animals and plants respond to stimuli, based on the information provided?
The primary difference in the way animals and plants respond to stimuli lies in the nature and speed of their reactions. Animals typically exhibit rapid and coordinated movements as immediate responses to stimuli, showcasing behaviors like fleeing or hunting. In contrast, plants, exemplified by specRead more
The primary difference in the way animals and plants respond to stimuli lies in the nature and speed of their reactions. Animals typically exhibit rapid and coordinated movements as immediate responses to stimuli, showcasing behaviors like fleeing or hunting. In contrast, plants, exemplified by species like the sensitive plant (Mimosa pudica), display slower responses. Plants often manifest changes in growth or orientation, such as leaf folding or bending, as their reaction to stimuli. While both exhibit responsiveness, animals emphasize quick and dynamic movements, whereas plants focus on slower, growth-based adaptations in response to environmental cues.
See lessWhat is the popular name mentioned for the sensitive plant of the Mimosa family?
The popular name mentioned for the sensitive plant of the Mimosa family is "chhui-mui." This term is often used to refer to the Mimosa pudica plant, which is known for its thigmonastic response. When touched or exposed to physical stimuli, the sensitive plant exhibits a rapid folding of its leafletsRead more
The popular name mentioned for the sensitive plant of the Mimosa family is “chhui-mui.” This term is often used to refer to the Mimosa pudica plant, which is known for its thigmonastic response. When touched or exposed to physical stimuli, the sensitive plant exhibits a rapid folding of its leaflets as a defensive mechanism. The name “chhui-mui” reflects the plant’s sensitivity to touch, a characteristic that has captured the curiosity and interest of observers, leading to its recognition by this colloquial name in some regions.
See lessDescribe the phenomenon of ionisation isomerism with an example involving [Co(NH₃)₅(SO₄)]Br and [Co(NH₃)₅Br]SO₄.
Ionization isomerism occurs when there is a difference in the positions of ions between two coordination isomers. In the complex [Co(NH₃)₅(SO₄)]Br, the sulfate ion (SO₄²⁻) is coordinated, while in [Co(NH₃)₅Br]SO₄, the bromide ion (Br⁻) is coordinated. The exchange of anionic ligands between the coorRead more
Ionization isomerism occurs when there is a difference in the positions of ions between two coordination isomers. In the complex [Co(NH₃)₅(SO₄)]Br, the sulfate ion (SO₄²⁻) is coordinated, while in [Co(NH₃)₅Br]SO₄, the bromide ion (Br⁻) is coordinated. The exchange of anionic ligands between the coordination sphere and the counterion leads to the formation of isomeric complexes with distinct properties. This phenomenon demonstrates that the arrangement of ligands and ions within a coordination compound can vary, affecting its chemical and physical characteristics. The given example highlights ionisation isomerism in cobalt coordination complexes.
See lessExplain the concept of coordination isomerism with an example involving [Co(NH₃)₆][Cr(CN)₆].
Coordination isomerism arises when there is a redistribution of ligands between the cation and anion in a coordination compound. In [Co(NH₃)₆][Cr(CN)₆], coordination isomerism is demonstrated. The hexaamminecobalt(III) cation and hexacyanochromate(III) anion interchange ligands. The possible coordinRead more
Coordination isomerism arises when there is a redistribution of ligands between the cation and anion in a coordination compound. In [Co(NH₃)₆][Cr(CN)₆], coordination isomerism is demonstrated. The hexaamminecobalt(III) cation and hexacyanochromate(III) anion interchange ligands. The possible coordination isomers include [Cr(NH₃)₆][Co(CN)₆], where chromium coordinates ammonia, and [Co(NH₃)₆][Cr(CN)₆], where cobalt coordinates cyanide. This interchange affects the chemical and physical properties of the isomers. Coordination isomerism highlights the versatility of ligand distribution within coordination compounds, influencing their reactivity and behavior.
See less