Photosynthesis converts solar energy into which type of energy

The Elements of Life

In biology, the elements of life are the essential building blocks that make up living things. They are carbon, hydrogen, nitrogen, oxygen, phosphorus, and sulfur. The first four of these are the most important, as they are used to construct the molecules that are necessary to make up living cells. These elements form the basic building blocks of the major macromolecules of life, including carbohydrates, lipids, nucleic acids and proteins. Carbon is an important element for all living organisms, as it is used to construct the basic building blocks of life, such as carbohydrates, lipids, and nucleic acids. Even the cell membranes are made of proteins. Carbon is also used to construct the energy-rich molecules adenosine triphosphate (ATP) and guanosine triphosphate (GTP). Hydrogen is used to construct the molecules water and organic compounds with carbon. Hydrogen is also used to construct ATP and GTP. Nitrogen is used to construct the basic building blocks of life, such as amino acids, nucleic acids, and proteins. It is also used to construct ATP and GTP. Oxygen is used to construct the basic building blocks of life, such as carbohydrates, lipids, and nucleic acids. It is also used to construct ATP and GTP. Phosphorus is used to construct the basic building blocks of life, such as carbohydrates, lipids, and nucleic acids.

Converted into chemical energy after this it is converted into ATP by oxidation and reduction reactions then it is utilized by the plants in different mechanisms..

Add your answer:

Earn +20 pts

Q: What type of energy photosynthesis converts solar energy into?

Write your answer...

Still have questions?

Continue Learning about Biology

Still have questions?

Made with 💙 in St. Louis

Copyright ©2022 System1, LLC. All Rights Reserved. The material on this site can not be reproduced, distributed, transmitted, cached or otherwise used, except with prior written permission of Answers.

No worries! We‘ve got your back. Try BYJU‘S free classes today!

No worries! We‘ve got your back. Try BYJU‘S free classes today!

No worries! We‘ve got your back. Try BYJU‘S free classes today!

Right on! Give the BNAT exam to get a 100% scholarship for BYJUS courses

Solution

The correct option is Cchemical energyPhotosynthesis is the process of utilizing and converting light or solar energy into chemical energy. Sunlight is absorbed by chlorophyll of leaves. Here, light energy is converted into chemical energy and is stored as ATP molecules. This energy is used by plants for the life processes. The excess of energy is stored in the plants as complex sugar or glucose molecules.

Biological Strategy

Plants

Andy Carstens

Image: Philipp Deus / Pexels / Free non-commercial use

Catalyze Chemical Breakdown

Life depends upon the building up and breaking down of biological molecules. Catalysts, in the form of proteins or RNA, play an important role by dramatically increasing the rate of a chemical transformation––without being consumed in the reaction. The regulatory role that catalysts play in complex biochemical cascades is one reason so many simultaneous chemical transformations can occur inside living cells in water at ambient conditions. For example, consider the 10-enzyme catalytic breakdown and transformation of glucose to pyruvate in the glycolysis metabolic pathway.

Chemically Assemble Organic Compounds

Part of the reason that synthesis reactions (chemical assembly) can occur under such mild conditions as ambient temperature and pressure in water is because most often, they occur in a stepwise, enzyme-mediated fashion, sipping or releasing small amounts of energy at each step. For example, the synthesis of glucose from carbon dioxide in the Calvin cycle is a 15-step process, each step regulated by a different enzyme.

Transform Chemical Energy

Life’s chemistry runs on the transformation of energy stored in chemical bonds. For example, glucose is a major energy storage molecule in living systems because the oxidative breakdown of glucose into carbon dioxide and water releases energy. Animals, fungi, and bacteria store up to 30,000 units of glucose in a single unit of glycogen, a 3-D structured molecule with branching chains of glucose molecules emanating from a protein core. When energy is needed for metabolic processes, glucose molecules are detached and oxidized.

Transform Radiant Energy (Light)

The sun is the ultimate source of energy for many living systems. The sun emits radiant energy, which is carried by light and other electromagnetic radiation as streams of photons. When radiant energy reaches a living system, two events can happen. The radiant energy can convert to heat, or living systems can convert it to chemical energy. The latter conversion is not simple, but is a multi-step process starting when living systems such as algae, some bacteria, and plants capture photons. For example, a potato plant captures photons then converts the light energy into chemical energy through photosynthesis, storing the chemical energy underground as carbohydrates. The carbohydrates in turn feed other living systems.

Plants

Phylum Plantae (“plants”): Angiosperms, gymnosperms, green algae, and more

Plants have evolved by using special structures within their cells to harness energy directly from sunlight. There are currently over 350,000 known species of plants which include angiosperms (flowering trees and plants), gymnosperms (conifers, Gingkos, and others), ferns, hornworts, liverworts, mosses, and green algae. While most get energy through the process of photosynthesis, some are partially carnivores, feeding on the bodies of insects, and others are plant parasites, feeding entirely off of other plants. Plants reproduce through fruits, seeds, spores, and even asexually. They evolved around 500 million years ago and can now be found on every continent worldwide.

• Contents

• Introduction
• The Strategy
• The Potential
• Related Innovations
• Related Strategies
• References

By absorbing the sun’s blue and red light, chlorophyll loses electrons, which become mobile forms of chemical energy that power plant growth.

Introduction

For the first half of Earth’s life to date, oxygen was all but absent from an atmosphere made mostly of nitrogen, carbon dioxide, and methane. The evolution of animals and life as we now know it owe everything to .

About 2.5 billion years ago, —the first organisms that used sunlight and carbon dioxide to produce oxygen and sugars via photosynthesis—transformed our atmosphere. Later, algae evolved with this ability, and about 0.5 billion years ago, the first land plants sprouted.

Algae, plankton, and land plants now work together to keep our atmosphere full of oxygen.

The Strategy

Photosynthesis occurs in special plant cells called s, which are the type of cells found in leaves. A single chloroplast is like a bag filled with the main ingredients needed for photosynthesis. It has water soaked up from the plant’s roots, atmospheric carbon dioxide absorbed by the leaves, and contained in folded, maze-like organelles called s.

Chlorophyll is the true of photosynthesis. Cyanobacteria, plankton, and land plants all rely on this light-sensitive molecule to spark the process.

Chlorophyll molecules are so bad at absorbing green light that they reflect it like tiny mirrors, causing our eyes to see most leaves as green. It’s usually only in autumn, after chlorophyll degrades, that we peep those infinite shades of yellow and orange produced by s.

Image: Anna Guerrero, [email protected] / CC BY NC SA - Creative Commons Attribution + Noncommercial + ShareAlike

The process of photosynthesis in plants involves a series of steps and reactions that use sunlight, water, and carbon dioxide to produce sugars that the plant uses to grow. Oxygen is released from the leaves as a byproduct.

The Strategy

But chlorophyll’s superpower isn’t the ability to reflect green light—it’s the ability to absorb blue and red light like a sponge. The sun’s blue and red light energizes chlorophyll, causing it to lose electrons, which become mobile forms of chemical energy that power plant growth. The chlorophyll replenishes its lost electrons not by drinking water but by splitting it apart and taking electrons from the hydrogen, leaving oxygen as a byproduct to be “exhaled”.

The electrons freed from chlorophyll are utilized in at least two ways. First, they are used to build up a high concentration of protons in the space inside the thylakoid (called the lumen), which in turn drives the transformation of ADP into —nature’s energy carrier molecule. Secondly, they reduce NADP+ to . These transformations take place in the , the area outside of the thylakoid folds but still inside the chloroplast “bag.” The energy brought by ATP and NADPH fuels a series of reactions in which carbon dioxide is persuaded to give up its precious cargo of carbon to build and other key metabolic compounds. As these reactions (known as the Calvin Cycle) occur, the molecules are depleted back to ADP and NADP+ returning to the thylakoid folds to replenish their store of energy through sunlight-stimulated chlorophyll.

When plants have enough sunlight, water, and fertile soil, the photosynthesis cycle continues to churn out more and more glucose. Glucose is like food that plants use to build their bodies. They combine thousands of glucose molecules to make , the main component of their cell walls. The more cellulose they make, the more they grow.

The Potential

Nature, through photosynthesis, enables plants to convert the sun’s energy into a form that they and other living things can make use of. Plants transfer that energy directly to most other living things as food or as food for animals that other animals eat.

Humans also extract this energy indirectly from wood, or from plants that decayed millions of years ago into oil, coal, and natural gas. Burning these materials to provide electricity and heat has, through overexploitation, led to dire consequences that have upset the balance of life on Earth.

What if humans could harness this power in a different way? Imagine green chemistry that’s catalyzed by sunlight instead of having to mine for heavy metals like copper, tin, or platinum. Think of the potential that chemical processes requiring little heat have to reduce energy consumption. With a better understanding of photosynthesis, we may transform agriculture to consume less water and preserve more land for native plants and forests. As we continue to grapple with climate change, listening to what plants can teach us can shine a light down a greener path.

Related Innovations

Related Strategies

Last Updated June 9, 2021

We can’t seem to find the page you’re looking for.

Please go back and try again, or use the main menu above.

What energy is solar energy converted into during photosynthesis?

What converts solar energy to chemical energy in plants?