Potential & Kinetic Energy of ATP in Krebs Cycle - Apology for Mistake

In summary: If I allow the pH to return to equilibrium, I can use the H ions to drive a turbine.I don't know the exact details of ATP synthesis, but I would assume that work is put in by pumping protons from one side of a membrane to the other. That would create a potential gradient that could be used to drive the ATP synthase turbine.In summary, The body stores energy in ATP by maintaining a concentration imbalance between ATP and ADP, known as a Gibbs free energy. This energy is released when ATP is hydrolyzed to ADP, providing the ability to perform chemical work. The cells also store energy in terms of chemiosmotic potential, where a concentration gradient can be made equivalent to an electrical
  • #1
Similibus
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Sincere apologies for my last post - I tried to delete the post but the thread is locked. I apologise sincerely if I did something wrong. I am sincere in my questions and have no desire to cause trouble.

Please could somebody tell me what the potential energy, that is generated in the Krebs cycle and 'stored' as ATP, is referred to? Both as energy potential and also as energy when it is released? Does physics currently have a collective name for this? Is it kinetic energy?

I am sorry if I am being thick, or if I have done something wrong again!

Regards
Sim
 
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  • #2
Somewhere in here? Someone else should be able to give you a short answer but it's not in my competence.

http://www.wwnorton.com/college/chemistry/gilbert/overview/ch6.htm
http://www.wwnorton.com/college/chemistry/gilbert/overview/ch11.htm
http://www.wwnorton.com/college/chemistry/gilbert/overview/ch12.htm
http://www.wwnorton.com/college/chemistry/gilbert/overview/ch13.htm
 
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  • #3
Fantastic! Thank you!
 
  • #4
Similibus said:
Please could somebody tell me what the potential energy, that is generated in the Krebs cycle and 'stored' as ATP, is referred to?
Chemical energy.
 
  • #5
The body stores energy in ATP by maintaining a concentration imbalance between ATP and ADP. That is, the relevant energy is the Gibbs free energy, expressed in terms of how far from equilibrium the relative concentration is set at- in mammalian cells, the relative concentration of ATP to ADP, [ATP]/[ADP], is about 10 orders of magnitude different from equilibrium. Hydrolyzing a molecule of ATP to ADP releases some of this energy in a form able to perform (chemical) work.

More generally, cells often store energy in terms of the 'chemiosmotic potential': a concentration gradient can be made equivalent to an electrical potential (about 60 mV across the cell membrane, 150 mV across the mitochondrial membrane).
 
  • #6
Thank you for your replies. I am a self educated person and am finding all this truly fascinating! Sorry if I seem confused about some things - this isn't easy for me to understand!

Andy Resnick said:
The body stores energy in ATP by maintaining a concentration imbalance between ATP and ADP. That is, the relevant energy is the Gibbs free energy, expressed in terms of how far from equilibrium the relative concentration is set at- in mammalian cells, the relative concentration of ATP to ADP, [ATP]/[ADP], is about 10 orders of magnitude different from equilibrium. Hydrolyzing a molecule of ATP to ADP releases some of this energy in a form able to perform (chemical) work.


So the chemical energy stored in molecular bonds is released as these bonds are broken, making energy available for chemical work? Please may I ask what force is responsible for the chemical bonds? Is this strong and weak nuclear forces, or am I way off? Do forces of gravitation or electromagnetism come into it at all?

Also, if it is not too long an answer - how is this energy potential made available to a muscle cell so that I can peddle a bicycle, for example? And how is the energy made available to the muscle cell on an 'on demand' basis, such as during periods of intense activity? Is ATP production increased as the ratio of ATP/ADP moves towards equilibrium - a negative feedback system?


Andy Resnick said:
More generally, cells often store energy in terms of the 'chemiosmotic potential': a concentration gradient can be made equivalent to an electrical potential (about 60 mV across the cell membrane, 150 mV across the mitochondrial membrane).


Thank you for that information - I was under the impression that all of the body's energy was generated through the Krebs cycle and stored as ATP! Please may I ask, where does the cell find this energy? Is a 'concentration gradient' due to a differing ratio of +/- ions, generating a small electrical potential (?ionisation energy)- and is electromagnetic force responsible for the energy potential here? Also do you know how the cell utilises this energy, in terms of the muscle cell as in the questions above? Lastly, is there a reason that the 'concentration gradient' is greater across the mitochondrial membrane, other than an increased +/- differential?

I am interested in how the cell functions as a 'generator' or 'dynamo' for the energy required by living things, and what forces come into play in the generation of this energy. Please let me know if I should be posting in a different forum.

many thanks for any replies,
Sim
 
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  • #7
Similibus said:
Please may I ask what force is responsible for the chemical bonds? Is this strong and weak nuclear forces, or am I way off? Do forces of gravitation or electromagnetism come into it at all?
Molecular bonds are with electrons, therefore, the electromagnetic force.
 
  • #8
Similibus said:
<snip>

So the chemical energy stored in molecular bonds is released as these bonds are broken, making energy available for chemical work?

<snip>

Definitely not- that is a common conceptual misunderstanding. One phosphate bond is identical to any other phosphate bond- *work* cannot be extracted by "breaking" a chemical bond, although heat may be generated.

The work is stored via a displacement from equilibrium. That displacement is a chemical concentration imbalance- either spatially (on either side of a membrane) or by the Gibbs free energy, by maintaining a solution with concentrations different from equilibrium conditions.

Here's a simple example: water has a normal pH of 7.0. Equal numbers of H and OH ions. Let me put work into the system by removing a lot of OH, and holding the pH of my 'water' at 2.0. I now have the ability to extract work from that solution by using those excess H ions.
 

FAQ: Potential & Kinetic Energy of ATP in Krebs Cycle - Apology for Mistake

What is ATP and its role in the Krebs cycle?

ATP stands for adenosine triphosphate, a molecule that acts as the primary energy currency of cells. In the Krebs cycle, ATP is used to transfer energy to other molecules and drive cellular processes.

What is the difference between potential and kinetic energy in the context of ATP in the Krebs cycle?

Potential energy refers to the stored energy in the chemical bonds of ATP, while kinetic energy refers to the energy released when those bonds are broken. In the Krebs cycle, ATP is converted from potential to kinetic energy as it is broken down to release energy for cellular processes.

Why is it important to understand the energy of ATP in the Krebs cycle?

The Krebs cycle is a crucial part of cellular respiration, the process by which cells convert nutrients into energy. ATP, as the primary energy source, plays a key role in this process and understanding its energy dynamics can help us better understand how cells function.

What happens to the energy of ATP after it is used in the Krebs cycle?

After ATP is used to transfer energy in the Krebs cycle, it is converted back to its original form, adenosine diphosphate (ADP). The released energy is used for cellular processes, and the ADP can be converted back to ATP through processes such as oxidative phosphorylation.

What mistake was made in the original question about Potential & Kinetic Energy of ATP in Krebs Cycle?

The original question likely intended to ask about the energy of ATP in the electron transport chain, which is the final stage of cellular respiration. In the Krebs cycle, ATP is not directly involved in the transfer of electrons, but instead provides energy for this process to occur in the electron transport chain.

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