
In chemistry, the standard state for as solution is 1 M (see Table17.2). This means that each solute concentration expressed in molarity is divided by 1 M. In biological systems, however, we define the standard state for the H+ ions to be 1×10−7 M because the physiological pH is about 7. Consequently, the change in the standard Gibbs free energy according to these two conventions will be different involving uptake or release of H+ ions, depending on which convention is used. We will therefore replaced ΔG° with ΔG°′, where the prime denotes that it is the standard Gibbs free-energy change for a biological process. (a) Consider the reaction
where x is a
(b) NAD+ and NADH are the oxidized and reduced forms of nicotinamide adenine dinucleotide, two key compounds in the
ΔG° is −21.8 kJ/mol at 298 K. Calculate ΔG°′. Also calculate ΔG using both the chemical and biological conventions when [NADH] = 1.5 × 10−2 M, [H+] = 3.0 × 10−5 M, [NAD] = 4.6 × 10−3 M, and
(a)

Interpretation:
The standard free energy
Concept Introduction:
Free energy
Free energy (Gibbs free energy) is the term that is used to explain the total energy content in a thermodynamic system that can be converted into work. The free energy is represented by the letter
Explanation of Solution
The given reverse process reaction is,
Let us consider the following free energy equation,
Where
Here the chemical standard of (1M), we can write has,
For the biological standard state, so we can write as,
We set the two equations (1) and (2) equal to each other,
Given the reverse reaction
(b)

Interpretation:
The standard free energy value
Concept Introduction:
Thermodynamics is the branch of science that relates heat and energy in a system. The four laws of thermodynamics explain the fundamental quantities such as temperature, energy and randomness in a system. Entropy is the measure of randomness in a system. For a spontaneous process there is always a positive change in entropy. Free energy (Gibbs free energy) is the term that is used to explain the total energy content in a thermodynamic system that can be converted into work. The free energy is represented by the letter G. All spontaneous process is associated with the decrease of free energy in the system. The equation given below helps us to calculate the change in free energy in a system.
Where,
Free energy (Gibbs free energy) is the term that is used to explain the total energy content in a thermodynamic system that can be converted into work. The free energy is represented by the letter
Explanation of Solution
Next we calculate the standard free energy
We can now calculate
The chemical standard state is,
The biological standard state is,
The expected free energy
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Chapter 17 Solutions
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- S: Using a phase diagram leksogi/x/sl.exe/1ou-IgNs kr 7j8P3jH-IQs_pBan HhvTCeeBZbufuBYTI0Hz7m7D3ZdHYU+80XL-5alyVp O States of Matter Using a phase diagram to find a phase transition temperature or pressure se the phase diagram of Substance X below to find the boiling point of X when the pressure on the liquid is 1.6 atm. pressure (atm) 32- 16- solid liquid 0. gas 100 200 temperature (K) 300 Note: your answer must be within 12.5 °C of the exact answer to be graded correct. 10 Explanation Check § Q Search J 2025 McGraw Hill LLC. All Rights Researrow_forward151.2 254.8 85.9 199.6 241.4 87.6 242.5 186.4 155.8 257.1 242.9 253.3 256.0 216.6 108.7 239.0 149.7 236.4 152.1 222.7 148.7 278.2 268.7 234.4 262.7 283.2 143.6 QUESTION: Using this group of data on salt reduced tomato sauce concentration readings answer the following questions: 1. 95% Cl Confidence Interval (mmol/L) 2. [Na+] (mg/100 mL) 3. 95% Na+ Confidence Interval (mg/100 mL)arrow_forwardResults Search Results Best Free Coursehero Unloc xb Success Confirmation of Q x O Google Pas alekscgi/x/lsl.exe/1o_u-IgNslkr 7j8P3jH-IQs_pBanHhvlTCeeBZbufu BYTI0Hz7m7D3ZcHYUt80XL-5alyVpwDXM TEZayFYCavJ17dZtpxbFD0Qggd1J O States of Matter Using a phase diagram to find a phase transition temperature or pressure Gabr 3/5 he pressure above a pure sample of solid Substance X at 101. °C is lowered. At what pressure will the sample sublime? Use the phase diagram of X below to nd your answer. pressure (atm) 24- 12 solid liquid gas 200 400 temperature (K) 600 ote: your answer must be within 0.15 atm of the exact answer to be graded correct. atm Thanation Check © 2025 McGraw Hill LLC. All Rights Reserved. Terms of Use | Privacy Center I Q Search L³ ملةarrow_forward
- 301.7 348.9 193.7 308.6 339.5 160.6 337.7 464.7 223.5 370.5 326.6 327.5 336.1 317.9 203.8 329.8 221.9 331.7 211.7 309.6 223.4 353.7 334.6 305.6 340.0 304.3 244.7 QUESTION: Using this group of data on regular tomato sauce concentration readings answer the following questions: 1. 95% Cl Confidence Interval (mmol/L) 2. [Na+] (mg/100 mL) 3. 95% Na+ Confidence Interval (mg/100 mL)arrow_forwardSearch Results Search Results Best Free Coursehero Unlo x b Success Confirmation of Q aleks.com/alekscgi/x/sl.exe/10_u-lgNslkr7j8P3jH-IQs_pBan HhvlTCeeBZbufu BYTIOHz7m7D3ZcHYUt80XL-5alyVpwDXM TEZayFYCav States of Matter Using a phase diagram to find a phase transition temperature or pressure Use the phase diagram of Substance X below to find the temperature at which X turns to a gas, if the pressure above the solid is 3.7 atm. pressure (atm) 0. 32- 16 solid liquid gas 200 temperature (K) Note: your answer must be within 20 °C of the exact answer to be graded correct. Дос Xarrow_forwardConsider the reaction below to answer the following questions: Acetoacetic ester can be prepared by the Claisen self-condensation reaction of ethyl acetate. 1. NaOEt, EtOH H&C OCH CH3 2 H30 H3C CH2 OCH2CH3 A. Write the complete stepwise mechanism for this reaction. Show all electron flow with arrows and draw all intermediate structures. B. Ethyl acetate can be prepared from ethanol as the only organic starting material. Show all reagents and structures for all intermediates in this preparation. C. Give the structures of the ester precursors for the following Claisen condensation product and formulate the reaction. OEtarrow_forward
- Use the phase diagram of Substance X below to find the temperature at which X turns to a gas, if the pressure above the solid is 3.7 atm. pressure (atm) 32 16 solid liquid gas 0 0 200 temperature (K) Note: your answer must be within 20 °C of the exact answer to be graded correct. Шос ☑ كarrow_forwardStarting from bromoethane, how could you prepare the following compounds: a. Ethanol. b. Acetaldehyde f. Acetone. e. 2-Propanol i. Acetoacetic ester. d. 2-Bromoacetic acid. c. Acetic acid g. Acetamide. j. Ethylmalonate k. Gama ketoacid. h. Ethyl magnesium bromide.arrow_forward- The pressure above a pure sample of solid Substance X at 60. °C is raised. At what pressure will the sample melt? Use the phase diagram of X below to find your answer. pressure (atm) 02 0.4 solid Hliquid gas 0 0 200 400 600 temperature (K) Note: your answer must be within 0.025 atm of the exact answer to be graded correct. ☐ atmarrow_forward
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