Simply by living, an 87.5 kg human being will consume approximately 20.0 mol of 0, per day. To provide energy for the human, the O, is reduced to H,0 duing food oxidation by the reaction 0, + 4 H+ + 4e 2H,0 2. Determine the current generated by the human per day. In this case, the current is defined as the flow of electrons (e-) to O, from the food the human consumes. I = A Reduction of O, can occur by a donation of electrons from nicotinamide adenine dinucleotide (NADH). When this occurs, the electrons experience a potential drop of 1.10 V. Determine the power output from the 87.5 kg human. P = W
Simply by living, an 87.5 kg human being will consume approximately 20.0 mol of 0, per day. To provide energy for the human, the O, is reduced to H,0 duing food oxidation by the reaction 0, + 4 H+ + 4e 2H,0 2. Determine the current generated by the human per day. In this case, the current is defined as the flow of electrons (e-) to O, from the food the human consumes. I = A Reduction of O, can occur by a donation of electrons from nicotinamide adenine dinucleotide (NADH). When this occurs, the electrons experience a potential drop of 1.10 V. Determine the power output from the 87.5 kg human. P = W
Chemical Principles in the Laboratory
11th Edition
ISBN:9781305264434
Author:Emil Slowinski, Wayne C. Wolsey, Robert Rossi
Publisher:Emil Slowinski, Wayne C. Wolsey, Robert Rossi
Chapter32: Voltaic Cell Measurements
Section: Chapter Questions
Problem 2ASA
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Transcribed Image Text:Simply by living, an 87.5 kg human being will consume approximately 20.0 mol of 0, per day. To provide energy for the
human, the O, is reduced to H,0 duing food oxidation by the reaction
O, + 4H+ + 4 e 2H,0
2.
Determine the current generated by the human per day. In this case, the current is defined as the flow of electrons (e-) to O,
from the food the human consumes.
I =
A
Reduction of O, can occur by a donation of electrons from nicotinamide adenine dinucleotide (NADH). When this occurs,
the electrons experience a potential drop of 1.10 V. Determine the power output from the 87.5 kg human.
P =
W
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