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Chapter 25: Problem 45

Treatment of Heart Failure. A heart defibrillator is used to enable the heart to start beating if it has stopped. This is done by passing a large current of 12 A through the body at 25 \(\mathrm{V}\) for a very short time, usually about 3.0 \(\mathrm{ms}\) . (a) What power does the defibrillator deliver to the body, and (b) how much energy is transferred?

Short Answer

Expert verified
Power is 300 W, and energy transferred is 0.9 J.

Step by step solution

01

Understand the Variables

To find the power delivered by the defibrillator, we must clearly understand the variables given: current \( I = 12 \, \mathrm{A} \), voltage \( V = 25 \, \mathrm{V} \), and time \( t = 3.0 \, \mathrm{ms} \). Power \( P \) is defined as the rate of energy transfer. It can be calculated using the formula \( P = IV \).
02

Calculate Power Delivered

Use the formula \( P = IV \) to calculate power.\[P = (12 \, \mathrm{A})(25 \, \mathrm{V}) = 300 \, \mathrm{W}\] Thus, the defibrillator delivers 300 watts of power to the body.
03

Convert Time to Seconds

The time provided is in milliseconds, but we need the time in seconds to calculate energy. Convert milliseconds to seconds:\[t = 3.0 \, \mathrm{ms} = 3.0 \times 10^{-3} \, \mathrm{s}\]
04

Calculate Energy Transferred

Energy transferred \( E \) is the product of power and time. Use the formula \( E = Pt \).\[E = (300 \, \mathrm{W})(3.0 \times 10^{-3} \, \mathrm{s}) = 0.9 \, \mathrm{J}\]Thus, the energy transferred is 0.9 joules.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Heart Defibrillator
A heart defibrillator is a life-saving device used primarily in emergencies when a person's heart has stopped beating effectively. The main purpose of a defibrillator is to deliver a controlled electric shock to the heart, which can help restore a normal rhythm. This electrical pulse temporarily stops all electrical activity in the heart and gives it a chance to reset. It's like sending a restart command to your computer when it freezes.

These devices are crucial in medical settings and sometimes in public spaces, as they can help prevent sudden cardiac arrest from becoming fatal. They are designed to be easy to use, even for individuals without medical training, due to semi-automated systems that guide the user through the process.
  • Typically applies high voltage for a very brief moment.
  • Used in scenarios of heart failure or irregular heart rhythms.
  • Can be part of automated external defibrillators (AEDs) accessible in public places.
Current and Voltage
In electrical terms, **current** and **voltage** are crucial components for understanding how energy is transferred through a system like a heart defibrillator. Current, denoted as "I" in equations, is the flow of electric charge and is measured in amperes (A). Voltage, represented as "V," is the electric potential difference between two points, measured in volts (V).

For a heart defibrillator, a high current of 12 amperes and a voltage of 25 volts are used to achieve effective energy transfer into the body. This combination ensures that sufficient energy is applied quickly enough to be effective without causing excessive harm or discomfort to the patient. The relationship between current and voltage is critical, as it defines the power output using the equation:

Power Calculation

The power (P) delivered by the defibrillator can be calculated using:
  • Formula: \( P = IV \)
  • Where \( I = 12 \, \mathrm{A} \) and \( V = 25 \, \mathrm{V} \)
  • Resulting in: \( P = 300 \, \mathrm{W} \)

This formula indicates how effectively the device transfers energy at any given moment.
Energy Transfer Calculation
Calculating the energy transferred by a heart defibrillator involves understanding the relationship between power, time, and energy. Energy, in this context, refers to the amount of work done or the amount of electrons moved through an electric circuit, which in the case of a defibrillator, helps the heart muscles reset their contractions.

**Energy Transfer Formula**
To calculate the energy transferred (E) during defibrillation:
  • Use the formula: \( E = Pt \)
  • Where power \( P = 300 \, \mathrm{W} \) and time \( t = 3.0 \, \mathrm{ms} = 3.0 \times 10^{-3} \, \mathrm{s} \)
  • The energy transferred is \( E = 0.9 \, \mathrm{J} \)

By converting milliseconds to seconds, you ensure that the time is correctly factored into the calculation, which deduces the precise amount of energy transmitted during this vital procedure. Understanding this energy transfer is crucial, as applying the correct dosage of energy determines the success of restarting the heart's normal rhythm.

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Most popular questions from this chapter

A \(12.0-\mathrm{V}\) battery has an internal resistance of 0.24 \(\mathrm{s}\) and a capacity of 50.0 \(\mathrm{A} \cdot \mathrm{h}\) (see Exercise 25.47\() .\) The battery is charged by passing a 10 -A current through it for 5.0 \(\mathrm{h}\) . (a) What is the terminal voltage during charging? (b) What total electricalenergy is supplied to the battery during charging? (c) What electrical energy is dissipated in the internal resistance during charging? (d) The battery is now completely discharged through a resistor, again with a constant current of 10 \(\mathrm{A}\) . What is the external circuit resistance? (e) What total electrical energy is supplied to the external resistor? (f) What total electrical energy is dissipated in the internal resistance? (g) Why are the answers to parts (b) and (e) not the same?

Transmission of Nerve Impulses. Nerve cells transmit electric signals through their long tubular axons. These signals propagate due to a sudden rush of \(\mathrm{Na}^{+}\) ions, each with charge \(+e,\) into the axon. Measurements have revealed that typically about \(5.6 \times 10^{11} \mathrm{Na}^{+}\) ions enter each meter of the axon during a time of 10 \(\mathrm{ms}\) . What is the current during this inflow of charge in a meter of axon?

A wire 6.50 \(\mathrm{m}\) long with diameter of 2.05 \(\mathrm{mm}\) has a resistance of 0.0290\(\Omega .\) What material is the wire most likely made of?

A source with emf \(\mathcal{E}\) and internal resistance \(r\) is connected to an external circuit. (a) Show that the power output of the source is maximum when the current in the circuit is one-half the short-circuit current of the source. (b) If the external circuit consists of a resistance \(R,\) show that the power output is maximum when \(R=r\) and that the maximum power is \(\mathcal{E}^{2} / 4 r_{1}\)

A cylindrical copper cable 1.50 \(\mathrm{km}\) long is connected across a 220.0 -V potential difference. (a) What should be its diameter so that it produces heat at a rate of 75.0 \(\mathrm{W}^{\prime}\) (b) What is the electric field inside the cable under these conditions?
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