(a)
Interpretation:
The time it would take to discharge a 0.025 µF capacitor to 1% of its full charge through a resistance of 10 Mχ should be calculated.
Concept introduction:
The product of RC is referred to as time constant for the circuitand is a measure of the time required for a capacitor to chargeor discharge.
Capacitor is discharged to 1% of its full charge. Therefore, the value of charge at time ‘t’ can be related to the initial charge by following equation.
Time taken for the discharge of the capacitor can be calculated using following relationship;
(b)
Interpretation:
The time it would take to discharge a 0.025 µF capacitor to 1% of its full charge through a resistance of 1 Mχ should be calculated.
Concept introduction:
The product of RC is referred to as time constant for the circuit and is a measure of the time required for a capacitor to charge or discharge.
Capacitor is discharged to 1% of its full charge. Therefore, the value of charge at time ‘t’ can be related to the initial charge by following equation.
Time taken for the discharge of the capacitor can be calculated using following relationship;
(c)
Interpretation:
The time it would take to discharge a 0.025 µF capacitor to 1% of its full charge through a resistance of 1 kχ should be calculated.
Concept introduction:
The product of RC is referred to as time constant for the circuit and is a measure of the time required for a capacitor to charge or discharge.
Capacitor is discharged to 1% of its full charge. Therefore, the value of charge at time ‘t’ can be related to the initial charge by following equation.
Time taken for the discharge of the capacitor can be calculated using following relationship;
Want to see the full answer?
Check out a sample textbook solution
Chapter 2 Solutions
PRINCIPLES OF INSTRUMENTAL ANALYSIS
- The mobility of a Li+ ion in an aqueous solution is 4.01×10−8 m2s−1 V−1 at 25°C. The potential difference between two electrodes in the solution placed 1.0 cm apart is 12.0 V. What is the lithium ion current rate? (Use μms-1 for your answer)arrow_forward9:01 A elearning.alsafwa.edu.iq الوقت المتبقي 0:43:09 1 Jlgw غير مجاب علیه بعد الدرجة من 3.00 علم هذا السؤال When a current of 0.4 A flows for 1.5 micro-seconds in a coper wire, estimate the number of electrons crossing the cross-section of the wire No. of electron= 4.8×10-19 electron No. of electron= 1.875×1012 electron No. of electron= 3x10-7 electron No. of electron= 4.8×10-26 electron الصفحة التالية الإعلاناتarrow_forwardAn air-gap parallel plate capacitor whose plates have an area of A=0,38m² are separated by a distance d=0,61m and are connected to a battery of V₁ = 1,8 V. The space between the parallel plates is partially filled (x=0,26m) with some material of dielectric constant K=4,56. Find the electric potential energy stored in the capacitor in terms of permitivity of free-space €0. Express your answer using 2 decimal places.arrow_forward
- The exchange-current density for a Pt|Fe3+,Fe2+ electrode is 2.5 mA cm−2. The standard potential of the electrode is +0.77 V. Derive an expression for the current flowing through an electrode of surface area 1.0 cm2 as a function of the potential applied to the electrode; assume standard conditions.arrow_forwardAn electrochemical cell consists of a Pt|H+ (aq,1.00 M)|H₂(g) cathode connected to a Pt|H+ (aq)|H₂(g) anode in which the H+ concentration is that of a buffer consisting of a weak acid, HA(0.181 M), mixed with its conjugate base, A (0.157 M). The measured cell voltage is Eºcell = 0.258 V at 25 °C, with PH₂ = 1.00 atm at both electrodes. Calculate the pH in the buffer solution and the Ka of the weak acid. Submit Answer Retry Entire Group pH = K₂ = 9 more group attempts remainingarrow_forwardThe electric field strength between the plates of a simple air capacitor is equal to the voltage across the plates divided by the distance between them. When a kV voltage of 64.6 V is put across the plates of such a capacitor an electric field strength of 3.4 is measured. Write an equation that will let you calculate the distance d between the plates. Your equation should contain only symbols. Be sure you define each symbol. Your equation: d = 0 Definitions of your symbols: kV 0 = 3.4 cm 0 = 64.6 V 010 X E A cm 3arrow_forward
- Consider a hydrogen electrode in H Br(aq) at 25 °C operating at 145 bar. Estimate the change in the electrode potential when the solution is changed from 5.0 mmol dm-3 to 15.0 mmol dm-3.arrow_forwardSilver is uniformly electro-deposited on a metallic vessel of surface area of 900 cm2 by passing a current of 0.5 ampere for 2 hours. Calculate the thickness of silver deposited.[Given: the density of silver is 10.5 g cm-3 and atomic mass of Ag = 108 amu.]arrow_forwardThe Weibull distribution is widely used in statistical problems relating to aging of solid insulating materials subjected to aging and stress. Use this distribution as a model for time (in hours) to failure of solid insulating specimens subjected to AC voltage. The values of the parameters depend on the voltage and temperature; suppose ? = 2.2 and ? = 220. (a) What is the probability that a specimen's lifetime is at most 250? Less than 250? More than 300? (Round your answers to five decimal places.) at most 250 less than 250more than 300 (b) What is the probability that a specimen's lifetime is between 100 and 250? (Round your answer to four decimal places.) (c) What value (in hr) is such that exactly 50% of all specimens have lifetimes exceeding that value? (Round your answer to three decimal places.) hrarrow_forward
- You make the following voltage measurements at four different temperatures. Temperature (°C): 13 30 48 70 Eocell (V): 1.247 1.242 1.237 1.231 Calculate the ΔGorxn at each of these temperatures:arrow_forwardHow many electrons or protons are transported through the double layer per second for each of the electrodes Cu,H2|H+ and Pt|Ce4+,Ce3+ when they are at equilibrium at 25 °C? Take the area as 1.0 cm2 in each case. Estimate the number of times each second a single atom on the surface takes part in an electron transfer event, assuming an electrode atom occupies about (260 pm)2 of the surface.arrow_forwardHelp me pleasearrow_forward
ChemistryChemistryISBN:9781305957404Author:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCostePublisher:Cengage Learning
ChemistryChemistryISBN:9781259911156Author:Raymond Chang Dr., Jason Overby ProfessorPublisher:McGraw-Hill Education
Principles of Instrumental AnalysisChemistryISBN:9781305577213Author:Douglas A. Skoog, F. James Holler, Stanley R. CrouchPublisher:Cengage Learning
Organic ChemistryChemistryISBN:9780078021558Author:Janice Gorzynski Smith Dr.Publisher:McGraw-Hill Education
Chemistry: Principles and ReactionsChemistryISBN:9781305079373Author:William L. Masterton, Cecile N. HurleyPublisher:Cengage Learning
Elementary Principles of Chemical Processes, Bind...ChemistryISBN:9781118431221Author:Richard M. Felder, Ronald W. Rousseau, Lisa G. BullardPublisher:WILEY