(a)
Interpretation:
Equation for the parallel capacitance Cp should be determined.
Concept introduction:
In a capacitor, the charge Q is directly proportional to the applied voltage.
Q = CV
V = Apply voltage
Q = quantity of the charge
C = Capacitance of capacitor
(b)
Interpretation:
Cp, charge on each capacitor and the total charge Qp should be calculated.
Concept introduction:
In a capacitor, the charge Q is directly proportional to the applied voltage.
Q = CV
V = Apply voltage
Q = quantity of the charge
C = Capacitance of capacitor
(c)
Interpretation:
An equation for the total capacitance (Cs) of a series capacitor circuit should be determined.
Concept introduction:
In a capacitor, the charge Q is directly proportional to the applied voltage.
Q = CV
V = Apply voltage
Q = quantity of the charge
C = Capacitance of capacitor
(d)
Interpretation:
Cs and the voltage drop across each capacitor should be calculated of a series capacitor circuit should be determined.
Concept introduction:
In a capacitor, the charge Q is directly proportional to the applied voltage.
Q = CV
V = Apply voltage
Q = quantity of the charge
C = Capacitance of capacitor
(e)
Interpretation:
An equation for the total capacitance (Cs) of a series with two capacitor circuit should be determined.
Concept introduction:
In a capacitor, the charge Q is directly proportional to the applied voltage.
Q = CV
V = Apply voltage
Q = quantity of the charge
C = Capacitance of capacitor
(f)
Interpretation:
The capacitance of the network, voltage across each capacitor and the charge on each capacitor should be calculated.
Concept introduction:
In a capacitor, the charge Q is directly proportional to the applied voltage.
Q = CV
V = Apply voltage
Q = quantity of the charge
C = Capacitance of capacitor
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Chapter 2 Solutions
Principles of Instrumental Analysis
- 1) One of Dr. G’s CHEM 102 students is working part-time at a hardware store. A customer tells this student “I need a single stud (a wooden beam) from which I can cut two (2) pieces of 2.7m studs”. The student does the math, goes behind counter, and brings a stud cut to 5m length. Select the most sensible and scientific answer to this situation. A) 2.7 × 2 when operated as a significant figure multiplication, gets you 5 and the student is right. B) Hardware stores don’t comply with correct sig. fig. rules for measurements. C) The customer must pay for 5.4m worth; but he/she should only get 5m to take home. D) The word ‘Two (2)’ mentioned here carries infinite significance, so the student is wrong. E) The word ‘Two (2)’ mentioned here is not a ‘measurement’, therefore this is an example of a situation where there is disagreement between science and day-to-day life.arrow_forward(a) A silicon sample maintained at T = 300 K is uniformly doped with Nd = 1016cm-3 donors. Calculate the resistivity of the sample.arrow_forwardI need step by step process solving [4.184x156(Tf-295)] + [4.184x85.2(Tf-368)] = 0. because my work is wrong. Thank you!!arrow_forward
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- The measured Eocell=+2.222 V. Using EoMg2+/Mg= -2.372 V, calculate Eo Sn2+/Sn in voltsarrow_forwardThe following data were obtained from the calibration of an air-displacement pipette by repetitive drawing 1000.0 microliters of pure water at 4.00 °C using this pipette and weighing them on an analytical balance, which gave the following readings, respectively: 1.003, 1.000, 1.005, 1.007 g. How many measurements would have to be averaged to obtain an S/N of 1000? Type your numeric answer and submitarrow_forward(b) The random error, r', on the result, R, is given by F = √()*² + ( )² R where v', and v, are the random errors on V', and Vt, respectively (1) Let V=26.00 mL, V = 24.00 mL; v' = ±0.01 (3) mL, vt = ±0.01 (2) mL. What is the percentage random error, r'/R x 100%, on R? (2) What is r'/Rx 100 if the conditions of each titration vary (e.g., different portions of the burette stem are used) so that V₁= 26.00 mL, V₁ = 24.00 mL; v' = ±0.05(2) mL, vt = ±0.04(8) mL?arrow_forward
- You have a solution containing two metal cations. You want to separate them by slowly and carefully adding a solution of an anion, until one metal cation precipitates as a compound with that anion, leaving the other metal cation still in solution. Your metal cations (M+ and M2+) and your anion M+= Cu^+ M^2+= Cd^2+ Anion= S^2- First Ksp(M+ w/anion)= 2.5 x 10-48 Second Ksp(M2+ w/anion)= 1.0 x 10-28 ----------------------------------------------------------------------------------- Starting concentrations of yourmetal ions in your initial solution: [M+]= 4.00 x 10-5 M [M2+]= 2.50 x 10-5 M Using these values, predict which metal will precipitate first, and at what concentration of anion the precipitation will begin. Clearly state the parameters of your particular problem at the beginning. What is M+, what is M2+, what are your concentrations, what are you solving for?arrow_forwardPart F The third variable (call it v) is v=x1-cx2 + x3, where c is a constant you need to determine so that the equation for v is the SHM equation. Determine v. The solution to the equation for vis v = 2B cos(t + b). Express your answer in terms of some, all, or none of the variables 21, 22, 23, and the appropriate constants. v = ΜΕ ΑΣΦ Submit Request Answer ?arrow_forwardAG° is independent of temperature. TRUE FALSEarrow_forward
Principles of Instrumental AnalysisChemistryISBN:9781305577213Author:Douglas A. Skoog, F. James Holler, Stanley R. CrouchPublisher:Cengage Learning