A model of a red blood cell portrays the cell as a shperical capacitor, a positively charged liquid sphere of surface area A separated from the surrounding negatively charged fluid by a membrane of thickness t. Tiny electrodes introduced into the interior of the cell show a potential difference of 100 mV across the membrane. The membrane’s thickness is estimated to be 100 nm and has a dielectric constant of 5.00. (a) If an average red blood cell has a mass of 1.00 x 10–12 kg, estimate the volume of the cell and thus find its surface area. The density of blood is 1 100 kg/m3. (b) Estimate the capacitance of the cell by assuming the membrane surfaces act as parallel plates. (c) Calculate the charge on the surface of the membrane. How many electronic charges does the surface charge represent?

Q: Two capacitors, C₁ = 4.00 μF and C₂ = 10.0 μF, are connected in parallel, and the resulting…

A: a) 14.0μFb) V1 = 9.00V, V2 = 9.00Vc) Q1 = 36.0μC, Q2 = 90.0μCExplanation:Please see the attached…

Q: Three capacitors charged with the following capacitances and corresponding voltages, (a) calculate…

A: Let us consider three capacitors having the capacity (Ca),(Cb) & (Cc) in Farad and different…

Q: A parallel plate capacitor, in which the space between the plates is filled with a dielectric…

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Q: A capacitor consists of two 6.0-cm-diameter circular plates separated by 1.0 mm. The plates are…

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Q: Two parallel-plate capacitors, 8.7 uF each, are connected in parallel to a 43 V battery. One of the…

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Q: Find the voltage V across the capacitor and the charge Qf stored by it after the dielectric is…

A: Voltage, V across the capacitor= 2.07 V

Q: A potential difference of 102 mV exists between the inner and outer surfaces of the membrane of a…

A: Given:Potential difference,∆V= 102×10-3 V The charge on the Na+atom  = charge of the electron…

Q: Consider the system of capacitors shown in the figure below (C1 = 2.00 µF, C2 = 9.00 µF). (a) Find…

A: Given that the capacitors  C1=2.00μF, and C2=9.00μF.

Q: A battery capable of producing a potential difference of 100 V and a parallel-plate capacitor…

A: The potential difference is V=100 V. The dielectric constant is k=4.6. The area of plate is A=0.18…

Q: Many electric cars can capture the kinetic energy of the car and store it in a capacitor or a…

A: Given data: Mass (m) = 1380 kg Initial velocity (v0) = 17.0 m/s Final velocity (v) = 0 m/s Potential…

Q: Three capacitors having capacitances of 6.00, 6.00, and 3.00 µF, respectively, are connected in…

A: Given:   Three capacitor connected in series,  C1 = 6 μF C2 = 6 μF C3 = 3 μF Voltage =27 V

Q: A capacitor can be made from two sheets of aluminum foil separated by a sheet of waxed paper. If the…

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Q: The figure shows four capacitors and a battery that supplies a potential difference of AV = 0 V. The…

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Q: A parallel plate capacitor, in which the space between the plates is filled with a dielectric…

A: Given dielecric constant k=5.5capacitance C=442 μFvoltage of battery V=16V=constant (Battery is…

Q: Two parallel-plate capacitors C₁ and C₂ are connected in parallel to a 12.0 V battery. Both…

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Q: A simple capacitor consists of two rectangular plates, each with an area of 5.3 cm2, and are…

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Q: (a) When a battery is connected to the plates of a 5.00-µF capacitor, it stores a charge of 15.0 µC.…

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Q: An air-filled (empty) parallel-plate capacitor is made from two square plates that are 28 cm on each…

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Q: In the figure below, capacitor 1 (C₁ = 27.0 μF) initially has a potential difference of 60.0 V and…

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Q: Two parallel-plate capacitors are constructed using dielectric materials with dielectric constants…

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Q: Two parallel-plate capacitors, 8.7 μF each, are connected in parallel to a 43 V battery. One of the…

A: Solution:Given:C1 = capacitance of capacitor 1 = 8.7 μFC2 = capacitance of capacitor 2 = 8.7 μFVb =…

Q: A parallel plate capacitor has a capacitance of 2.0 µF and plate separation of 1.0 mm. (a) How much…

A: Given:- The capacitance of the plate C = 2.0 x 10-6  F  The plate are seprated by d=  1.0 mm = 1 x…

Q: For the system of four capacitors shown in Figure, find (a) the equivalent capacitance of the…

A: Equivalent capacitance in parallel C = C1 + C2    equivalent capacitance in series 1/C = 1/C1 + 1/C2…

Q: Two capacitors, C, = 6.00 µF and C, = 13.0 µF, are connected in parallel, and the resulting…

A: Given data:  Two capacitors are connected in parallel C1 = 6.00 μF C2 = 13.0 μF Battery voltage (V)…

Q: Capacitor of unknown capacitance (C₁) has been charged to a potential difference of 300 V and then…

A: thank you

Q: A parallel plate capacitor consists of two rectangular plates, each with an area of 4.5 cm2 and are…

A: U=12CV2=12ε0AdV2=ε0εrAV22d

Q: For a 5.6 µF capacitor which has a charge of 90 mC, how much energy is stored in the capacitor:

A: charge on the capacitor is Q = 90 mC Q = 90 x 10-3 C the capacitance of the capacitor is C = 5.6 μF…

Q: An initially uncharged air-filled capacitor is connected to a 2.07 V charging source. As a result,…

A: V= 2.07 volts  Q= 3.39× 10-5 C  K= 4.25

Q: A 9V battery is connected across a set of capacitors distributed in the arrangement shown in the…

A: “Since you have posted a question with multiple sub-parts, we will solve first three sub-parts for…

Q: The same voltage is applied between the plates of two different capacitors. When used with capacitor…

A: Let the applied voltage = V For capacitor A : charge stored (Q) = 15 μC Energy stored (E) = 5.3×10-5…

Q: Two capacitors, C¡ = 4.00 µF and C, = 9.00 µF, are connected in parallel and the resulting…

A: The equivalent capacitance of capacitors C1=4×10-6 F and C2=9×10-6 F in parallel by using the…

Q: In the figure a potential difference of V-100 V is applied across a capacitor arrangement with…

A: We have C1 = 9.08 μF   C2 = 7.32 μF  C3 = 14.3 μF  V = 100 v

Q: A model of a red blood cell portrays the cell as a spherical capacitor, a positively charged liquid…

A: thickness of membrane = 98 nm dielectric constant = 5 mass of average red blood cell = 1.10×10-12 kg…

Q: A model of a red blood cell portrays the cell as a spherical capacitor, a positively charged liquid…

A:

Q: An engineer builds a parallel-plate capacitor with adjustable spacing between the plates. When the…

A: Part-(a): A capacitor consists of 2 isolated conductors (the plates) with opposite charges +q and…

Q: A parallel plate capacitor, in which the space between the plates is filled with a dielectric…

A: Given that Capacitance of capacitor C = 870 micro Farad Dielectric constant K = 3 Voltage of the…

Q: A parallel-plate air-filled capacitor having area 31 cm² and plate spacing 1.2 mm is charged to a…

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Q: model of a red blood cell portrays the cell as a spherical capacitor, a positively charged liquid…

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Q: A dielectric-filled parallel-plate capacitor has plate area A = 10.0 cm2cm2 , plate separation d =…

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Q: The plates of a parallel-plate capacitor are charged to a potential difference of 35.0 V. If the…

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Dielectric Constant Of Water

Water constitutes about 70% of earth.  Some important distinguishing properties of water are high molar concentration, small dissociation constant and high dielectric constant.

Electrostatic Potential and Capacitance

An electrostatic force is a force caused by stationary electric charges /fields. The electrostatic force is caused by the transfer of electrons in conducting materials. Coulomb’s law determines the amount of force between two stationary, charged particles. The electric force is the force which acts between two stationary charges. It is also called Coulomb force.