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som . (a) Red Blood cells often become charged and can be treated as point charges...
Consider the following. 0.500 mm 60.00 (a) Red blood cells often become charged and can be treated as point charges. Healthy red blood cells are negatively charged, but unhealthy cells (due to the presence of a bacteria, for example) can become positively charged. In the figure, three red blood cells are oriented such that they are located on the corners of an equilateral triangle. The red blood cell charges are A = 2.40 PC, B = 6.90 pc, and C...
Red blood cells can often be charged. Consider two red blood cells with the following charges: -15.8 PC and +45.6 p. The red blood cells are 3.52 cm apart. (1 pc - 1 x 10-12 C.) (a) What is the magnitude of the force on each red blood cell? N Are the red blood cells attracted or repulsed by each other? attracted repulsed (b) The red blood cells come into contact with each other and then are separated by 3.52...
Red blood cells often can be charged. Two red blood cells are separated by 1.24 m and have an attractive electrostatic force of 0.974 N between them. If one of the red blood cells has a charge of +8.56 10-6 C, what is the sign and magnitude of the second charge, Q?
Red blood cells often can be charged. Two red blood cells are separated by 1.36 m and have an attractive electrostatic force of 0.980 N between them. If one of the red blood cells has a charge of +8.32 10-6 C, what is the sign and magnitude of the second charge, Q?
A model of a red blood cell portrays the cell as a spherical 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 95 nm and has a dielectric constant of 5.00 (a) If an average red blood cell has a...
A model of a red blood cell portrays the cell as a spherical 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 104 nm and has a dielectric constant of 5.00. (a) If an average red blood cell has a...
Three point charges are located at the corners of an equilateral triangle as in the figure below. Find the magnitude and direction of the net electric force on the 1.75 B-7.10 pC, and C -4.30 pC.) charge. (Let A = 1.75 pC, 0.500 m 60.0° magnitude direction below the +x-axis
Need help in calculating the first answer!
Red Blood Cells
Charge of Cell #1 = -1.8 x 10-12 C
Charge of Cell #2 = -3.1 x 10-12 C
Diameter = 6.8 x 10-6 m
Two red blood cells each have a mass of 7.50 x 10-14 kg and carry a negative charge spread uniformly over their surfaces The repulsion arising from the excess charge prevents the cells from clumping together. Once cell carries -1.80 pC of charge and the other...
A model of a red blood cell portrays the cell as a spherical 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 96 nm and has a dielectric constant of 5.00. (a) If an average red blood cell has a...
Two red blood cells each have a mass of 4.60 x 10-14 kg and carry a negative charge spread uniformly over their surfaces The repulsion arising from the excess charge prevents the cells from clumping together. Once cell carries-2.40 pC of charge and the other-3-10 pc, and each cell can be modeled as a sphere 7.60 μrm in diameter. What minimum relative speed o would the red blood cells need when very far away from each other to get close...