Three point-like charges are placed at the corners of a rectangle as shown in the figure, a = 20.0 cm and b = 66.0 cm. Find the magnitude of the electric force exerted on the charge q. Let q = −2.00 μC, q = −3.90 μC, q = −3.70 μC.
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Three point-like charges are placed at the corners of a rectangle as shown in the figure, a = 20.0 cm and b = 66.0 cm. Find the magnitude of the electric force exerted on the charge q. Let q = −2.00 μC, q = −3.90 μC, q = −3.70 μC.
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- X= 5009618.596 Y=3664880.325 Z=1409190.807 SAT ID, X, Y, Z1 -16344666.151 -2728939.557 20658479.4432 14599389.291 21642189.782 -4841358.4083 -19782593.480 8031126.013 15713919.0265 10606629.037 11640082.198 -21490132.2286 5977034.172 25070732.986 6414596.3387 -10188818.151 13104378.593 -20387747.4068 -25478269.471 -6127327.576 -4840854.5699 -19660053.951 8957811.816 -15504101.90910 9176950.240 -23038750.733 9288715.55811 -21607341.598 -4784060.713 13988573.89712 19146698.015 -4291564.379 17616168.31313 20703829.603 12802029.889 -10783033.52914 -6803941.208 -15979931.468 20444839.08815 26544908.019 2713833.024 -2471391.08816 -9064955.452 -11862746.652 -22100079.35817 -3913538.697 14423991.316 22362387.48918 -17734815.436 -12799604.808 14692010.24119 6629923.708 15395724.715 20282174.52320 14081250.296 -22413255.230 -1110279.75221 6774854.395 -16745700.078 -18696887.44222 -17987713.323 391728.476 19756616.90823 -25791816.315 2079256.748 -6572981.34524 18096088.396 7150727.508…G kinema x HW 1 WP NWP A X G At a fo X b Answe X b Enter y x C Solved x G kinema x WP Wiley X WileyP X + A education.wiley.com/was/ui/v2/assessment-player/index.html?launchld=e8766b99-b0e5-4f5f-a66b-abe3e9936.. E Update : Paused E HW 1 Question 6 of 7 > 0/1 X Incorrect Starting from rest at home plate, a baseball player runs to first base (90 ft away). He uniformly accelerates over the first 10.5 ft to his maximum speed, which is then maintained until he crosses first base. If the overall run is completed in 3.8 seconds, determine his maximum speed, the acceleration over the first 10.5 feet, and the time duration of the acceleration. t = 0 t = 3.8 sec 10.5- 79.5' Answers: Vmax = 26 ft/sec a = i 33 ft/sec2 t = i 0.79 sec 9:46 PM O Type here to search DELL 49°F 1/24/2022 > 凸)Coulomb constant, k = 8.987 x 10° N · m2 /C2. Vacuum permitivity, €n = 8.854 x 10 12 F/m. Magnitude of the charge of the electron, e = -1.60217662 x 10-19 C. Mass of the electron, me = 9.10938356 x 10 31 kg. Unless specified otherwise, each symbol carries their usual meaning. For example, uC means micro coulomb. +Y ↑ +x Coordinates of three charges in a 2D plane is given as follows: q1 = -42 µC at p1 = (-9,14), q2 = 21 µC at p2 = (-13,17) and q3 = -30 pC at p3 = (-9, -20). These coordinates are given in centimeters. c) Compute force on qi due to q2. x component of the force Give your answer to at least three significance digits. y component of the force Give your answer to at least three significance digits. d) Compute force on q due to q3- z component of the force Give your answer to at least three significance digits. y component of the force Give your answer to at least three significance digits. N e) Compute net force on qi due to q2 and q3. You can use the superposition principle…
- Coulomb constant, k=8.987×109N⋅m2/C2. Vacuum permitivity, ϵ0=8.854×10−12F/m. Magnitude of the Charge of one electron, e=−1.60217662×10−19C. Mass of one electron, me=9.10938356×10−31kg. Mass of one proton, mp=1.6726219×10−27kg, Charge of one proton, ep=1.60217662×10−19C Unless specified otherwise, each symbol carries their usual meaning. For example, μC means microcoulomb . PartI Suppose, We have a dipole where 3 charges q1=3e,q2=2e,q3=−5e are placed on the vertices of the square as shown in the figure given above. Side length of the square is 2nm. a) Calculate the dipole moment of this dipole. X component of the dipole: Y component of the dipole: b) Calculate the electric potential at point P due to this dipole. PartII Now suppose, we have a continuous charge distribution D for which potential at any point (x,y) in the xy plane is given by, V(x,y)=3xy(mx+n), where V is in volt, coordinates x, y are in meter, m, n both are constant and m=1N/Cm2, n=1N/Cm. c) Calculate the potential at…Coulomb constant, k=8.987×109N⋅m2/C2. Vacuum permitivity, ϵ0=8.854×10−12F/m. Magnitude of the Charge of one electron, e=−1.60217662×10−19C. Mass of one electron, me=9.10938356×10−31kg. Mass of one proton, mp=1.6726219×10−27kg, Charge of one proton, ep=1.60217662×10−19C Unless specified otherwise, each symbol carries their usual meaning. For example, μC means microcoulomb . PartI Suppose, We have a dipole where 3 charges q1=3e,q2=2e,q3=−5e are placed on the vertices of the square as shown in the figure given above. Side length of the square is 3nm. a) Calculate the X and Y components of dipole moment of this dipole. b) Calculate the electric potential at point P due to this dipole. PartII Now suppose, we have a continuous charge distribution D for which potential at any point (x,y) in the xy plane is given by, V(x,y)=3xy(mx+n), where V is in volt, coordinates x, y are in meter, m, n both are constant and m=1N/Cm2, n=1N/Cm. c) Calculate the potential at point P due to continuous charge…Coulomb constant, k=8.987×109N⋅m2/C2. Vacuum permitivity, ϵ0=8.854×10−12F/m. Magnitude of the Charge of one electron, e=−1.60217662×10−19C. Mass of one electron, me=9.10938356×10−31kg. Mass of one proton, mp=1.6726219×10−27kg, Charge of one proton, ep=1.60217662×10−19C Unless specified otherwise, each symbol carries their usual meaning. For example, μC means microcoulomb . PartI Suppose, We have a dipole where 3 charges q1=3e,q2=2e,q3=−5e are placed on the vertices of the square as shown in the figure given above. Side length of the square is 2nm. a) Calculate the dipole moment of this dipole.
- For the equation 3Cu+ 8HNO3 3Cu(NO3)2+ 2NO + 4H20, how many units of NO3 are represented on the products side? 2. 8. Submit Next Save and Exit Mark this and return US Sign cot 36Coulomb constant, k=8.987×109N⋅m2/C2. Vacuum permitivity, ϵ0=8.854×10−12F/m. Magnitude of the charge of the electron, e=−1.60217662×10−19C. Mass of the electron, me=9.10938356×10−31kg. Unless specified otherwise, each symbol carries their usual meaning. For example, μC means microcoulomb . Coordinates of three charges in a 2D plane is given as follows: q1=33μC at p1=(18,8), q2=37μC at p2=(−12,−12) and q3=−13μC at p3=(−7,−18). These coordinates are given in centimeters. a) Compute x and y components of force on q1 due to q2. b) Compute x and y components of force on w1 due to q3.21/WI B X M Inbox (9 x ILourseld=16544025&OpenVellumHMAC=ed9a5440b33a265c23d9d62107290c4c#10001 O Post Att x Scott B x O Course Xx + puTube M Gmail D Web design tutori. WA MATH180: HW08-. Update Winter 2021 PHYS 231 03 Hi, ala v Sign Out Help g Physics Course Home I Review I Constants A 1.3 kg ball on the end of a lightweight rod is located at (z, y) = (3.0 m, 2.0 m), where the y-axis is vertical. The other end of the rod is attached to a pivot at (z, y) = (0 m, 3.0 m). Part A What is the torque about the pivot? Express your answer using unit vectors. Express your answer in terms of the unit vectors i, j, and k. Use the 'unit vector' button to denote unit vectors in aring your answer. ? Hνα ΑΣφ Nm 7 = Submit Request Answer Next> Provide Feedback 64 RU
- Coulomb constant, k = 8.987 x 10° N· m2/C2. Vacuum permitivity, eo = 8.854 x 10-12 F/m. Magnitude of the charge of the electron, e = -1.60217662 x 10-19 C. Mass of the electron, me = 9.10938356 x 10-31 kg. Unless specified otherwise, each symbol carries their usual meaning. For example, µC means micro coulomb +x Coordinates of three charges in a 2D plane is given as follows: q1 = -45 µC at pi = (17, 17), g2 = 21 µC at p2 = (17, –11) and g3 = 43 µC at p3 = (-15, 13). These coordinates are given in centimeters. a) Compute force on q2 due to qi using the formula F12 = k 12- I component of the force Give your answer to at least three significance digits. y component of the force Give your answer to at least three significance digits. N b) Compute force on q2 due to qi using the formula F12 = kr12. I component of the force Give your answer to at least three significance digits. y component of the force Give your answer to at least three significance digits.In this question, please explain to me why x and y components are not considered? Why is it simply B1cos60 + B1cos60?The spherical harmonics wavefunction Y,²(0, 4) = sin²0 e¬i2 is given. a) Normalize the wavefunction. b) Show that Y7²(0, 4) is an eigenfunction of the total energy operator ( Hamiltonian) for 3D rigid rotator model c) What is the energy and the degeneracy of the state represented by Yz²(0, 4)?