The figure below shows three positively charged particles at three corners of a rectangle. The particle at upper left has a charge q1 = 4.00 nC, the one at the lower left has a charge of q2 = 5.00 nC,and the one at lower right has a charge q3 = 6.00 nC. The rectangle's horizontal side has length x = 5.00 cm and its vertical side has length y = 3.50 cm. Three positive charges lie at three of the corners of a rectangle of horizontal side length x and vertical side length y < x. An charge labeled q1 is at the upper left corner. A charge labeled q2 is at the lower left corner. A charge labeled q3 is at the lower right corner. (a)What is the electric potential (in V) at the upper-right corner of the rectangle? (Assume the zero of electric potential is at infinity.) ______V (b)What would be the potential (in V) at the upper-right corner if the charge q2 at lower left was−5.00 nC instead? _____V

The figure below shows three positively charged particles at three corners of a rectangle. The particle at upper left has a charge q1 = 4.00 nC, the one at the lower left has a charge of q2 = 5.00 nC,and the one at lower right has a charge q3 = 6.00 nC. The rectangle's horizontal side has length x = 5.00 cm and its vertical side has length y = 3.50 cm. Three positive charges lie at three of the corners of a rectangle of horizontal side length x and vertical side length y < x. An charge labeled q1 is at the upper left corner. A charge labeled q2 is at the lower left corner. A charge labeled q3 is at the lower right corner. (a)What is the electric potential (in V) at the upper-right corner of the rectangle? (Assume the zero of electric potential is at infinity.) __V (b)What would be the potential (in V) at the upper-right corner if the charge q2 at lower left was−5.00 nC instead? _V

Related questions

Q: +4.00 µC The drawing shows an equilateral triangle, each side of which has a length of 2.00 cm.…

Q: There are two charges in the xy plane and no other nearby charges. There is a 9 millicoulomb charge…

A: Q1 = 9×10-³ C Q2 = 8×10-³ C x = 21 m y = 35 m

Q: Three charges are arranged in a triangle. The first charge has a magnitude of 6.7 nC and is located…

Q: In the figure below, each charged particle is located at one of the four vertices of a square with…

Q: Two small plastic spheres are given positive electric charges. When they are 15.0 cm apart, the…

A: Since it is a multipart question, I answer the second part. Please resubmit the first…

Q: Two identical conducting spheres, fixed in place, attract each other with an electrostatic force of…

Q: Two charges, q1 = −11 nC and q2 = 29.5 nC, are separated by a distance d = 2.50 cm as shown in…

Q: A metallic sphere has a charge of +4.00 nC. A negatively charged rod has a charge of −6.00 nC. When…

A: Given data The charge on the sphere is given as Qs = 4 nC. The charge on the rod is given as Qr =…

Q: There is a 30 microcoulomb charge at the origin. There is a 203 microcoulomb charge on the x axis at…

A: Given data: q1 = 30 μC at origin q2 = 203μC at x = 4 m q3 = 151 μC at y = 5 m

Q: The drawing shows an equilateral triangle, each side of which has a length of 1.99 cm. Point charges…

Q: A large positively-charged object with charge q = 3.75 ?C is brought near a negatively-charged…

Q: as shown in the figure. Two charges and two points lie along the perimeter of an equilateral…

Q: Four charges of +1.2 µC are placed at three corners of a square of side 10.0 cm. What is the…

A: First we have to calculate electrostatic force on a charge due to other charges. Then add them…

Q: b. Two charges are lying on the horizontal axis and are 0.2m away from each other. The charges are:…

Q: The figure below shows three small, positively charged beads at three corners of a rectangle. The…

Q: a) What is the force of q2 on q1 in the x direction, Fx? Give your answer in newtons, and recall k =…

A: Given data: The first charge is: q1=4.6×10-16 C The second charge is: q2=-1.5×10-16 C The third…

Q: Four point charges of equal magnitude Q = 75 nC are placed on the corners of a rectangle of sides D1…

Q: 9 9 S S 9 9 N 9 Point A 9 9

Q: A large positively charged object with charge q4 = 4.75 µC is brought near a negatively charged…

A: Given data The magnitude of the positively charged object is q+ = 4.75 μC = 4.75 x 10-6 C The…

Q: Two identical conducting spheres, fixed in place, attract each other with an electrostatic force of…

Q: The charge Q is midway between two other charges, q1 and q2. If Q = +9.0 nC, what must be the %3D…

A: Given data: Charge Q placed between q1 and q2 at midpoint. Q = +9.0 nC

Q: Charge q1 = 27 μC is located at r1 = (3.7 i − 3.5 j) m. A second charge q2 = −37.8 μC is located at…

Q: Three-point charges are fixed to the corners of an equilateral triangle, as the drawing shows. The…

A: We are given 3 charges. We are given values of these 3 charges. We are given that these charges are…

Q: Two identical conducting spheres, fixed in place, attract each other with an electrostatic force of…

A: Given: F=0.108N, r=0.702m, F'=0.0515N Let the charges on spheres be q1 and q2 initially. They are…

Q: Two identical conducting spheres, fixed in place, attract each other with an electrostatic force of…

A: The attractive force acting between the spheres is given. Then the spheres are connected and the…

Q: 2q d +-x 2d d

Q: Two particles, one with charge −4.61×10−6 C and the other with charge 3.55×10−6 C, are 0.0434 m…

Q: Two identical conducting spheres, fixed in place, attract each other with an electrostatic force of…

A: Approach to solving the question: Detailed explanation:Examples: Key references:

Q: Three charges are placed in a line. Charge A is at x = -0.0500 m, Charge B is at the origin, and…

Q: A thin charged rod has a linear charge density of λ = 8.00 nC/m. How much charge is on a piece of…

Q: The figure below shows three small, positively charged beads at three corners of a rectangle. The…

Question

The figure below shows three positively charged particles at three corners of a rectangle. The particle at upper left has a charge q₁ = 4.00 nC, the one at the lower left has a charge of q₂ = 5.00 nC,and the one at lower right has a charge q₃ = 6.00 nC. The rectangle's horizontal side has length x = 5.00 cm and its vertical side has length y = 3.50 cm.

Three positive charges lie at three of the corners of a rectangle of horizontal side length x and vertical side length y < x.

An charge labeled q₁ is at the upper left corner.
A charge labeled q₂ is at the lower left corner.
A charge labeled q₃ is at the lower right corner.

(a)What is the electric potential (in V) at the upper-right corner of the rectangle? (Assume the zero of electric potential is at infinity.)

______V

(b)What would be the potential (in V) at the upper-right corner if the charge q₂ at lower left was−5.00 nC instead?

_____V

Expert Solution

This question has been solved!

Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.

This is a popular solution!

SEE SOLUTION Check out a sample Q&A here

Step 1

Step 2

Step 3

Step 4

Trending now

This is a popular solution!

Step by step

Solved in 4 steps

SEE SOLUTION Check out a sample Q&A here

Similar questions

Let's say two unknown charges are given to you. You do not know their individual charges, but you know that their total charge is 8.00µC. You made a test in the laboratory and found that these two charges push each other away with a force of 0.150 N when separated by 0.500 m. What is the charge of the "higher charge" in units of µC ?
Three charges are located as shown in the figure, with values q1 = 3.3 × 10-16 C, q2 = -1.1 × 10-16 C, q3 = 6.25 × 10-16 C. The charges are separated by d1 = 2.9 × 10-6 m and d2 = 2.1 × 10-6 m. What is the force of q2 on q1 in the x direction, Fx? Give your answer in newtons, and recall k = 8.988 × 109 N m2/C2.
The figure below shows three small, positively charged spheres at three corners of a rectangle. The particle at upper left has a charge q, = 3.00 nC, the one at the lower left has a charge of g2 = 4.00 nC, and the one at lower right has a charge q3 = 6.00 nC. The rectangle's horizontal side has length x = 5.00 cm and its vertical side has length y = 3.50 cm. Three positive charges lie at three of the corners of a rectangie of horizontal side length X and vertical side length yx. • An charge labeled q, is at the upper left corner. • A charge labeled q, is at the lower left comer A charge labeled q is at the lower right corner. (a) What is the electric potential (in V) at the upper-right corner of the rectangle? (Assume the zero of electric potential is at infinity.) (b) What would be the potential (in V) at the upper-right corner if the charge q, at lower left was -4.00 nC instead?
Three-point charges are fixed to the corners of an equilateral triangle, as the drawing shows. The magnitude of charge A, located in the lower-left corner, is qA = -5.0 μC. The magnitude of charge B, located in the top corner, is q = +7µC. The magnitude of charge C, located in the lower-right corner, is qc = +2µC. The lengths of the sides of the triangle are 5.0 cm. Show all your work for full credit. For each step below, provide a brief statement as to why you chose a particular strategy to solve the question. 1. What is the magnitude of the electromagnetic force between charge 9₁ and 92?
The magnitude of the net electric field, at point P, midway between the two charges is: a 3.48 x108 N/C b 6.00 x 107 N/C c 5.22 x 106 N/C d 8.99 x 105 N/C
Two identical, charged styrofoam balls are hung by threads from a ceiling, as shown in Figure 2. The balls each have a mass m = 425 g and the thread has a length of 30.0 cm. In equilibrium the angle 0 = 26.0°. What is the magnitude of the charge on each ball? (0) A q1 9₁ Enter your answer in µC.
The figure below shows three small, positively charged spheres at three corners of a rectangle. The particle at upper left has a charge q, = 8.00 nC, the one at the lower left has a charge of q2 = 4.00 nC, and the one at lower right has a charge q, = 6.00 nC. The rectangle's horizontal side has length x = 5.50 cm and its vertical side has length y = 4.00 cm. (a) What is the electric potential (in V) at the upper-right corner of the rectangle? (Assume the zero of electric potential is at infinity.) 2.65*10**3 What is the electric potential at a point due to a single charged particle? Given more than one charged particle, how do you find the total potential at a point? How far is each charge from upper right point? Be careful with units and signs. V (b) What would be the potential (in V) at the upper-right corner if the charge q, at lower left was -4.00 nC instead? 2.71*10**3 Use the same method as used in part (a). Note q, is now the opposite sign. How does this affect the potential due…
Three charges, q₁ =-2.7 µC, q2 =5.4 μC and 93 =2 μC are placed on xy plane as shown in the picture below. 92 a 91 y b a a = 4.0 cm b = 2.0 cm r12 r13 = √√√a² + b² = 0.0447 m 93 X What is the x component of the net force exerted on charge q₁ by charges 92 and 93. Provide your answer in newtowns with the precision of two places after decimal.
Two small particles have charges Q₁ = +4.0 μC and Q₂ = -7.0 μC. The particles are conducting and are brought together so that they touch. Charge then moves between the two particles so as to make the excess charge on the two particles equal. If the particles are then separated by a distance of 5.4 mm, what is the magnitude of the electric force between them?
Four identical charged particles (g = +10.1 µC) are located on the corners of a rectangle as shown in the figure below. The dimensions of the rectangle are L = 64.2 cm and W = 14.6 cm. L (a) Calculate the magnitude of the total electric force exerted on the charge at the lower left corner by the other three charges. (b) Calculate the direction of the total electric force exerted on the charge at the lower left corner by the other three charges. ° (counterclockwise from the +x-axis)
2 narrow, flat metal plates are positioned vertically, 20.00 cm. The first plate has a positive charge with charge density σ=+630.0 mC/m2 and a second plate has an equal but opposite negative charge with charge density σ=-6300.0 mC/m2 . There are also two narrow, flat metal plates positioned horizontally, 30.00 cm apart, with the top plate given a negative charge, and the bottom plate given an equal but opposite positive charge, such that the electric potential of the bottom plate is 5.00 V higher than the top plate. A small sphere with a mass of m =64.35 g, and a charge of q =22.00 mC is attached to a narrow, stiff, massless, insulating rod with a length of L= 8.00 cm, which is pivoted at point O, which is 2.000 cm from the second plate. The sphere/rod unit is angled at 5 degrees with horizontal and released from rest. Will the sphere/rod ever hit an angle of 0 degrees with the horizontal? If so, how long will it take to reach that point?
Four identical charged particles (q +10.4 pC) are located on the corners of a rectangle as shown in the figure below. The dimensions of the rectangle are L 54.6 cm and W 14.7 cm L W (a) Calculate the magnitude of the total electric force exerted on the charge at the lower left corner by the other three charges. N (b) Calculate the direction of the total electric force exerted on the charge at the lower left corner by the other three charges. (counterclockwise from the x-axis)