Determine the values of m and n when the following charge of a proton is written...

In the figure, a proton is projected horizontally midway between two parallel plates that are separated...

In the figure, a proton is projected horizontally midway between two parallel plates that are separated by 0.50 cm. The electrical field due to the plates has magnitude 610,000 N/C between the plates away from the edges. If the plates are 5.60 cm long, find the minimum speed of the proton if it just misses the lower plate as it emerges from the field. Please enter your answer in m/s without using scientific notation. (e = 1.60 × 10-19 C,...

Suppose that f(x)=x−3x^1/3 (A) Find all critical values of f. If there are no critical values,...

Suppose that f(x)=x−3x^1/3 (A) Find all critical values of f. If there are no critical values, enter -1000. If there are more than one, enter them separated by commas. Critical value(s) = (B) Use interval notation to indicate where f(x) is increasing. Note: When using interval notation in WeBWorK, you use INF for ∞∞, -INF for −∞−∞, and U for the union symbol. If there are no values that satisfy the required condition, then enter "{}" without the quotation marks....

A -5.00 μC charge is moving at a constant speed of 6.90×105 m/s in the +x−direction...

A -5.00 μC charge is moving at a constant speed of 6.90×105 m/s in the +x−direction relative to a reference frame. At the instant when the point charge is at the origin, what is the magnetic-field vector it produces at the following points. Part A x=0.500m,y=0, z=0 Enter your answers numerically separated by commas. Bx,By,Bz = nothing   T   SubmitRequest Answer Part B x=0, y=0.500m, z=0 Enter your answers numerically separated by commas. Bx,By,Bz = nothing   T   SubmitRequest Answer Part C...

Determine the percent ionization of the following solutions of phenol at 25°C:   (a) 0.713 M...

Determine the percent ionization of the following solutions of phenol at 25°C:   (a) 0.713 M   %   (b) 0.220 M   %   (c) 1.86 × 10−6 M   × 10% (Enter your answer in scientific notation.)

A -4.80 μC charge is moving at a constant speed of 6.80×105 m/s in the +x−direction...

A -4.80 μC charge is moving at a constant speed of 6.80×105 m/s in the +x−direction relative to a reference frame. At the instant when the point charge is at the origin, what is the magnetic-field vector it produces at the following points. Part A x=0.500m,y=0, z=0 Enter your answers numerically separated by commas. Part B x=0, y=0.500m, z=0 Part C x=0.500m, y=0.500m, z=0 Enter your answers numerically separated by commas. Part D x=0, y=0, z=0.500m

An infinitely long line of charge has a linear charge density of 5.00×10−12 C/m. A proton...

An infinitely long line of charge has a linear charge density of 5.00×10−12 C/m. A proton is at distance 18.0cm from the line and is moving directly toward the line with speed 1500 m/s. a) Calculate the potential of an infinitely long line from the electric field. b) Calculate the force felt by the proton when it is 18 cm from the line c) What is the maximum approximation of the proton to the load line? d) What is the...

4. A proton (charge +e = 1.602x 10^-19 C) moves a distance d = 0.50 m...

4. A proton (charge +e = 1.602x 10^-19 C) moves a distance d = 0.50 m in a straight line between points a and b in a linear accelerator. The electric field is uniform along this line, with magnitude E = 1.5x10^7 N/C in the direction from a to b. Determine (a) the work done on the proton by the field; (b) the potential difference Va - Vb.

A proton moves through a region of space where there is a magnetic field B⃗ =(0.64i+0.40j)T...

A proton moves through a region of space where there is a magnetic field B⃗ =(0.64i+0.40j)T and an electric field E⃗ =(3.3i−4.5j)×103V/m. At a given instant, the proton's velocity is v⃗ =(6.6i+2.8j−4.8k)×103m/s. Determine the components of the total force on the proton. Express your answers using two significant figures. Enter your answers numerically separated by commas.

An infinitely long line of charge has linear charge density 4.00×10^−12 C/m. A proton (mass 1.67×10^−27kg,...

An infinitely long line of charge has linear charge density 4.00×10^−12 C/m. A proton (mass 1.67×10^−27kg, charge +1.60×10^−19 C) is 18.0 cm from the line and moving directly toward the line at 3.80×10^3 m/s. How close does the proton get to the line of charge? Please show all steps CLEARLY so I can follow and understand how to derive the equation and solve for the answer with my given values. Thank you so much in advance!!!

A proton is located at a distance of 0.050 m from a point charge of +8.30...

A proton is located at a distance of 0.050 m from a point charge of +8.30 ?C. The repulsive electric force moves the proton until it is at a distance of 0.15 m from the charge. Suppose that the electric potential energy lost by the system were carried off by a photon. What would be its wavelength? answer isn't 1.248e-4nm