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Today’s agenda: Electric potential energy. You must be able to use electric potential energy in work-energy calculations. Electric potential. You must be able to calculate the electric potential for a point charge, and use the electric potential in work-energy calculations. Electric potential and electric potential energy of a system of charges. You must be able to calculate both electric potential and electric potential energy for a system of charged particles (point charges today, charge distributions next lecture). The electron volt. You must be able to use the electron volt as an alternative unit of energy. Electric Potential Energy of a System of Charges Electric potential energy comes from the interaction between pairs of charged particles, so you have to add the potential energies of each pair of charged particles in the system. (Could be a pain to calculate!) Electric Potential of a System of Charges The potential due to a particle depends only on the charge of that particle and where it is relative to some reference point. The electric potential of a system of charges is simply the sum of the potential of each charge. (Much easier to calculate!) Example: electric potential energy of three charged particles A single charged particle has no electrical potential energy. To find the electric potential energy for a system of two charges, we bring a second charge in from an infinite distance away: r q1 q1 U 0 before q2 q1q 2 U k r after To find the electric potential energy for a system of three charges, we bring a third charge in from an infinite distance away: r12 q1 q2 before q1q 2 U k r12 q1 r12 q2 r13 r23 q3 after q1q 2 q1q3 q 2q3 U k r13 r23 r12 We have to add the potential energies of each pair of charged particles. Electric Potential of a Charge Distribution 1 Collection of charges: VP 40 (details next lecture) qi i r . i P is the point at which V is to be calculated, and ri is the distance of the ith charge from P. Charge distribution: 1 dq V . 40 r Potential at point P. We’ll work with this next lecture. dq P r “In homework and on exams, can I automatically assume the electric potential outside of a spherically-symmetric charge distribution with total charge Q is the same as the electric potential of a point charge Q located at the center of the sphere?” Exception: in 23.5 (if assigned), because the spheres are “small” you can calculate potential energies using the equation for the potential energy of point charges. Example: a 1 C point charge is located at the origin and a -4 C point charge 4 meters along the +x axis. Calculate the electric potential at a point P, 3 meters along the +y axis. y q1 q 2 qi VP = k = k + i ri r1 r2 P 3m r 1 r2 q1 4m q2 x -6 -6 1×10 -4×10 9 = 9×10 + 3 5 = - 4.2×103 V Example: how much work is required to bring a +3 C point charge from infinity to point P? (And what assumption must we make?) 0 y Wexternal E K U q3 Wexternal U q3V P 0 3m q1 Wexternal q3 VP V 4m q2 x Wexternal 3 106 4.2 103 Wexternal 1.26 103 J The work done by the external force was negative, so the work done by the electric field was positive. The electric field “pulled” q3 in (keep in mind q2 is 4 times q1). Positive work would have to be done by an external force to remove q3 from P. Example: find the total potential energy of the system of three charges. y q3 q1 q 2 q1 q3 q 2 q3 U = k + + r r r 13 23 12 P r23 3m r 13 r12 q2 4m q1 x -6 -6 -6 -6 1×10-6 -4×10-6 1×10 3×10 -4×10 3×10 U = 9 109 + + 4 3 5 U = - 2.16 10-2 J Today’s agenda: Electric potential energy. You must be able to use electric potential energy in work-energy calculations. Electric potential. You must be able to calculate the electric potential for a point charge, and use the electric potential in work-energy calculations. Electric potential and electric potential energy of a system of charges. You must be able to calculate both electric potential and electric potential energy for a system of charged particles (point charges today, charge distributions next lecture). The electron volt. You must be able to use the electron volt as an alternative unit of energy. The Electron Volt An electron volt (eV) is the energy acquired by a particle of charge e when it moves through a potential difference of 1 volt. U= qV 1 eV= 1.6 10-19C 1 V 1 eV= 1.6 10-19 J This is a very small amount of energy on a macroscopic scale, but electrons in atoms typically have a few eV (10’s to 1000’s) of energy. Example: on slide 9 we found that the potential energy of the hydrogen atom is about -4.36x10-18 joules. How many electron volts is that? 1 eV U = -4.36 10 J = -4.36 10 J -27.2 eV -19 1.6 10 J -18 -18 “Hold it! I learned in Chemistry (or high school physics) that the ground-state energy of the hydrogen atom is -13.6 eV. Did you make a physics mistake?” The ground-state energy of the hydrogen atom includes the positive kinetic energy of the electron, which happens to have a magnitude of half the potential energy. Add KE+PE to get ground state energy. Homework Hints! You’ll need to use starting equations from Physics 1135! Remember your Physics 1135 hammer equation? Ef Ei Wother if What “goes into” Ef and Ei? What “goes into” Wother? This is also handy: Uf Ui Wc if Homework Hints! Work-Energy Theorem: Wnet if K “Potential of a with respect to b” means Va - Vb