For Q6 through Q8, use the following information. A positronium atom is formed from an electron and a positron, the positron being a particle like an electron, with essentially the same mass, but with a positive charge. Presume that the model for a positronium atom is otherwise like the hydrogen atom, but with this different mass for the positively charged particle. The different reduced mass of this system will lead to different "Rydberg" and "Bohr radius" values. Give your answer to three significant figures, using scientific notation (i.e. 1.23e-3). What will be the "Rydberg" (and hence the magnitude of the "binding" energy), in eV, of this positronium particle?

For Q6 through Q8, use the following information. A positronium atom is formed from an electron and a positron, the positron being a particle like an electron, with essentially the same mass, but with a positive charge. Presume that the model for a positronium atom is otherwise like the hydrogen atom, but with this different mass for the positively charged particle. The different reduced mass of this system will lead to different "Rydberg" and "Bohr radius" values. Give your answer to three significant figures, using scientific notation (i.e. 1.23e-3). What will be the "Rydberg" (and hence the magnitude of the "binding" energy), in eV, of this positronium particle?

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