Four years after publication of the Schrödinger equation, Lev Davidovich Landau, age 23, solved the equation for a charged particle moving in a uniform magnetic field. A single electron moving perpendicular to a field B can be considered as a model atom without a nucleus, or as the irreducible quantum limit of the cyclotron. Landau proved that its energy is quantized in uniform steps of eħB/me. Gerald Gabrielse traps a single electron in an evacuated centimeter-size metal can cooled to a temperature of 90 mK. In a magnetic field of magnitude 5.37 T, the electron circulates for hours in its lowest energy level, generating a measurable signal as it moves. Evaluate the size of a quantum jump in the electron's energy. State your answer to the nearest micro electron Volt (µeV).

i provided a solution for the same problem but while using 5.26 T instead of 5.37 T. In the solution provided it gives the answer in eV but for my question, i need the answer to be in micro electron Volt (μeV). 

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(a) The size of the quantum jump in the electron's energy is ekB (1.60 x 10-19 C)(6.626x 104 J -s)(5.26 T) 2n 9.11x1081 kg) -34 AE -31 Mo 1 eV = 9.75 x 10-23 J =6.09x 104 eV = 609 xeV 1.60x 10-19 J

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Four years after publication of the Schrödinger equation, Lev Davidovich Landau, age 23, solved the equation for a charged particle moving in a uniform magnetic field. A single electron moving perpendicular to a field B can be considered as a model atom without a nucleus, or as the irreducible quantum limit of the cyclotron. Landau proved that its energy is quantized in uniform steps of eħB/me. Gerald Gabrielse traps a single electron in an evacuated centimeter-size metal can cooled to a temperature of 90 mK. In a magnetic field of magnitude 5.37 T, the electron circulates for hours in its lowest energy level, generating a measurable signal as it moves. Evaluate the size of a quantum jump in the electron's energy. State your answer to the nearest micro electron Volt (ueV).