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1.3.4 Atoms and molecules Name Symbol Definition nucleon number, mass number proton number, atomic number neutron number electron rest mass mass of atom, atomic mass atomic mass constant mass excess elementary charge, proton charage Planck constant Planck constant/2π Bohr radius Rydberg constant fine structure constant ionization energy electron affinity A 1 Z 1 N me ma, m N=A-Z mu ∆ e mu = ma( C)/12 ∆ = ma - Amu h h a0 R∞ α Ei Eea 12 h = h/2π 2 2 a0 = 4πε0 h /mee R∞ = Eh/2hc 2 α = e /4πε0 h c 1 SI unit 1 kg kg kg kg C Notes (1) (1), (2) Js Js m -1 m J J (1) Analogous symbols are used for other particles with subscripts: p for proton, n for neutron, a for atom, N for nucleus, etc. (2) mu is equal to the unified atomic mass unit, with symbol u, i.e. mu = 1 u. In biochemistry the name dalton, with symbol Da, is used for the unified atomic mass unit, although the name and symbols have not been accepted by CGPM. Chapter 1 - 1 Name Symbol Definition electronegativity dissociation energy from the ground state from the potential minimum principal quantum number (H atom) angular momentum quantum numbers magnetic dipole moment of a molecule magnetizability of a molecule Bohr magneton χ Ed, D D0 De χ = ½(Ei +Eea) J n E = -hcR/n (3) SI unit (3) J J J 2 Notes (4) (4) 1 see under Spectroscopy, section 3.5. -1 m, µ Ep = -m⋅B ξ m = ξB JT µB µB = eh/2me JT JT (5) -2 -1 The concept of electronegativity was intoduced by L. Pauling as the power of an atom in a molecule to attract electrons to itself. There are several ways of defining this quantity. The one given in the table has a clear physical meaning of energy and is due to R.S. Mulliken. The most frequently used scale, due to Pauling, is based on bond dissociation energies in eV and it is relative in the sense that the values are dimensionless and that only electronegativity differences are defined. For atoms A and B χ r, A − χ r, B = (eV ) −1 / 2 E d (AB) − [E d (AA) + E d (BB)] where χr denotes the Pauling relative electronegativity. The scale is chosen so as to make the relative electronegativity of hydrogen χr,H = 2.1. There is a difficulty in choosing the sign of the square root, which determines the sign of χr,A - χr,B. Pauling made this choice intuitively. (4) The symbols D0 and De are mainly used for diatomic dissociation energies. (5) Magnetic moments of specific particles may be denoted by subscripts, e.g. µe, µp, µn for an electron, a proton and a neutron. Chapter 1 - 2 Name Symbol Definition SI unit nuclear magneton magnetogyric ratio (gyromagnetic ratio) g-factor nuclear g-factor Larmor angular frequency Larmor frequency relaxation time, longitudinal transverse electric field gradient tensor activity (of a radioactive substance) decay (rate) constant, disintegration (rate) constant half life mean life level width disintegration energy cross section (of a nuclear reaction) µN γ µN = (me/mp)µB γ = µ/L JT -1 -1 s T g gN ωL vL g = 2µ/µB gN = µ/IµN ωL = (e/2m)B vL = ωL/2π 1 1 -1 s Hz Notes -1 (6) (7) T1 T2 q A qαβ = -∂ V/∂α∂β A = -dNB/dt s s -2 Vm Bq λ, k A = λNB s (9) t½,T½ τ Γ Q σ NB(t½)= NB(0)/2 τ = 1/λ Γ = h/τ s s J J 2 m (9), (10) (10) 2 -1 (8) (8) (9) (6) µ is the magnetic moment, L the angular momentum. (7) This quantity is commonly called Larmor circular frequency. (8) These quantities are used in the context of saturation effects in spectroscopy, particularly spin-resonance spectroscopy (see section 3.5). (9) NB is the number of radioactive atoms B. (10) Half lives and mean lives are often given in years (a), see conversion tables. t½ = τ ln2 for exponential decays. Chapter 1 - 3