List of equations in nuclear and particle physics

N₀ = Initial number of atoms at time t = 0
N_D = Number of atoms decayed at time t

${\displaystyle t\to t+T_{1/2}}$
${\displaystyle N\to N/2}$

Q = radiation quality factor (dimensionless)

W_j = weighting factors corresponding to radiosensitivities of matter (dimensionless)

${\displaystyle \sum _j{W}_j=1}$

• A = (Relative) atomic mass = Mass number = Sum of protons and neutrons
• N = Number of neutrons
• Z = Atomic number = Number of protons = Number of electrons

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• M'_nuc = Mass of nucleus, bound nucleons
• M_Σ = Sum of masses for isolated nucleons
• m_p = proton rest mass
• m_n = neutron rest mass

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• ${\displaystyle M_{\mathrm{\Sigma }}=Z{m}_p+N{m}_n}$
• ${\displaystyle M_{\mathrm{\Sigma }}>M_N}$
• ${\displaystyle \mathrm{\Delta }M=M_{\mathrm{\Sigma }}-M_{\mathrm{n}\mathrm{u}\mathrm{c}}}$
• ${\displaystyle \mathrm{\Delta }E=\mathrm{\Delta }M{c}^2}$

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hence (approximately) Template:Plainlist

• nuclear volume ∝ A
• nuclear surface ∝ A^2/3

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• E_B = binding energy,
• a_v = nuclear volume coefficient,
• a_s = nuclear surface coefficient,
• a_c = electrostatic interaction coefficient,
• a_a = symmetry/asymmetry extent coefficient for the numbers of neutrons/protons,Template:Endplainlist

where (due to pairing of nuclei) Template:Plainlist

• δ(N, Z) = +1 even N, even Z,
• δ(N, Z) = −1 odd N, odd Z,
• δ(N, Z) = 0 odd A

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• N₀ = Initial number of atoms
• N = Number of atoms at time t
• λ = Decay constant
• t = Time

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${\displaystyle \frac{\mathrm{d}N}{\mathrm{d}t}=-\lambda N}$

${\displaystyle N=N_0{e}^{-\lambda t}}$

• I₀ = Initial intensity/Flux of radiation
• I = Number of atoms at time t
• μ = Linear absorption coefficient
• x = Thickness of substance

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• E₀ = Resonant energy
• Γ, Γ_ab, Γ_c are widths of R, a + b, c respectively
• k = incoming wavenumber
• s = spin angular momenta of a and b
• J = total angular momentum of R

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${\displaystyle \sigma (E)=\frac{\pi g}{k^2}\frac{{\mathrm{\Gamma }}_{ab}{\mathrm{\Gamma }}_c}{(E-E_0{)}^2+{\mathrm{\Gamma }}^2/4}}$

Spin factor:

${\displaystyle g=\frac{2J+1}{(2s_a+1)(2s_b+1)}}$

Total width:

${\displaystyle \mathrm{\Gamma }={\mathrm{\Gamma }}_{ab}+{\mathrm{\Gamma }}_c}$

Resonance lifetime:

${\displaystyle \tau =\hslash /\mathrm{\Gamma }}$

• r = radial distance
• μ = Scattering angle
• A = 2 (spin-0), −1 (spin-half particles)
• Δk = change in wavevector due to scattering
• V = total interaction potential
• V = total interaction potential

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${\displaystyle \frac{d\sigma }{d\mathrm{\Omega }}={|\frac{2\mu }{{\hslash }^2}{\displaystyle \underset{0}{\overset{\mathrm{\infty }}{\int }}}\frac{\sin (\mathrm{\Delta }kr)}{\mathrm{\Delta }kr}V(r)r^{2}dr|}^2}$

• χ = reduced mass of a and b
• v = incoming velocity

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${\displaystyle \frac{d\sigma }{d\mathrm{\Omega }}=\left(\frac{\alpha }{4E}\right){[{\csc }^4\frac{\chi }{2}+{\sec }^4\frac{\chi }{2}+\frac{A\cos (\frac{\alpha }{\hslash \nu }\ln {\tan }^2\frac{\chi }{2})}{{\sin }^2\frac{\chi }{2}\cos \frac{\chi }{2}}]}^2}$

Scattering potential energy (α = constant):

${\displaystyle V=-\alpha /r}$

${\displaystyle \frac{d\sigma }{d\mathrm{\Omega }}=\left(\frac{1}{n}\right)\frac{dN}{d\mathrm{\Omega }}={\left(\frac{\alpha }{4E}\right)}^2{\csc }^4\frac{\chi }{2}}$

${\displaystyle {ℒ}_g=-\frac{1}{4}{W}_a^{\mu \nu }{W}_{\mu \nu }^a-\frac{1}{4}{B}^{\mu \nu }{B}_{\mu \nu }}$

${\displaystyle {ℒ}_f={\bar{Q}}_{i}iD/Q_i+{\bar{u}}_i^{c}iD/u_i^c+{\bar{d}}_i^{c}iD/d_i^c+{\bar{L}}_{i}iD/L_i+{\bar{e}}_i^{c}iD/e_i^c}$

${\displaystyle {ℒ}_h=|D_{\mu }h{|}^2-\lambda {(|h{|}^2-\frac{v^2}{2})}^2}$

${\displaystyle {ℒ}_y=-y_{uij}{ϵ}^{ab}{h}_b^{†}{\bar{Q}}_{ia}{u}_j^c-y_{dij}h{\bar{Q}}_i{d}_j^c-y_{eij}h{\bar{L}}_i{e}_j^c+h.c.}$