IUPAC Gold Book - Quantities

Quantities

A B C D E FGH IJK L M N O P Q R S TUV WXYZ

quantity	symbol	referenced in	equation
$G$ value in nuclear chemistry	$Math - math$	$G$ value in nuclear chemistry	$G$
gain, $G$ of a photomultiplier	$Math - math$	gain, $G$ of a photomultiplier	$G$
		gain, $G$ of a photomultiplier	$G = k σ n$
generation time, $t G$ in biotechnology	$Math - math$	generation time, $t G$ in biotechnology	$t G$
Gibbs energy (function), $G$	$Math - math$	chemical equilibrium	$G$
		Marcus equation (for electron transfer)	$Δ G ‡ = ( λ + Δ ET G o ) 2 4 λ$
		Marcus equation (for electron transfer)	$Δ ET G o$
	$Math - ci$	driving force (for electron transfer)	$Δ ET G o$
		Gibbs energy of photoinduced electron transfer	$Δ ET G o = N A e E o D +• / D − E o A / A −• + w D +• A −• − w DA − Δ E 0,0$
		Gibbs energy of photoinduced electron transfer	$Δ ET G o = N A e ( E ox o − E red o ) + z A − z D − 1 e 2 4 π ɛ 0 ɛ r a − Δ E 0,0$
		normal region (for electron transfer)	$Δ ET G o$
		normal region (for electron transfer)	$− Δ ET G o ≤ λ$
		Rehm–Weller equation	$k q = k d 1 + k d K d Z exp ( Δ G ‡ R T ) + exp ( Δ ET G o R T )$
	$Math - apply$	miscibility	$( ∂ 2 Δ mix G ∂ ϕ 2 ) T , p > 0$
		miscibility	$Δ mix G$
Gibbs energy of activation (standard free energy of activation), $Δ ‡ G o$	$Math - math$	Gibbs energy of activation (standard free energy of activation), $Δ ‡ G o$	$Δ ‡ G o$
	$Math - apply$	Gibbs energy of activation (standard free energy of activation), $Δ ‡ G o$	$Δ ‡ G = R T ln ( k B h ) − ln ( k T )$
	$Math - apply$	Marcus equation (for electron transfer)	$k ET = κ ET k T h exp ( − Δ G ‡ R T )$
		Marcus equation (for electron transfer)	$Δ G ‡ = ( λ + Δ ET G o ) 2 4 λ$
		Rehm–Weller equation	$k q = k d 1 + k d K d Z exp ( Δ G ‡ R T ) + exp ( Δ ET G o R T )$
		Rehm–Weller equation	$Δ G ‡$
Gibbs film elasticity	$Math - apply$	Gibbs film elasticity	$E = A ( ∂ σ ∂ A ) T , p , n i$