Excited-state response theory within the context of the coupled-cluster formalism

Abstract: The propagation of general electronic quantum states provides information of the interaction of molecular systems with external driving fields. These can also offer understandings regarding non-adiabatic quantum phenomena. Well established methods focus mainly on propagating a quantum system that is initially described exclusively by the ground state wavefunction. In this work, we expand a previously developed formalism within coupled cluster theory, called second response theory, so it propagates quantum syst… Show more

“…If known, Ψ(t) would determine all the measurable quantities of the system. Previous work [68] on SR CC theory showed how to propagate general arbitrary states by computing separately the CC representations of ⟨Ψ E | ÂH (t)|Ψ 0 ⟩, and ⟨Ψ E | ÂH (t)|Ψ E ⟩. In this current work we show how, through an integrated approach, an arbitrary initial state that includes a contribution from the ground state is propagated in SR CC theory.…”

“…However, the evolved 'right' excitation TD vector is not connected in a straightforward fashion to the EOM-CC eigen-vectors, nor the conjugate TD excitation vector. This motivates our goal, which is to describe the auxiliary observable shown in equation ( 8) through CC quantities, then use of the differential step followed by the limiting procedure presented in section 2.1 to compute ⟨Ψ(t)| Â|Ψ(t)⟩ (similarly as in [68]), without calculating the wavefunction Ψ(t) of course. It allows for a connection between EOM-CC eigen-vectors and general TD propagations, where one sets the values of the initial-state coefficients S, and {C N }.…”

“…where the subscript 'm' indicates the vectors are modified objects as they account for the new initial conditions (which depend on g L and g R ), xm = ∑ µ x m,µ τµ , and ⟨•⟩ 0 denotes average with respect to the reference (|0⟩): ⟨•⟩ 0 = ⟨0| • |0⟩. The terms x m,0 and λ m,0 are time-independent (this is a consequence of our TD variational method [68]). The phase follows the relation: ∂ t ϕ(t) = ⟨ λm (t)e −xm(t) Ĥ(t)e +xm (t)⟩ 0 .…”

“…The phase follows the relation: ∂ t ϕ(t) = ⟨ λm (t)e −xm(t) Ĥ(t)e +xm (t)⟩ 0 . This number, ϕ(t), does not influence the calculation of observable expectation values, so it will not be considered in detail in this work (its properties are presented in [68]). These modified operators determine the TD behavior of the following kept and its left conjugate:…”

“…The inner product of these two CC wavefunctions is ⟨Υ(t)|Φ(t)⟩ = ⟨ λm (t)⟩ 0 . As shown in [68], there are four (reduced to three in this work) TD excitation vectors that are needed to compute TD observables. These are: xr (t) = ∂ R xm (t), λl (t) = ∂ L λm (t), λr (t) = ∂ R λm (t), and λl,r (t) = ∂ 2 LR λm (t).…”

Second response theory: a theoretical formalism for the propagation of quantum superpositions

“…If known, Ψ(t) would determine all the measurable quantities of the system. Previous work [68] on SR CC theory showed how to propagate general arbitrary states by computing separately the CC representations of ⟨Ψ E | ÂH (t)|Ψ 0 ⟩, and ⟨Ψ E | ÂH (t)|Ψ E ⟩. In this current work we show how, through an integrated approach, an arbitrary initial state that includes a contribution from the ground state is propagated in SR CC theory.…”

“…However, the evolved 'right' excitation TD vector is not connected in a straightforward fashion to the EOM-CC eigen-vectors, nor the conjugate TD excitation vector. This motivates our goal, which is to describe the auxiliary observable shown in equation ( 8) through CC quantities, then use of the differential step followed by the limiting procedure presented in section 2.1 to compute ⟨Ψ(t)| Â|Ψ(t)⟩ (similarly as in [68]), without calculating the wavefunction Ψ(t) of course. It allows for a connection between EOM-CC eigen-vectors and general TD propagations, where one sets the values of the initial-state coefficients S, and {C N }.…”

“…where the subscript 'm' indicates the vectors are modified objects as they account for the new initial conditions (which depend on g L and g R ), xm = ∑ µ x m,µ τµ , and ⟨•⟩ 0 denotes average with respect to the reference (|0⟩): ⟨•⟩ 0 = ⟨0| • |0⟩. The terms x m,0 and λ m,0 are time-independent (this is a consequence of our TD variational method [68]). The phase follows the relation: ∂ t ϕ(t) = ⟨ λm (t)e −xm(t) Ĥ(t)e +xm (t)⟩ 0 .…”

“…The phase follows the relation: ∂ t ϕ(t) = ⟨ λm (t)e −xm(t) Ĥ(t)e +xm (t)⟩ 0 . This number, ϕ(t), does not influence the calculation of observable expectation values, so it will not be considered in detail in this work (its properties are presented in [68]). These modified operators determine the TD behavior of the following kept and its left conjugate:…”

“…The inner product of these two CC wavefunctions is ⟨Υ(t)|Φ(t)⟩ = ⟨ λm (t)⟩ 0 . As shown in [68], there are four (reduced to three in this work) TD excitation vectors that are needed to compute TD observables. These are: xr (t) = ∂ R xm (t), λl (t) = ∂ L λm (t), λr (t) = ∂ R λm (t), and λl,r (t) = ∂ 2 LR λm (t).…”

Second response theory: a theoretical formalism for the propagation of quantum superpositions