Sec 4.1 Notes
... Determine whether (–3, 1) is a solution of the system. x–y=–4 2x + 10y = 4 Replace x with –3 and y with 1 in both equations. First equation: –3 – 1 = – 4 True Second equation: 2(–3) + 10(1) = – 6 + 10 = 4 True Since the point (–3, 1) produces a true statement in both equations, it is a solution of t ...
... Determine whether (–3, 1) is a solution of the system. x–y=–4 2x + 10y = 4 Replace x with –3 and y with 1 in both equations. First equation: –3 – 1 = – 4 True Second equation: 2(–3) + 10(1) = – 6 + 10 = 4 True Since the point (–3, 1) produces a true statement in both equations, it is a solution of t ...
2-1 Solving One-Step Equations
... the solutions of an equation is also called solving the equation. ...
... the solutions of an equation is also called solving the equation. ...
On the adequacy of the Redfield equation and related approaches
... to a phonon bath. Their discussions are, however, applicable to nontransfer processes such as spin relaxation and vibrational relaxation problems. In the EET process, each site of a multichromophoric array is coupled to its local environmental phonons. In such systems, electronic de-excitation of a ...
... to a phonon bath. Their discussions are, however, applicable to nontransfer processes such as spin relaxation and vibrational relaxation problems. In the EET process, each site of a multichromophoric array is coupled to its local environmental phonons. In such systems, electronic de-excitation of a ...