We discuss the triangular map and also Baker's map [2], [4] with the parameter ju chosen wit... more We discuss the triangular map and also Baker's map [2], [4] with the parameter ju chosen with the value of the golden mean: (1 + V5)/2 « 1.618. For an arbitrary parameter value in the range 0 < ju < 2, the starting graph (x, /(*)) in the range 0 < x < 1 is a line segment for a triangular map, and two line segments for Baker's map (see Fig. 1 and Fig. 4). We are interested in the
We show the method for constructing nonspreading wave packets whose shape and motion can be gener... more We show the method for constructing nonspreading wave packets whose shape and motion can be general. We analyze the time evolution of nonspreading wave packets by decomposing the Hamiltonian into two parts. Of the two, one changes the instantaneous state, the other does not. Through this decomposition, the time evolution operator is shown to be effectively a spatial shifting operator. This explains why nonspreading wave packets can be nonspreading. And we show that the part of the Hamiltonian which changes the instantaneous state governs the motion of the nonspreading wave packets.
Logistic Map f(x)=μx(1-x) is Topologically Conjugate to the Map f(x)=(2-μ) x(1-x)
We prove that the well-known logistic map, f(x)=μx(1-x), is topologically conjugate to the map f(... more We prove that the well-known logistic map, f(x)=μx(1-x), is topologically conjugate to the map f(x)=(2-μ) x(1-x). The logistic map thus has the same dynamics at parameter values μ and 2-μ, and hence has the μ→2-μ symmetry in dynamics. To examine this symmetry, we study the (μ,s)n relation of f^n, which is obtained by eliminating x from the equations f^n(x)=x and s=df^n(x)/dx. We then obtain an equation directly relating μ and s for period-n point of f. We derive the (μ, s)n relation for period n=1, 2, 3, and 4, and we show that the (μ,s)n relations are invariant under the transformation of μ→2-μ.
The Effective Hamiltonian and Ehrenfest Theorem in the Propagation Dynamics of Nonspreading Wave Packets
Chinese Journal of Physics, 2014
We analyze the propagation dynamics of nonspreading wave packets by decomposing the Hamiltonian H... more We analyze the propagation dynamics of nonspreading wave packets by decomposing the Hamiltonian H into two parts: H = □(t) + H_c(t). The first part □(t) is such that Ψ(x, t) is its instantaneous eigenstate, and is therefore irrelevant to the propagation of the packet. The second part H_c(t) is shown to be the effective Hamiltonian governing the propagation dynamics of nonspreading wave packets both quantum mechanically and classically. The Ehrenfest theorem is thus based on the Hamiltonian H_c(t) connecting quantum mechanics and classical mechanics. This analysis also works for non-square-integrable packets, such as Airy packets, and explains why Airy packets can self-accelerate in free space.
The concept of photon is not necessary only applied to the relativistic Doppler theory. It may al... more The concept of photon is not necessary only applied to the relativistic Doppler theory. It may also work well for classical theory. As conservation of momentum and energy are physical laws, if applying these laws gives the exact relativistic Doppler effect, it should also give the exact classical Doppler effect. So far the classical Doppler effect is only obtained by using some approximation, as derived by Fermi in 1932. We show that the exact classical Doppler effect can be derived from the photon emission process in the exact treatment and reveal that these results are the same as those derived from the wave theory of light.
By defining F,,, maps, in which m = 2,3,4, ..., we show that these maps generate the generalized ... more By defining F,,, maps, in which m = 2,3,4, ..., we show that these maps generate the generalized F,,, Fibonacci sequences that include the customary Fibonacci sequence and its generalized sequences. All these F,,, maps and the F, Fibonacci sequences are found in the triangular map with its parameter p chosen with the specified values C,. For each m, C, has the meaning that C, is the largest parameter value among those m-cycle parameters pm for which I = 0 is a period-m point, and Cm+1 = X,, where X, is the limit ratio of the F, Fibonacci sequence.
We show a new method for analyzing the time evolution of the Schrodinger wave function Psi(x,t). ... more We show a new method for analyzing the time evolution of the Schrodinger wave function Psi(x,t). We propose the decomposition of the Hamiltonian as: H(t)=Hp(t)+Hc(t), where Hp(t) is the Hamiltonian such that Psi(x,t) is its instantaneous eigenfunction, and Hc(t) the Hamiltonian which changes the state Psi. With this decomposition, the action of H(t) on the wave function is simplified and the Schrodinger equation is in a simpler form which can be solved more easily. We illustrate this method by exactly solving the Schrodinger equation for cases of nonspreading wave packets. This method can be applied as well to analyzing the time evolution of general Hamiltonian systems.
The original model of the infinite square well contains a vague notation infinity and therefore r... more The original model of the infinite square well contains a vague notation infinity and therefore results some ambiguities. We investigate to obtain a functional form for the potential energy V(x). This is done by substituting back the original energy eigenstates and eigenvalues into the Schrodinger equation. We then obtain a precise functional form of the V(x). From this reformed model, we show that energy eigenstates and eigenvalues can directly be obtained without the need of imposing boundary condition, Ehrenfest's theorem can directly be confirmed, and ambiguities in the original model can be resolved.
Abnormal Total External Reflection for Waves Propagating from an Isotropic Medium to an Anisotropic Medium
We examine total reflection for waves propagating from an isotropic medium to an anisotropic medi... more We examine total reflection for waves propagating from an isotropic medium to an anisotropic medium. By calculating the value, ni=neff (µt), the ratio of the indices of refraction of an isotropic medium and an anisotropic medium, it is found that total reflection can occur for waves propagating from a rarer medium to a denser medium. This is contrary to the usual total internal reflection which occurs only for waves transmitting from a denser medium to a rarer medium. We refer to this phenomenon as the abnormal total external reflection.
Berry and Balazs showed that an initial Airy packet Ai(b x) under time evolution is nonspreading ... more Berry and Balazs showed that an initial Airy packet Ai(b x) under time evolution is nonspreading in free space and also in a homogeneous time-varying linear potential V(x,t)=-F(t) x. We find both results can be derived from the time evolution operator U(t). We show that U(t) can be decomposed into ordered product of operators and is essentially a shift operator in x; hence, Airy packets evolve without distortion. By writing the Hamiltonian H as H=H_b+H_i, where H_b is the Hamiltonian such that Ai(b x) is its eigenfunction. Then, H_i is shown to be as an interacting Hamiltonian that causes the Airy packet into an accelerated motion of which the acceleration a=(-H_i/( x))/m. Nonspreading Airy packet then acts as a classical particle of mass m, and the motion of it can be described classically by H_i.
We show that it needs a more delicate potential to confine particles inside a well. The original ... more We show that it needs a more delicate potential to confine particles inside a well. The original model containing a vague notation of infinity in the potential energy is ambiguous. Using the Heaviside step function and the Dirac delta-function, we give a precise form for the confining potential. Although such form appears unusual, the ambiguities are resolved. This form also shows that the infinite square well is not the limit of a finite square well.
For a quantum confinement model, the wave function of a particle is zero outside the confined reg... more For a quantum confinement model, the wave function of a particle is zero outside the confined region. Due to this, the negative energy states are, in fact, square integrable. As negative energy states are not physical, we need to impose some boundary conditions in order to avoid these states. For the case of the infinite square well model, we show the possible boundary conditions that avoid the existence of the negative energy states. The well-known boundary condition requiring the wave function be continuous on both sides of the well is one of the boundary conditions that avoids negative energy states. However, there are other types of boundary condition that can also avoid the negative energy states. This shows that there are the different branch of physical systems that can be established on the infinite square well model.
We start from the simple fact that the method of images can always be used to obtain {\Phi}_{\sig... more We start from the simple fact that the method of images can always be used to obtain {\Phi}_{\sigma} (r^\to_in), which is the potential inside conductor produced by induced surface charges. We use this fact to construct image method for outside potential {\Phi}_{\sigma} (r^\to_out). We show that if we can find a relation between {\Phi}_{\sigma} (r^\to_out) and {\Phi}_{\sigma} (r^\to_in), then the image method for {\Phi}_{\sigma} (r^\to_in) can be used to derive the image method for {\Phi}_{\sigma} (r^\toout). The number, the position and the amount of charge of the images can be directly derived. The discussion can be extended to the general n dimensions.
We discuss nonspreading wave packets in one dimensional Schr\"{o}dinger equation. We derive ... more We discuss nonspreading wave packets in one dimensional Schr\"{o}dinger equation. We derive general rules for constructing nonspreading wave packets from a general potential $\textmd{V}(x,t)$. The essential ingredients of a nonspreading wave packet, the shape function $f(x)$, the motion $d(t)$, the phase function $\phi(x,t)$ are derived. Since the form of the shape of a nonspreading wave packet does not change in time, the shape equation should be time independent. We show that the shape function $f(x)$ is the eigenfunction of the time independent Schr\"{o}dinger equation with an effective potential $V_{\textmd{eff}}$ and an energy $E_{\textmd{eff}}$. We derive nonspreading wave packets found by Schr\"{o}dinger, Senitzky, and Berry and Balazs as examples. We show that most stationary potentials can only support stationary nonspreading wave packets. We show how to construct moving nonspreading wave packets from time dependent potentials, which drive nonspreading wave p...
Ehrenfest's theorem in the infinite square well is up to now only manifested indirectly. The ... more Ehrenfest's theorem in the infinite square well is up to now only manifested indirectly. The manifestation of this theorem is first done in the finite square well, and then consider the infinite square well as the limit of the finite well. For a direct manifestation, we need a more precise formula to describe the degree of infiniteness of the divergent potential energy. We show that the potential energy term term, which is the product of the potential energy and the energy eigenfunction, is a well defined function which can be expressed in terms of Dirac delta functions. This means that the infinity in this model is not that vague but has obtained a specification. This results that expectation values can be calculated precisely and Ehrenfest's thereom can be confirmed directly.
We show a new method for analyzing the time evolution of the Schrodinger wave function phi(x,t). ... more We show a new method for analyzing the time evolution of the Schrodinger wave function phi(x,t). We propose the decomposition of the Hamiltonian as: H(t)=Hp(t)+Hc(t), where Hp(t)is the operator which does not change the state and therefore phi(x,t) is its eigenfunction, and Hc(t)is the operator that changes the state. With this decomposition, the time evolution of a wave function can be understood more clearly via the operator Hc(t). We illustrate this method by exactly solving the system of driven harmonic oscillator. We show that nonspreading wave packets exist in this system in addition to historically known paradigms. This method can be applied to analyze the time evolution of general Hamiltonian systems as well.
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Papers by Chyi-lung Lin