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file mode 100644 index 0000000..e0305f4 --- /dev/null +++ b/content/know/category/nonlinear-dynamics.md @@ -0,0 +1,9 @@ +--- +title: "Nonlinear dynamics" +firstLetter: "N" +date: 2021-02-26T20:30:17+01:00 +draft: false +layout: "category" +--- + +This page will fill itself. diff --git a/content/know/category/perturbation.md b/content/know/category/perturbation.md new file mode 100644 index 0000000..f7897b2 --- /dev/null +++ b/content/know/category/perturbation.md @@ -0,0 +1,9 @@ +--- +title: "Perturbation" +firstLetter: "P" +date: 2021-02-26T20:37:33+01:00 +draft: false +layout: "category" +--- + +This page will fill itself. diff --git a/content/know/concept/dispersive-broadening/index.pdc b/content/know/concept/dispersive-broadening/index.pdc new file mode 100644 index 0000000..7342295 --- /dev/null +++ b/content/know/concept/dispersive-broadening/index.pdc @@ -0,0 +1,93 @@ +--- +title: "Dispersive broadening" +firstLetter: "D" +publishDate: 2021-02-27 +categories: +- Physics +- Optics +- Fiber optics + +date: 2021-02-27T11:48:34+01:00 +draft: false +markup: pandoc +--- + +# Dispersive broadening + +In optical fibers, **dispersive broadening** is a (linear) effect +where group velocity dispersion (GVD) "smears out" a pulse in the time domain +due to the different group velocities of its frequencies, +since pulses always have a non-zero width in the $\omega$-domain. +No new frequencies are created. + +A pulse envelope $A(z, t)$ inside a fiber must obey the nonlinear Schrödinger equation, +where the parameters $\beta_2$ and $\gamma$ respectively +control dispersion and nonlinearity: + +$$\begin{aligned} + 0 + = i \pdv{A}{z} - \frac{\beta_2}{2} \pdv[2]{A}{t} + \gamma |A|^2 A +\end{aligned}$$ + +We set $\gamma = 0$ to ignore all nonlinear effects, +and consider a Gaussian initial condition: + +$$\begin{aligned} + A(0, t) + = \sqrt{P_0} \exp\!\Big(\!-\!\frac{t^2}{2 T_0^2}\Big) +\end{aligned}$$ + +By [Fourier transforming](/know/concept/fourier-transform/) in $t$, +the full analytical solution $A(z, t)$ is found to be as follows, +where it can be seen that the amplitude +decreases and the width increases with $z$: + +$$\begin{aligned} + A(z,t) = \sqrt{\frac{P_0}{1 - i \beta_2 z / T_0^2}} + \exp\!\bigg(\! -\!\frac{t^2 / (2 T_0^2)}{1 + \beta_2^2 z^2 / T_0^4} \big( 1 + i \beta_2 z / T_0^2 \big) \bigg) +\end{aligned}$$ + +To quantify the strength of dispersive effects, +we define the dispersion length $L_D$ +as the distance over which the half-width at $1/e$ of maximum power +(initially $T_0$) increases by a factor of $\sqrt{2}$: + +$$\begin{aligned} + T_0 \sqrt{1 + \beta_2^2 L_D^2 / T_0^4} = T_0 \sqrt{2} + \qquad \implies \qquad + \boxed{ + L_D = \frac{T_0^2}{|\beta_2|} + } +\end{aligned}$$ + +This phenomenon is illustrated below for our example of a Gaussian pulse +with parameter values $T_0 = 1\:\mathrm{ps}$, $P_0 = 1\:\mathrm{kW}$, +$\beta_2 = -10 \:\mathrm{ps}^2/\mathrm{m}$ and $\gamma = 0$: + + + +The **instantaneous frequency** $\omega_\mathrm{GVD}(z, t)$, +which describes the dominant angular frequency at a given point in the time domain, +is found to be as follows for the Gaussian pulse, +where $\phi(z, t)$ is the phase of $A(z, t) = \sqrt{P(z, t)} \exp(i \phi(z, t))$: + +$$\begin{aligned} + \omega_{\mathrm{GVD}}(z,t) + = \pdv{t} \Big( \frac{\beta_2 z t^2 / (2 T_0^4)}{1 + \beta_2^2 z^2 / T_0^4} \Big) + = \frac{\beta_2 z / T_0^2}{1 + \beta_2^2 z^2 / T_0^4} \frac{t}{T_0^2} +\end{aligned}$$ + +This expression is linear in time, and depending on the sign of $\beta_2$, +frequencies on one side of the pulse arrive first, +and those on the other side arrive last. +The effect is stronger for smaller $T_0$: +this makes sense, since short pulses are spectrally wider. + +The interaction between dispersion and [self-phase modulation](/know/concept/self-phase-modulation/) +leads to many interesting effects, +such as [modulational instability](/know/concept/modulational-instability/) +and [optical wave breaking](/know/concept/optical-wave-breaking/). +Of great importance is the sign of $\beta_2$: +in the **anomalous dispersion regime** ($\beta_2 < 0$), +lower frequencies travel more slowly than higher ones, +and vice versa in the **normal dispersion regime** ($\beta_2 > 0$). diff --git a/content/know/concept/dispersive-broadening/pheno-disp.jpg b/content/know/concept/dispersive-broadening/pheno-disp.jpg new file mode 100644 index 0000000..a97312b Binary files /dev/null and b/content/know/concept/dispersive-broadening/pheno-disp.jpg differ diff --git a/content/know/concept/fourier-transform/index.pdc b/content/know/concept/fourier-transform/index.pdc index 6d8901a..96653f5 100644 --- a/content/know/concept/fourier-transform/index.pdc +++ b/content/know/concept/fourier-transform/index.pdc @@ -5,6 +5,7 @@ publishDate: 2021-02-22 categories: - Mathematics - Physics +- Optics date: 2021-02-22T21:35:54+01:00 draft: false diff --git a/content/know/concept/modulational-instability/index.pdc b/content/know/concept/modulational-instability/index.pdc new file mode 100644 index 0000000..d912c04 --- /dev/null +++ b/content/know/concept/modulational-instability/index.pdc @@ -0,0 +1,197 @@ +--- +title: "Modulational instability" +firstLetter: "M" +publishDate: 2021-02-26 +categories: +- Physics +- Fiber optics +- Optics +- Perturbation +- Nonlinear dynamics + +date: 2021-02-26T20:36:22+01:00 +draft: false +markup: pandoc +--- + +# Modulational instability + +In fiber optics, **modulational instability** (MI) +is a nonlinear effect that leads to the exponential amplification +of background noise in certain frequency regions. +It only occurs in the [anomalous dispersion regime](/know/concept/dispersive-broadening/) +($\beta_2 < 0$), which we will prove shortly. + +Consider the following simple solution to the nonlinear Schrödinger equation: +a time-invariant constant power $P_0$ at the carrier frequency $\omega_0$, +which is experiencing [self-phase modulation](/know/concept/self-phase-modulation/): + +$$\begin{aligned} + A(z,t) = \sqrt{P_0} \exp( i \gamma P_0 z) +\end{aligned}$$ + +We add a small perturbation $\varepsilon(z,t)$ to this signal, +representing background noise: + +$$\begin{aligned} + A(z,t) = \big(\sqrt{P_0} + \varepsilon(z,t)\big) \exp( i \gamma P_0 z) +\end{aligned}$$ + +We insert this into the nonlinear Schrödinger equation to get a perturbation equation, +which we linearize by assuming that $|\varepsilon|^2$ is negligible compared to $P_0$, +such that all higher-order terms of $\varepsilon$ can be dropped, yielding: + +$$\begin{aligned} + 0 + &= - P_0 \sqrt{P_0} \gamma - P_0 \gamma \varepsilon + i \pdv{\varepsilon}{z} + - \frac{\beta_2}{2} \pdv[2]{\varepsilon}{t} + + \gamma \big(\sqrt{P_0} + \varepsilon\big)^2 \big(\sqrt{P_0} + \varepsilon\big)^* + \\ + &= i \pdv{\varepsilon}{z} + - \frac{\beta_2}{2} \pdv[2]{\varepsilon}{t} + + \gamma \big( P_0 (\varepsilon + \varepsilon^*) + \sqrt{P_0} |\varepsilon|^2 + + \sqrt{P_0} \varepsilon (\varepsilon + \varepsilon^*) + \varepsilon |\varepsilon|^2 \big) + \\ + &= i \pdv{\varepsilon}{z} - \frac{\beta_2}{2} \pdv[2]{\varepsilon}{t} + \gamma P_0 (\varepsilon + \varepsilon^*) +\end{aligned}$$ + +We split the perturbation into real and imaginary parts +$\varepsilon(z,t) = \varepsilon_r(z,t) + i \varepsilon_i(z,t)$, +which we fill in in this equation. +The point is that $\varepsilon_r$ and $\varepsilon_i$ are real functions: + +$$\begin{aligned} + 0 + &= i \pdv{\varepsilon_r}{z} - \pdv{\varepsilon_i}{z} + - \frac{\beta_2}{2} \pdv[2]{\varepsilon_r}{t} - i \frac{\beta_2}{2} \pdv[2]{\varepsilon_i}{t} + + 2 \gamma P_0 \varepsilon_r +\end{aligned}$$ + +Splitting this into its real and imaginary parts gives two PDEs +relating $\varepsilon_r$ and $\varepsilon_i$: + +$$\begin{aligned} + \pdv{\varepsilon_r}{z} = \frac{\beta_2}{2} \pdv[2]{\varepsilon_i}{t} + \qquad \quad + \pdv{\varepsilon_i}{z} = - \frac{\beta_2}{2} \pdv[2]{\varepsilon_r}{t} + 2 \gamma P_0 \varepsilon_r +\end{aligned}$$ + +We [Fourier transform](/know/concept/fourier-transform/) +these in $t$ to turn them into ODEs relating +$\tilde{\varepsilon}_r(z,\omega)$ and $\tilde{\varepsilon}_i(z,\omega)$: + +$$\begin{aligned} + \pdv{\tilde{\varepsilon}_r}{z} = - \frac{\beta_2}{2} \omega^2 \tilde{\varepsilon}_i + \qquad \quad + \pdv{\tilde{\varepsilon}_i}{z} = \Big(\frac{\beta_2}{2} \omega^2 + 2 \gamma P_0 \Big) \tilde{\varepsilon}_r +\end{aligned}$$ + +We are interested in exponential growth, so let us make the following ansatz, +where $k$ may be a function of $\omega$, as long as it is $z$-invariant: + +$$\begin{aligned} + \tilde{\varepsilon}_r(z, \omega) = \tilde{\varepsilon}_r(0, \omega) \exp(k z) + \qquad \quad + \tilde{\varepsilon}_i(z, \omega) = \tilde{\varepsilon}_i(0, \omega) \exp(k z) +\end{aligned}$$ + +With this, we can write the system of ODEs for +$\tilde{\varepsilon}_r(z,\omega)$ and $\tilde{\varepsilon}_i(z,\omega)$ +in matrix form: + +$$\begin{aligned} + \begin{bmatrix} + k & \beta_2 \omega^2 / 2 \\ + \beta_2 \omega^2 / 2 \!+\! 2 \gamma P_0 & - k + \end{bmatrix} + \cdot + \begin{bmatrix} \tilde{\varepsilon}_r(0, \omega) \\ \tilde{\varepsilon}_i(0, \omega) \end{bmatrix} + = + \begin{bmatrix} 0 \\ 0 \end{bmatrix} +\end{aligned}$$ + +This has non-zero solutions if the system matrix' determinant is zero, +which is true when: + +$$\begin{aligned} + k = \pm \sqrt{ - \frac{\beta_2}{2} \omega^2 \Big( \frac{\beta_2}{2} \omega^2 + 2 \gamma P_0 \Big) } +\end{aligned}$$ + +To get exponential growth, it is essential that $\mathrm{Re}\{k\} > 0$, +so we discard the negative sign, +and get the following condition for MI: + +$$\begin{aligned} + - \frac{\beta_2}{2} \omega^2 \Big( \frac{\beta_2}{2} \omega^2 + 2 \gamma P_0 \Big) > 0 + \quad \implies \quad + \boxed{ + \omega^2 < -\frac{4 \gamma P_0}{\beta_2} + } +\end{aligned}$$ + +Since $\omega^2$ is positive, $\beta_2$ must be negative, +so MI can only occur in the ADR. +It is worth noting that $\beta_2 = \beta_2(\omega_0)$, +meaning there can only be exponential +noise growth when the "parent pulse" is in the anomalous dispersion regime, +but that growth may appear in areas of normal dispersion, +as long as the above condition is satisfied by the parent. + +This result has been derived using perturbation, +so only holds as long as $|\varepsilon|^2 \ll P_0$. +Over time, the noise gets amplified so greatly +that this approximation breaks down. + +Next, we define the **gain** $g(\omega)$, +which expresses how quickly the +perturbation grows as a function of the frequency offset $\omega$: + +$$\begin{aligned} + \boxed{ + g(\omega) + = \mathrm{Re}\{k\} + = \mathrm{Re} \bigg\{ \sqrt{ - \frac{\beta_2}{2} \omega^2 \Big( \frac{\beta_2}{2} \omega^2 + 2 \gamma P_0 \Big) } \bigg\} + } +\end{aligned}$$ + +The frequencies with maximum gain are then found as extrema of $g(\omega)$, +which satisfy: + +$$\begin{aligned} + g'(\omega_\mathrm{max}) = 0 + \qquad \implies \qquad + \boxed{ + \omega_\mathrm{max} = \pm \sqrt{\frac{2 \gamma P_0}{-\beta_2}} + } +\end{aligned}$$ + +A simulation of MI is illustrated below. +The pulse considered was a solition of the following form +with settings $T_0 = 10\:\mathrm{ps}$, $P_0 = 10\:\mathrm{kW}$, +$\beta = -10\:\mathrm{ps}^2/\mathrm{m}$ and $\gamma = 0.1/\mathrm{W}/\mathrm{m}$, +whose peak is approximately flat, so our derivation is valid there, +hence it "wrinkles" in the $t$-domain: + +$$\begin{aligned} + A(0, t) + = \sqrt{P_0} \sech\!\Big(\frac{t}{T_0}\Big) +\end{aligned}$$ + + + +Where $L_\mathrm{NL} = 1/(\gamma P_0)$ is the characteristic length of nonlinear effects. +Note that no noise was added to the simulation; +what you are seeing are pure numerical errors getting amplified. + +If one of the gain peaks accumulates a lot of energy quickly ($L_\mathrm{NL}$ is small), +and that peak is in the anomalous dispersion regime, +then it can in turn also cause MI in its own surroundings, +leading to a cascade of secondary and tertiary gain areas. +This is seen above for $z > 30 L_\mathrm{NL}$. + +What we described is "pure" MI, but there also exists +a different type caused by Raman scattering. +In that case, amplification occurs at the strongest peak of the Raman gain $\tilde{g}_R(\omega)$, +even when the parent pulse is in the NDR. +This is an example of stimulated Raman scattering (SRS). + diff --git a/content/know/concept/modulational-instability/pheno-mi.jpg b/content/know/concept/modulational-instability/pheno-mi.jpg new file mode 100644 index 0000000..e45f074 Binary files /dev/null and b/content/know/concept/modulational-instability/pheno-mi.jpg differ diff --git a/content/know/concept/optical-wave-breaking/index.pdc b/content/know/concept/optical-wave-breaking/index.pdc new file mode 100644 index 0000000..3c509fe --- /dev/null +++ b/content/know/concept/optical-wave-breaking/index.pdc @@ -0,0 +1,229 @@ +--- +title: "Optical wave breaking" +firstLetter: "O" +publishDate: 2021-02-27 +categories: +- Physics +- Optics +- Fiber optics +- Nonlinear dynamics + +date: 2021-02-27T10:09:46+01:00 +draft: false +markup: pandoc +--- + +# Optical wave breaking + +In fiber optics, **optical wave breaking** (OWB) is a nonlinear effect +caused by interaction between +[group velocity dispersion](/know/concept/dispersive-broadening/) (GVD) and +[self-phase modulation](/know/concept/self-phase-modulation/) (SPM). +It only happens in the normal dispersion regime ($\beta_2 > 0$) +for pulses meeting a certain criterium, as we will see. + +SPM creates low frequencies at the front of the pulse, and high ones at the back, +and if $\beta_2 > 0$, GVD lets low frequencies travel faster than high ones. +When those effects interact, the pulse gets temporally stretched +in a surprisingly sophisticated way. + +To illustrate this, the instantaneous frequency $\omega_i(z, t) = -\pdv*{\phi}{t}$ +has been plotted below for a theoretical Gaussian input pulse experiencing OWB, +with settings $T_0 = 100\:\mathrm{fs}$, $P_0 = 5\:\mathrm{kW}$, +$\beta_2 = 2\:\mathrm{ps}^2/\mathrm{m}$ and $\gamma = 0.1/\mathrm{W}/\mathrm{m}$. + +In the left panel, we see the typical S-shape caused by SPM, +and the arrows indicate the direction that GVD is pushing the curve in. +This leads to steepening at the edges, i.e. the S gradually turns into a Z. +Shortly before the slope would become infinite, +small waves start "falling off" the edge of the pulse, +hence the name *wave breaking*: + + + +Several interesting things happen around this moment. +To demonstrate this, spectrograms of the same simulation +have been plotted below, together with pulse profiles +in both the $t$-domain and $\omega$-domain on an arbitrary linear scale +(click the image to get a better look). + +Initially, the spectrum broadens due to SPM in the usual way, +but shortly after OWB, this process is stopped by the appearance +of so-called **sidelobes** in the $\omega$-domain on either side of the pulse. +In the meantime, in the time domain, +the pulse steepens at the edges, but flattens at the peak. +After OWB, a train of small waves falls off the edges, +which eventually melt together, leading to a trapezoid shape in the $t$-domain. +Dispersive broadening then continues normally: + + + + + +We call the distance at which the wave breaks $L_\mathrm{WB}$, +and would like to analytically predict it. +We do this using the instantaneous frequency $\omega_i$, +by estimating when the SPM fluctuations overtake their own base, +as was illustrated earlier. + +To get $\omega_i$ of a Gaussian pulse experiencing both GVD and SPM, +it is a reasonable approximation, for small $z$, to simply add up +the instantaneous frequencies for these separate effects: + +$$\begin{aligned} + \omega_i(z,t) + &\approx \omega_\mathrm{GVD}(z,t) + \omega_\mathrm{SPM}(z,t) + \\ +% &= \frac{\beta_2 z / T_0^2}{1 + \beta_2^2 z^2 / T_0^4} \frac{t}{T_0^2} +% + \frac{2\gamma P_0 z}{T_0^2} t \exp\!\Big(\!-\frac{t^2}{T_0^2}\Big) +% \\ + &= \frac{tz}{T_0^2} \bigg( \frac{\beta_2 / T_0^2}{1 + \beta_2^2 z^2 / T_0^4} + + 2\gamma P_0 \exp\!\Big(\!-\!\frac{t^2}{T_0^2}\Big) \bigg) +\end{aligned}$$ + +Assuming that $z$ is small enough such that $z^2 \approx 0$, this +expression can be reduced to: + +$$\begin{aligned} + \omega_i(z,t) + \approx \frac{\beta_2 tz}{T_0^4} \bigg( 1 + 2\frac{\gamma P_0 T_0^2}{\beta_2} \exp\!\Big(\!-\!\frac{t^2}{T_0^2}\Big) \bigg) + = \frac{\beta_2 t z}{T_0^4} \bigg( 1 \pm 2 N_\mathrm{sol}^2 \exp\!\Big(\!-\!\frac{t^2}{T_0^2}\Big) \bigg) +\end{aligned}$$ + +Where we have assumed $\beta_2 > 0$, +and $N_\mathrm{sol}$ is the **soliton number**, +which is defined as: + +$$\begin{aligned} + N_\mathrm{sol}^2 = \frac{L_D}{L_N} = \frac{\gamma P_0 T_0^2}{|\beta_2|} +\end{aligned}$$ + +This quantity is very important in anomalous dispersion, +but even in normal dispesion, it is still a useful measure of the relative strengths of GVD and SPM. +As was illustrated earlier, $\omega_i$ overtakes itself at the edges, +so OWB only occurs when $\omega_i$ is not monotonic, +which is when its $t$-derivative, +the **instantaneous chirpyness** $\xi_i$, +has *two* real roots for $t^2$: + +$$\begin{aligned} + 0 + = \xi_i(z,t) + = \pdv{\omega_i}{t} + &= \frac{\beta_2 z}{T_0^4} \bigg( 1 + 2 N_\mathrm{sol}^2 \Big( 1 - \frac{2 t^2}{T_0^2} \Big) \exp\!\Big(\!-\!\frac{t^2}{T_0^2}\Big) \bigg) + = \frac{\beta_2 z}{T_0^4} \: f\Big(\frac{t^2}{T_0^2}\Big) +\end{aligned}$$ + +Where the function $f(x)$ has been defined for convenience. As it turns +out, this equation can be solved analytically using the Lambert $W$ function, +leading to the following exact minimum value $N_\mathrm{min}^2$ for $N_\mathrm{sol}^2$, +such that OWB can only occur when $N_\mathrm{sol}^2 > N_\mathrm{min}^2$: + +$$\begin{aligned} + N_\mathrm{min}^2 = \frac{1}{4} \exp\!\Big(\frac{3}{2}\Big) \approx 1.12 +\end{aligned}$$ + +Now, consider two times $t_1$ and $t_2$ in the pulse, separated by +a small initial interval $(t_2 - t_1)$. +The frequency difference between these points due to $\omega_i$ +will cause them to displace relative to each other +after a short distance $z$ by some amount $\Delta t$, +estimated by: + +$$\begin{aligned} + \Delta t + &\approx z \Delta\beta_1 + \qquad + &&\Delta\beta_1 = \beta_1(\omega_i(z,t_2)) - \beta_1(\omega_i(z,t_1)) + \\ + &\approx z \beta_2 \Delta\omega_i + \qquad + &&\Delta\omega_i = \omega_i(z,t_2) - \omega_i(z,t_1) + \\ + &\approx z \beta_2 \Delta\xi_i \,(t_2 - t_1) + \qquad \quad + &&\Delta\xi_i = \xi_i(z,t_2) - \xi_i(z,t_1) +\end{aligned}$$ + +Where $\beta_1(\omega)$ is the inverse of the group velocity. +OWB takes place when $t_2$ and $t_1$ catch up to each other, +which is when $-\Delta t = (t_2 - t_1)$. +The distance where this happens, $z = L_\mathrm{WB}$, +must therefore satisfy the following condition +for a particular value of $t$: + +$$\begin{aligned} + L_\mathrm{WB} \, \beta_2 \, \xi_i(L_\mathrm{WB}, t) = -1 + \qquad \implies \qquad + L_\mathrm{WB}^2 = - \frac{T_0^4}{\beta_2^2 \, f(t^2/T_0^2)} +\end{aligned}$$ + +The time $t$ of OWB must be where $\omega_i(t)$ has its steepest slope, +which is at the minimum value of $\xi_i(t)$, and, by extension $f(x)$. +This turns out to be $f(3/2)$: + +$$\begin{aligned} + f_\mathrm{min} = f(3/2) + = 1 - 4 N_\mathrm{sol}^2 \exp(-3/2) + = 1 - N_\mathrm{sol}^2 / N_\mathrm{min}^2 +\end{aligned}$$ + +Clearly, $f_\mathrm{min} \ge 0$ when +$N_\mathrm{sol}^2 \le N_\mathrm{min}^2$, which, when inserted in the +condition above, confirms that OWB cannot occur in that case. Otherwise, +if $N_\mathrm{sol}^2 > N_\mathrm{min}^2$, then: + +$$\begin{aligned} + L_\mathrm{WB} + = - \frac{T_0^2}{\beta_2 \, \sqrt{f_\mathrm{min}}} + = \frac{L_D}{\sqrt{N_\mathrm{sol}^2 / N_\mathrm{min}^2 - 1}} + = \frac{L_D}{\sqrt{4 N_\mathrm{sol}^2 \exp(-3/2) - 1}} +\end{aligned}$$ + +This prediction for $L_\mathrm{WB}$ appears to agree well +with the OWB observed in the simulation: + + + +Because all spectral broadening up to $L_\mathrm{WB}$ is caused by SPM, +whose frequency behaviour is known, it is in fact possible to draw +some analytical conclusions about the achieved bandwidth when OWB sets in. +Filling $L_\mathrm{WB}$ in into $\omega_\mathrm{SPM}$ gives: + +$$\begin{aligned} + \omega_{\mathrm{SPM}}(L_\mathrm{WB},t) + = \frac{2 \gamma P_0 t}{\beta_2 \sqrt{4 N_\mathrm{sol}^2 \exp(-3/2) - 1}} \exp\!\Big(\!-\frac{t^2}{T_0^2}\Big) +\end{aligned}$$ + +Assuming that $N_\mathrm{sol}^2$ is large in the denominator, this can +be approximately reduced to: + +$$\begin{aligned} + \omega_\mathrm{SPM}(L_\mathrm{WB}, t) +% = \frac{2 \gamma P_0 t \exp(-t^2 / T_0^2)}{\beta_2 \sqrt{N_\mathrm{sol}^2 / N_\mathrm{min}^2 - 1}} + \approx \frac{2 \gamma P_0 t}{\beta_2 N_\mathrm{sol}} \exp\!\Big(\!-\frac{t^2}{T_0^2}\Big) + = 2 \sqrt{\frac{\gamma P_0}{\beta_2}} \frac{t}{T_0} \exp\!\Big(\!-\frac{t^2}{T_0^2}\Big) +\end{aligned}$$ + +The expression $x \exp(-x^2)$ has its global extrema +$\pm 1 / \sqrt{2 e}$ at $x^2 = 1/2$. The maximum SPM frequency shift +achieved at $L_\mathrm{WB}$ is therefore given by: + +$$\begin{aligned} + \omega_\mathrm{max} = \sqrt{\frac{2 \gamma P_0}{e \beta_2}} +\end{aligned}$$ + +Interestingly, this expression does not contain $T_0$ at all, +so the achieved spectrum when SPM is halted by OWB +is independent of the pulse width, +for sufficiently large $N_\mathrm{sol}$. + + +## References +1. D. Anderson, M. Desaix, M. Lisak, M.L. Quiroga-Teixeiro, + [Wave breaking in nonlinear-optical fibers](https://doi.org/10.1364/JOSAB.9.001358), + 1992, Optical Society of America. +2. A.M. Heidt, A. Hartung, H. Bartelt, + [Generation of ultrashort and coherent supercontinuum light pulses in all-normal dispersion fibers](https://doi.org/10.1007/978-1-4939-3326-6_6), + 2016, Springer Media. + diff --git a/content/know/concept/optical-wave-breaking/pheno-break-inst.jpg b/content/know/concept/optical-wave-breaking/pheno-break-inst.jpg new file mode 100644 index 0000000..de92efd Binary files /dev/null and b/content/know/concept/optical-wave-breaking/pheno-break-inst.jpg differ diff --git a/content/know/concept/optical-wave-breaking/pheno-break-sgram.jpg b/content/know/concept/optical-wave-breaking/pheno-break-sgram.jpg new file mode 100644 index 0000000..340343a Binary files /dev/null and b/content/know/concept/optical-wave-breaking/pheno-break-sgram.jpg differ diff --git a/content/know/concept/optical-wave-breaking/pheno-break.jpg b/content/know/concept/optical-wave-breaking/pheno-break.jpg new file mode 100644 index 0000000..5b08714 Binary files /dev/null and b/content/know/concept/optical-wave-breaking/pheno-break.jpg differ diff --git a/content/know/concept/self-phase-modulation/index.pdc b/content/know/concept/self-phase-modulation/index.pdc new file mode 100644 index 0000000..868fd68 --- /dev/null +++ b/content/know/concept/self-phase-modulation/index.pdc @@ -0,0 +1,95 @@ +--- +title: "Self-phase modulation" +firstLetter: "S" +publishDate: 2021-02-26 +categories: +- Physics +- Optics +- Fiber optics +- Nonlinear dynamics + +date: 2021-02-27T10:09:32+01:00 +draft: false +markup: pandoc +--- + +# Self-phase modulation + +In fiber optics, **self-phase modulation** (SPM) is a nonlinear effect +that gradually broadens pulses' spectra. +Unlike dispersion, SPM does create new frequencies: in the $\omega$-domain, +the pulse steadily spreads out with a distinctive "accordion" peak. +Lower frequencies are created at the front of the +pulse and higher ones at the back, giving S-shaped spectrograms. + +A pulse envelope $A(z, t)$ inside a fiber must obey the nonlinear Schrödinger equation, +where the parameters $\beta_2$ and $\gamma$ respectively +control dispersion and nonlinearity: + +$$\begin{aligned} + 0 + = i \pdv{A}{z} - \frac{\beta_2}{2} \pdv[2]{A}{t} + \gamma |A|^2 A +\end{aligned}$$ + +By setting $\beta_2 = 0$ to neglect dispersion, +solving this equation becomes trivial. +For any arbitrary input pulse $A_0(t) = A(0, t)$, +we arrive at the following analytical solution: + +$$\begin{aligned} + A(z,t) = A_0 \exp\!\big( i \gamma |A_0|^2 z\big) +\end{aligned}$$ + +The intensity $|A|^2$ in the time domain is thus unchanged, +and only its phase is modified. +It is also clear that the largest phase increase occurs at the peak of the pulse, +where the intensity is $P_0$. +To quantify this, it is useful to define the **nonlinear length** $L_N$, +which gives the distance after which the phase of the +peak has increased by exactly 1 radian: + +$$\begin{aligned} + \gamma P_0 L_N = 1 + \qquad \implies \qquad + \boxed{ + L_N = \frac{1}{\gamma P_0} + } +\end{aligned}$$ + +SPM is illustrated below for the following Gaussian initial pulse envelope, +with parameter values $T_0 = 6\:\mathrm{ps}$, $P_0 = 1\:\mathrm{kW}$, +$\beta_2 = 0$, and $\gamma = 0.1/\mathrm{W}/\mathrm{m}$: + +$$\begin{aligned} + A(0, t) + = \sqrt{P_0} \exp\!\Big(\!-\!\frac{t^2}{2 T_0^2}\Big) +\end{aligned}$$ + +From earlier, we then know the analytical solution for the $z$-evolution: + +$$\begin{aligned} + A(z, t) = \sqrt{P_0} \exp\!\Big(\!-\!\frac{t^2}{2 T_0^2}\Big) \exp\!\bigg( i \gamma z P_0 \exp\!\Big(\!-\!\frac{t^2}{T_0^2}\Big) \bigg) +\end{aligned}$$ + + + +The **instantaneous frequency** $\omega_\mathrm{SPM}(z, t)$, +which describes the dominant angular frequency at a given point in the time domain, +is found to be as follows for the Gaussian pulse, +where $\phi(z, t)$ is the phase of $A(z, t) = \sqrt{P(z, t)} \exp(i \phi(z, t))$: + +$$\begin{aligned} + \omega_{\mathrm{SPM}}(z,t) + = - \pdv{\phi}{t} + = 2 \gamma z P_0 \frac{t}{T_0^2} \exp\!\Big(\!-\!\frac{t^2}{T_0^2}\Big) +\end{aligned}$$ + +This result gives the S-shaped spectrograms seen in the illustration. +The frequency shift thus not only depends on $L_N$, +but also on $T_0$: the spectra of narrow pulses broaden much faster. + +The interaction between self-phase modulation +and [dispersion](/know/concept/dispersive-broadening/) +leads to many interesting effects, +such as [modulational instability](/know/concept/modulational-instability/) +and [optical wave breaking](/know/concept/optical-wave-breaking/). diff --git a/content/know/concept/self-phase-modulation/pheno-spm.jpg b/content/know/concept/self-phase-modulation/pheno-spm.jpg new file mode 100644 index 0000000..6d5c92a Binary files /dev/null and b/content/know/concept/self-phase-modulation/pheno-spm.jpg differ diff --git a/content/know/concept/self-steepening/index.pdc b/content/know/concept/self-steepening/index.pdc new file mode 100644 index 0000000..efbdfe4 --- /dev/null +++ b/content/know/concept/self-steepening/index.pdc @@ -0,0 +1,144 @@ +--- +title: "Self-steepening" +firstLetter: "S" +publishDate: 2021-02-26 +categories: +- Physics +- Optics +- Fiber optics +- Nonlinear dynamics + +date: 2021-02-26T15:18:25+01:00 +draft: false +markup: pandoc +--- + +# Self-steepening + +For a laser pulse travelling through an optical fiber, +its intensity is highest at its peak, so the Kerr effect will be strongest there. +This means that the peak travels slightly slower +than the rest of the pulse, leading to **self-steepening** of its trailing edge. +Mathematically, this is described by adding a new term to the +nonlinear Schrödinger equation: + +$$\begin{aligned} + 0 + = i\pdv{A}{z} - \frac{\beta_2}{2} \pdv[2]{A}{t} + \gamma \Big(1 + \frac{i}{\omega_0} \pdv{t}\Big) \big(|A|^2 A\big) +\end{aligned}$$ + +Where $\omega_0$ is the angular frequency of the pump. +We will use the following ansatz, +consisting of an arbitrary power profile $P$ with a phase $\phi$: + +$$\begin{aligned} + A(z,t) = \sqrt{P(z,t)} \, \exp\big(i \phi(z,t)\big) +\end{aligned}$$ + +For a long pulse travelling over a short distance, it is reasonable to +neglect dispersion ($\beta_2 = 0$). +Inserting the ansatz then gives the following, where $\varepsilon = \gamma / \omega_0$: + +$$\begin{aligned} + 0 &= i \frac{1}{2} \frac{P_z}{\sqrt{P}} - \sqrt{P} \phi_z + \gamma P \sqrt{P} + i \varepsilon \frac{3}{2} P_t \sqrt{P} - \varepsilon P \sqrt{P} \phi_t +\end{aligned}$$ + +This results in two equations, respectively corresponding to the real +and imaginary parts: + +$$\begin{aligned} + 0 &= - \phi_z - \varepsilon P \phi_t + \gamma P + \\ + 0 &= P_z + \varepsilon 3 P_t P +\end{aligned}$$ + +The phase $\phi$ is not so interesting, so we focus on the latter equation for $P$. +As it turns out, it has a general solution of the form below, which shows that +more intense parts of the pulse will tend to lag behind compared to the rest: + +$$\begin{aligned} + P(z,t) = f(t - 3 \varepsilon z P) +\end{aligned}$$ + +Where $f$ is the initial power profile: $f(t) = P(0,t)$. +The derivatives $P_t$ and $P_z$ are then given by: + +$$\begin{aligned} + P_t + &= (1 - 3 \varepsilon z P_t) \: f' + \qquad \quad \implies \quad + P_t + = \frac{f'}{1 + 3 \varepsilon z f'} + \\ + P_z + &= (-3 \varepsilon P - 3 \varepsilon z P_z) \: f' + \quad \implies \quad + P_z + = \frac{- 3 \varepsilon P f'}{1 + 3 \varepsilon z f'} +\end{aligned}$$ + +These derivatives both go to infinity when their denominator is zero, +which, since $\varepsilon$ is positive, will happen earliest where $f'$ +has its most negative value, called $f_\mathrm{min}'$, +which is located on the trailing edge of the pulse. +At the propagation distance where this occurs, $L_\mathrm{shock}$, +the pulse will "tip over", creating a discontinuous shock: + +$$\begin{aligned} + \boxed{ + L_\mathrm{shock} = -\frac{1}{3 \varepsilon f_\mathrm{min}'} + } +\end{aligned}$$ + +In practice, however, this will never actually happen, because by the time +$L_\mathrm{shock}$ is reached, the pulse spectrum will have become so +broad that dispersion can no longer be neglected. + +A simulation of self-steepening without dispersion is illustrated below +for the following Gaussian initial power distribution, +with $T_0 = 25\:\mathrm{fs}$, $P_0 = 3\:\mathrm{kW}$, +$\beta_2 = 0$ and $\gamma = 0.1/\mathrm{W}/\mathrm{m}$: + +$$\begin{aligned} + f(t) = P(0,t) = P_0 \exp\!\Big(\! -\!\frac{t^2}{T_0^2} \Big) +\end{aligned}$$ + + +Its steepest points are found to be at $2 t^2 = T_0^2$, so +$f_\mathrm{min}'$ and $L_\mathrm{shock}$ are given by: + +$$\begin{aligned} + f_\mathrm{min}' = - \frac{\sqrt{2} P_0}{T_0} \exp\!\Big(\!-\!\frac{1}{2}\Big) + \quad \implies \quad + L_\mathrm{shock} = \frac{T_0}{3 \sqrt{2} \varepsilon P_0} \exp\!\Big(\frac{1}{2}\Big) +\end{aligned}$$ + +This example Gaussian pulse therefore has a theoretical +$L_\mathrm{shock} = 0.847\,\mathrm{m}$, +which turns out to be accurate, +although the simulation breaks down due to insufficient resolution: + + + +Unfortunately, self-steepening cannot be simulated perfectly: as the +pulse approaches $L_\mathrm{shock}$, its spectrum broadens to infinite +frequencies to represent the singularity in its slope. +The simulation thus collapses into chaos when the edge of the frequency window is reached. +Nevertheless, the general trends are nicely visible: +the trailing slope becomes extremely steep, and the spectrum +broadens so much that dispersion cannot be neglected anymore. + +When self-steepening is added to the nonlinear Schrödinger equation, +it no longer conserves the total pulse energy $\int |A|^2 \dd{t}$. +Fortunately, the photon number $N_\mathrm{ph}$ is still +conserved, which for the physical envelope $A(z,t)$ is defined as: + +$$\begin{aligned} + \boxed{ + N_\mathrm{ph}(z) = \int_0^\infty \frac{|\tilde{A}(z,\omega)|^2}{\omega} \dd{\omega} + } +\end{aligned}$$ + + +## References +1. B.R. Suydam, [Self-steepening of optical pulses](https://doi.org/10.1007/0-387-25097-2_6), 2006, Springer Media. diff --git a/content/know/concept/self-steepening/pheno-steep.jpg b/content/know/concept/self-steepening/pheno-steep.jpg new file mode 100644 index 0000000..c369d62 Binary files /dev/null and b/content/know/concept/self-steepening/pheno-steep.jpg differ diff --git a/content/know/concept/time-independent-perturbation-theory/index.pdc b/content/know/concept/time-independent-perturbation-theory/index.pdc index 4f30ae8..2035fc2 100644 --- a/content/know/concept/time-independent-perturbation-theory/index.pdc +++ b/content/know/concept/time-independent-perturbation-theory/index.pdc @@ -4,6 +4,7 @@ firstLetter: "T" publishDate: 2021-02-22 categories: - Quantum mechanics +- Perturbation - Physics date: 2021-02-22T21:38:18+01:00 -- cgit v1.2.3