# Superscript in Python plots

I want to label my x axis at follows :

pylab.xlabel('metres 10^1')


But I don't want to have the ^ symbol included .

pylab.xlabel('metres 10$^{one}$')


This method works and will superscript letters but doesn't seem to work for numbers . If I try :

pylab.xlabel('metres 10$^1$')


It superscripts a letter N for some reason .

Anyone know how to superscript numbers in python plots ? thanks .

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Try to remove the curly braces as they are superfluous when superscripting only one character. –  halex Jan 20 at 5:39
You are right , the curly braces were superfluous , but unfortunately I still end up with a letter N instead of the number 1 . –  Derek Jan 20 at 6:16
Sounds like you're missing some fonts? I guess using rc('text', usetex=True) works? –  Jakob Jan 20 at 7:03
@Jakob . Excuse my ignorance but how exactly do I implement that ? Where do I type it ? –  Derek Jan 20 at 7:08
Try from matplotlib import rc and rc('text', usetex=True) see matplotlib.org/1.3.1/users/usetex.html –  Jakob Jan 20 at 7:28

You just need to have the full expression inside the $. Basically, you need "meters$10^1$". You don't need usetex=True to do this (or most any mathematical formula). You may also want to use a raw string (e.g. r"\t", vs "\t") to avoid problems with things like \n, \a, \b, \t, \f, etc. For example: import matplotlib.pyplot as plt fig, ax = plt.subplots() ax.set(title=r'This is an expression$e^{\sin(\omega\phi)}$', xlabel='meters$10^1$', ylabel=r'Hertz$(\frac{1}{s})$') plt.show()  If you don't want the superscripted text to be in a different font than the rest of the text, use \mathregular (or equivalently \mathdefault). Some symbols won't be available, but most will. This is especially useful for simple superscripts like yours, where you want the expression to blend in with the rest of the text. import matplotlib.pyplot as plt fig, ax = plt.subplots() ax.set(title=r'This is an expression$\mathregular{e^{\sin(\omega\phi)}}$', xlabel='meters$\mathregular{10^1}$', ylabel=r'Hertz$\mathregular{(\frac{1}{s})}\$')