An LED typically has a voltage/current relationship like this:
A resistor's voltage/current relationship is a straight line, passing through the origin, with the slope defined by the resistance (from Ohm's law: \$ I = \frac{E}{R} \$).
The LED's curve is not unlike a straight line, once you get above 1.8V or so. So, at least for the LED's operating region between "current starting to flow" and "overheating", an LED is not unlike a resistor, with the voltage pushed to the right.
What's the value of this imagined resistor? Well, in this graph it looks like the curve goes through \$(2V, 5mA)\$ and \$(2.2V, 20mA)\$. If you rearrange Ohm's law, you can see that an Ohm is a volt-per-amp:
\$ R = \dfrac{E}{I} \$
We will deal with shifting this curve to the right later, so for now we can consider only the change in voltage and current between the two points we picked:
\$ R = \dfrac{\Delta E}{\Delta I} \$
\$ R = \dfrac{2.2V - 2V}{20mA - 5mA} \$
\$ R = \dfrac{0.2V}{15mA} \approx 13 \Omega \$
So that gives us the straight line. How do we shift it to the right? Simple: all simulation packages have a voltage source: a component that has a voltage you define across it under all conditions. To get the value, we can simply look at our graph and extend the line to see where it would intersect the Y axis (\$0A\$). Looks like about 1.8V. So here's our simple LED model, a voltage source and LED in series:
This model breaks down if the current becomes very small. A real LED turns off, and blocks current like a diode, but in this model you start getting a reverse current, like a resistor would do. You can improve this by adding an ideal diode in series, if you like.
There are finer details that this also doesn't simulate: it doesn't simulate that smooth "knee" where the LED just starts to turn on. It doesn't simulate reverse leakage current, or temperature effects, or photocurrent. However, most of this is not significant in practical LED circuits.
On that practical note: there is a simpler model most engineers use day-to-day: just a voltage source. For this LED, if you just assume the voltage across it whenever it's on will be \$2V\$ whenever its on, you are probably close enough. If you are going to include a \$1k\Omega\$ current-limiting resistor in series, then the \$13\Omega\$ from the LED hardly matters. If the current gets high enough to deviate significantly from that \$2V\$ estimate, the LED is probably destroyed.
These are complex devices containing many transistors and components, so any SPICE model will be a macro model, made up of voltage controlled currents sources, Current controlled current sources , Voltage controlled voltage sources etc. etc. and the only people who can do that reasonably are the designers themselves.
Look on the Maxim website for these models, if they don't have them look to someone who second sources these parts and might have done it. The company that is best at this is LT itself so I'd suggest seeing if there is a close match and then it would be likely that LT has these devices in the library for LTSpice.
Best Answer
Try ngspice or - probably easier if you use Windows - LTspice (beside the GUI, it can run SPICE netlists).