I agree with Jim and Crutshow and I would like to add a few points.
A 2.6 nH inductor might have a Q as high as 100. (
https://www.farnell.com/datasheets/1681998.pdf). Has your simulation allowed for the imperfections of the components?
The inductance and capacitance imply a frequency of 200 MHz of higher. The transistor has an fT of 60 MHz. (
https://www.onsemi.com/pub/Collateral/BF420-D.PDF) which is the frequency at which its gain drops to 1. The gain of 50 that the transistor has will be available up to about 1 MHz. At 200 MHz it will be useless.
2.6 nH is tiny. 4 mm of 0.2 mm diameter wire has more inductance (). From my experience of oscillators, the capacitance should be much smaller and the inductance much larger for it to oscillate. If you have 330 pF and 2.6 nH, they resonate at 167 MHz, when their impedances are both 2.7 Ohms. With a Q of 100, the best impedance you could hope for is around 100 * 2.7 = 270 Ohms, so with a supply resistor of 2.2 kOhms, the very best you could get is about 1/10th output swing compared to supply.
A larger inductor and a smaller capacitor will give more impedance at resonance.
Are you intending to get an oscillator to run at 200 MHz or so? What is the application? At those sorts of frequencies, layout is possibly the most important thing to look at, and the simulations generally only look at the circuit diagram.