While cegaton's answer will work, I'd like to point out that your question is much more complex than what many folks might see at first glance and is a perfect example to examine the output view transform.
Photorealism and Flames
Flames are, as we all know, bright.
When we say a term such as "photorealistic" we can infer very quickly that the learned aesthetic is referencing something. In this case, it is referencing the learned aesthetic of photography.
Photographic still images hold a good deal of latitude, or the entire range of light from a scene. For example, if a particular film stock holds fifteen stops of light, it might mean that it holds 8 stops down and 7 stops above middle grey.
When we consider a flame, we are dealing with a very large ratio of light in the flame itself, possibly four or five stops or more over middle grey. Film has often more than a sufficient number of stops above middle grey to hold and delicately roll off the highlight from a candel in many instances. Digital CGI though doesn't have an automatic and "native" latitude like film, but rather relies on a uniquely crafted display referred transform to map these ranges of light.
So what is happening in your image if you manage to get the emission correct on the candle? The candle can be very obviously emitting a coloured light, but no such colour is captured in the default render? How come?
The Secret Sauce of Views
The secret to this answer is the sRGB default view transform. This transform is directly dumped into the view via OpenGL calls, which are clipped at a display referred value of typically 1.0. That is, the sRGB view LUT is completely blind and ignorant, and chops off all of the scene referred data above 1.0.
In your scene, the linear value of 0.2 will be your baseline middle grey via the default view transform. That leaves a meager two and a bit stops above middle grey for the entire scene's highlights. That is, 0.2 + 0.2 is one stop, 0.4 + 0.4 is two stops, and the remaining 0.2 is a sliver of the next stop. That pathetically small two and a bit stops is obviously not even remotely the amount of latitude required to maintain any semblance of colour in the flame, and not even remotely close to emulating the dynamic range of a photograph.
When we compare that with the amount of light our sample film stock holds, we can see that the round off of highlights is entirely chopped off, and our candle flame bursts out to display referred white long before an equivalent film stock would.
Reconciling Display Referred and Scene Referred
The whole concept of photorealism then, is inherently broken and fundamentally impossible, with the default sRGB display referred transform from the scene referred data.
As a result, another possible solution could be to apply a method to get more stops into a gentle roll-off of the default sRGB view transform. In this case, trying a tone mapping operation or using a custom curve in the Color Management settings that bends roughly six or seven stops of latitude into the range between 0.2 and 1.0 display referred. For the more adventurous artist, they can experiment with crafting their own display referred view transforms that seek to emulate a closer dynamic range of film / digital photography.
Again, cegaton's answer will obviously work fine, but this question provides a wonderful opportunity to explore the nature of "photorealism" and the OpenColorIO view transformations.