| Adding specific alloying substances, like nickel or | | | | near stability with theory basis. |
| manganese could stabilize the structure of the | | | | Transformation of Austenite |
| Austenitization, to facilitate the high temperature | | | | The temperature of magnetic materials "especially |
| adjustment of steel alloys of low ratios. | | | | when they have a Curie point", tend to act |
| Concerning the critical case of Austenitic | | | | magnetically at almost the exact temperature |
| stainless-steel, highly rated alloy contents form a | | | | that the transformation of Austenite has. That |
| stable structure, even in the ordinary | | | | behavior is attached to the special attitude of the |
| Room-Temperature. But on the other side, | | | | Austenite, |
| substances like chromium, molybdenum and, silicon | | | | Emission of Thermo "Optical": |
| tend to reveal the stabilization of the Austenite. | | | | The blacksmith results in noticeable modifications |
| The Austenite is stable only over 910°C. | | | | within the carbon-iron systems, therefore it |
| Meanwhile, using the Face-Centeraed-Cubic enables | | | | handles the desired mechanical features on the |
| the raising growth of the Face-Centered-Cubic | | | | metal. This happens mostly within quenching hard |
| and metallic transition. The raising growth of the | | | | and cooling operations. Within this trend, the |
| Austenite is very fruitful concerning the perfect | | | | shadow of light supported by the workspace is a |
| lattice matching and the similarity of the diamond | | | | pretty good measurement of temperature. When |
| face of the Face-Centered-Cubic. More of | | | | it turns into Red from basically Orange, we can |
| mono-layers (γ-iron type) could enhance rapidly | | | | say that the Austenite is formed in moderate or |
| as the predetermined thickness of strain | | | | high carbon steel. |
| multi-layers have been posed in addition to the | | | | |