Method to prevent cracks in optical fiber preforms

What is claimed is: 1. A core-cladding assembly comprising: a porous soot cladding monolith, said porous soot cladding monolith including a first porous cladding glass layer surrounding an internal cavity, said porous soot cladding monolith comprising a first material having a first coefficient of thermal expansion; a first consolidated glass body having a portion positioned in said internal cavity, said first consolidated glass body comprising a second material having a second coefficient of thermal expansion, said second coefficient of thermal expansion differing from said first coefficient of thermal expansion, said first consolidated glass body having a centerline aligned along an axial direction of said internal cavity and an end surface, said end surface crossing said centerline; and a second glass body having a portion positioned in said internal cavity in direct contact with said end surface of said first consolidated glass body, said second glass body comprising a third material having a third coefficient of thermal expansion, said third coefficient of thermal expansion differing from said second coefficient of thermal expansion. 2. The core-cladding assembly of claim 1 , wherein said first material comprises silica. 3. The core-cladding assembly of claim 1 , wherein said second material comprises silica containing a dopant. 4. The core-cladding assembly of claim 3 , wherein said first consolidated glass body has a core-clad ratio of at least 0.70. 5. The core-cladding assembly of claim 1 , wherein said third material comprises silica. 6. The core-cladding assembly of claim 1 , wherein said second coefficient of thermal expansion is greater than said first coefficient of thermal expansion. 7. The core-cladding assembly of claim 1 , wherein said second coefficient of thermal expansion is greater than said third coefficient of thermal expansion. 8. The core-cladding assembly of claim 1 , further comprising a third glass body having a portion positioned in said internal cavity, said third glass body comprising a fourth material having a fourth coefficient of thermal expansion, said fourth coefficient of thermal expansion differing from said second coefficient of thermal expansion. 9. A product formed by consolidating the core-cladding assembly of claim 1 . 10. The core-cladding assembly of claim 3 , wherein said dopant comprises Ge. 11. The core-cladding assembly of claim 3 , wherein said first consolidated glass body has a core-clad ratio of at least 0.90. 12. The core-cladding assembly of claim 1 , wherein said second material has a higher refractive index than said first material. 13. The core-cladding assembly of claim 1 , wherein said third material has a lower refractive index than said second material. 14. The core-cladding assembly of claim 1 , wherein said first consolidated glass body is wholly contained within said internal cavity. 15. The core-cladding assembly of claim 14 , wherein said second glass body is wholly contained within said internal cavity. 16. The core-cladding assembly of claim 14 , further comprising a third glass body having a portion positioned in said internal cavity, said third glass body comprising a fourth material having a fourth coefficient of thermal expansion, said fourth coefficient of thermal expansion differing from said second coefficient of thermal expansion. 17. The core-cladding assembly of claim 16 , wherein said first consolidated glass body is in direct contact with said second glass body and said third glass body within said internal cavity. 18. The core-cladding assembly of claim 16 , wherein said second glass body has a thickness in the range from 1.0 mm to 75 mm and said third glass body has a thickness in the range from 1.0 mm to 75 mm. 19. The core-cladding assembly of claim 1 , wherein said second glass body has a thickness in the range from 1.0 mm to 75 mm. 20. The core-cladding assembly of claim 7 , wherein said third coefficient of thermal expansion is greater than or equal to said first coefficient of thermal expansion. 21. The core-cladding assembly of claim 1 , wherein said first consolidated glass body and said second glass body are stacked in an axial direction in said internal cavity. 22. The core-cladding assembly of claim 1 , wherein said first consolidated glass body has a cylindrical shape. 23. The core-cladding assembly of claim 22 , wherein said second glass body has a cylindrical shape. 24. The core-cladding assembly of claim 1 , wherein the second glass body covers the end surface of the first consolidated glass body. 25. The core-cladding assembly of claim 8 , wherein said third glass body directly contacts a second end surface of said first consolidated glass body. 26. The core-cladding assembly of claim 1 , wherein said end surface faces an entrance of said internal cavity. 27. The core-cladding assembly of claim 1 , wherein said end surface is flat. 28. The core-cladding assembly of claim 1 , wherein said core-cladding assembly includes a gap between an outer surface of said first consolidated glass body and an inner surface of said porous soot cladding monolith. 29. The core-cladding assembly of claim 1 , wherein said first consolidated glass body and said second glass body directly contact said first porous cladding glass layer.