Assembly having at least two ceramic bodies joined with one another, especially a pressure measuring cell, and method for joining ceramic bodies by means of an active hard solder, or braze

The invention claimed is: 1. An assembly, comprising: a first ceramic body: a second ceramic body; and a joint for connecting said first ceramic body to said second ceramic body, wherein: said joint contains an active hard solder, or braze; said active hard solder, or braze, averaged over a continuous core volume, which is spaced from said first ceramic body and from said second ceramic body, in each case, by at least 1 μm, has an average composition C K having a liquidus temperature T l (C K ); the composition C K has a coefficient of thermal expansion α(C K ), wherein α(C K )=m·α(K), wherein m≤1.5, wherein α(K) is the average coefficient of thermal expansion of the ceramic material of said first and said second ceramic bodies; said joint has a first boundary layer and a second boundary layer of said active hard solder, or braze, which border on said first ceramic body and said second ceramic body, respectively; wherein at least one of said boundary layers, which lies outside of the core volume, has an average composition C B having a liquidus temperature T l (C B ), which lies not less than 50 K, under the liquidus temperature T l (C K ) of the average composition C K of the core volume. 2. The assembly as claimed in claim 1 , wherein: said at least one boundary layer has a thickness of no more than 3 μm. 3. The assembly as claimed in claim 1 , wherein: the composition C B has a liquidus temperature T l (C B ), which lies no more than 300 K above the liquidus temperature T l (C e ) of the eutectic point, respectively of the nearest intersection with a eutectic valley having a composition C e in the composition space. 4. The assembly as claimed in claim 1 , wherein: the alloy of the joint at the eutectic point, respectively at the nearest intersection with a eutectic valley, has a composition C e in the composition space, wherein C e :=(c e1 , . . . , c eN ), wherein |C e |=1, wherein the c ei are the stoichiometric fractions of the components K i with i=1, . . . , N at the eutectic point, respectively at the nearest intersection with a eutectic valley, wherein the difference between the composition C e and the composition C B is describable with a normalized vector difference D eB , wherein: C e =C B +a eB *D eB , with D eB |=1, wherein the difference between the composition C K and the composition C B is describable with a normalized vector difference D KB , wherein: C K =C B +a KB *D KB , with |D KB |=1, wherein a eB and a KB are positive scalars, and wherein for the scalar product s eK :=D eB ·D KB :s eK <0. 5. The assembly as claimed in claim 1 , wherein: said first ceramic body and/or said second ceramic body comprise Al 2 O 3 . 6. The assembly as claimed in claim 1 , wherein: said active hard solder, or braze, comprises Zr, Ni and Ti. 7. The assembly as claimed in claim 6 , wherein: the composition C K contains essentially zirconium and titanium, with (50+x) atom-% titanium and (50−x) atom-% zirconium, wherein x<10, and wherein the composition C K is present in the α-(Zr, Ti) phase. 8. The assembly as claimed in claim 1 , wherein: the composition C K has a coefficient of thermal expansion α(C K ), wherein α(C K )≤10·10 −6 /K. 9. The assembly as claimed in claim 1 , wherein: said at least one boundary layer has a thickness of no more than 1 μm. 10. The assembly as claimed in claim 1 , wherein: the composition C B has a liquidus temperature T l (C B ), which lies no more than 150 K above the liquidus temperature T l (C e ) of the eutectic point, respectively of the nearest intersection with a eutectic valley having a composition C e in the composition space. 11. The assembly as claimed in claim 1 , wherein: the composition C B has a liquidus temperature T l (C B ), which lies no more than 50 K above the liquidus temperature T l (C e ) of the eutectic point, respectively of the nearest intersection with a eutectic valley having a composition C e in the composition space. 12. A pressure measuring cell, comprising: a first ceramic body, said first ceramic body is a membrane body of a measuring membrane of the pressure measuring cell; a second ceramic body, said second ceramic body being a platform of the pressure measuring cell; and a ring-shaped joint for connecting said first ceramic body to said second ceramic body, wherein: said joint contains an active hard solder, or braze, said active hard solder, or braze, averaged over a continuous core volume, which is spaced from said first ceramic body and from said second ceramic body, in each case, by at least 1 um has an average composition C k having a liquidus temperature T l (C k ), the composition CK has a coefficient of thermal expansion *(CK), wherein *(CK)=m**(K), wherein m*1.5, wherein *(K) is the average coefficient of thermal expansion of the ceramic material of said first and said second ceramic bodies; said joint has a first boundary layer and a second boundary layer, which border on said first ceramic body and said second ceramic body, respectively; and at least one of said boundary layers, which lies outside of the core volume, has an average composition CB having a liquidus temperature Tl(CB), which lies not less than 50 K under the liquidus temperature Tl(CK) of the average composition CK of the core volume. 13. A method for manufacturing an assembly comprising a first ceramic body and a second ceramic body joined by means of an active hard solder, or braze, comprising the steps of: providing the active hard solder, or braze, between the ceramic bodies, wherein the active hard solder, or braze, has, averaged over a continuous core volume, an average composition C Ko having a liquidus temperature T i (C Ko ), wherein the composition has a coefficient of thermal expansion α(C K ), wherein α(C K )=m−α(K), wherein m<1.5, wherein α(K) is the average coefficient of thermal expansion of the ceramic material of said first and second ceramic bodies, wherein the active hard solder, or braze, has, on at least one of its surfaces facing said ceramic bodies, a boundary layer having an average composition C BO , wherein the composition C BO has a liquidus temperature T l (C BO ), which lies not less than 50 K, under the liquidus temperature T l (C KO ) of the average composition C KO of the core volume, wherein C BO :=(c BO1 , . . . , c BON ), wherein |C BO |=1, and wherein the c BOi are the stoichiometric fractions of the components K i i=1, . . . , N of the average composition of the active hard solder, or braze, in said boundary layer; and heating the ceramic body and the active hard solder, or braze, in a vacuum soldering, brazing process, up to a melting of the composition C BO , wherein: the boundary layer develops a melt and said melt mixes in the transition to the core region with the material of the core volume, whereby the liquidus temperature of the boundary layer is increased, so that the boundary layer at least partially isothermally solidifies or becomes more viscous. 14. A method as claimed in claim 13 , wherein: the providing of the active hard solder, or braze, includes that a solder preform, which has the composition C K0 , is coated by means of gas phase deposition, by sputtering, on at least one surface with a boundary layer, which has the composition C B0 . 15. A method as claimed in claim 13 , wherein: the providing of the active hard solder, or braze, includes that at least one surface section of a ceramic body is coated with a boundary layer, which has the composition C B0 , wherein the coating occurs by sputtering. 16. The method as claimed in claim