Electromagnetic actuator, valve, and injection pump

What is claimed is: 1. An electromagnetic actuator, comprising: an electromagnet comprising a coil that surrounds a pole core and a magnet armature, the magnet armature configured for an approach movement toward the pole core by the electromagnet, a stop element defining an air gap with a width between the magnet armature and the pole core at a closest approach position, the magnet armature fixedly connected to a pin extending from the magnet armature through the pole core, and wherein the magnet armature includes a support face facing toward the pole core, and the pole core has a counterpart face facing toward the support face of the magnet armature, wherein at least one of the support face and the counterpart support face includes a layer between that face and the other one of the support face and the counterpart support face, wherein the layer dampens the approach movement of the magnet armature toward the pole core, the layer comprising a plurality of webs and free spaces between adjacent pairs of webs, wherein a surface area of the webs is greater than the surface area of the free spaces, and wherein a thickness of the layer is less than a width of the air gap; wherein the layer comprises multiple partial layers allowing radial flow across the respective face between adjacent partial layers. 2. The electromagnetic actuator of claim 1 , wherein the layer is adhesively bonded or welded to at least one of the support face and the counterpart support face. 3. The electromagnetic actuator of claim 1 , wherein the layer has a uniform thickness. 4. The electromagnetic actuator of claim 1 , wherein the free spaces between the webs are formed such that air present in each free space builds up in at least one subregion of that free space during the approach movement of the support face and the counterpart support face, thereby pneumatically damping the approach movement. 5. The electromagnetic actuator of claim 1 , wherein the layer comprises a metal, a composite material, or a plastic. 6. A valve, comprising: a spring having a spring force, an electromagnetic actuator comprising: an electromagnet comprising a coil that surrounds a pole core and a magnet armature, the magnet armature configured for an approach movement toward the pole core by the electromagnet, and a stop element defining an air gap with a width between the magnet armature and the pole core at a closest approach position, the magnet armature fixedly connected to a pin extending from the magnet armature through the pole core, the magnet armature has a support face facing toward the pole core, and the pole core has a counterpart face facing toward the support face of the magnet armature, wherein at least one of the support face and the counterpart support face includes a layer between that face and the other one of the support face and the counterpart support face, wherein the layer dampens the approach movement of the magnet armature toward the pole core, the layer comprising a plurality of webs and free spaces between adjacent pairs of webs, wherein a surface area of the webs is greater than the surface area of the free spaces, and wherein a thickness of the layer is less than a width of the air gap, wherein the layer comprises multiple partial layers allowing radial flow across the respective face between adjacent partial layers, and wherein the electromagnetic actuator provides an actuator force acting counter to the spring force, a valve member actuated by the actuator as the magnet armature moves along with the connected pin, a sealing element configured for coupling to the valve member, a sealing seat that bears against the sealing element when the valve is closed. 7. The valve of claim 6 , wherein the layer is adhesively bonded or welded to at least one of the support face and the counterpart support face. 8. The valve of claim 6 , wherein the layer has a uniform thickness. 9. The valve of claim 6 , wherein the free spaces between the webs are formed such that air present in each free space builds up in at least one subregion of that free space during the approach movement of the support face and the counterpart support face, thereby pneumatically damping the approach movement. 10. The valve of claim 6 , wherein the layer comprises a metal, a composite material, or a plastic.