Vibration absorber

What is claimed is: 1. A tuned mass damper, comprising: a damper mass including a first mass portion and a second mass portion connected by a third mass portion such that the first mass portion, the second mass portion, and the third mass portion form a U-shaped configuration of the damper mass, wherein the damper mass includes a portion of stress concentration within the third mass portion such that the third mass portion is configured to separate within the portion of stress concentration in response to a force transferred to the damper mass of the tuned mass damper to allow relative motion between the first mass portion and the second mass portion. 2. The tuned mass damper according to claim 1 , wherein the third mass portion is thinner in a lateral direction than the first mass portion and the second mass portion. 3. The tuned mass damper according to claim 1 , wherein the first mass portion is larger and has a greater mass than the second mass portion. 4. The tuned mass damper according to claim 1 , wherein the first mass portion has a first curved surface defined at a first end of the damper mass facing a first direction away from the second mass portion and the second mass portion has a second curved surface defined at a second end of the damper mass facing in a second and opposite direction away from the first mass portion, the force transferred to the damper mass is applied at the first curved surface of the first mass portion, and the damper mass is configured to rotate in response to the force applied at the first curved surface. 5. The tuned mass damper according to claim 4 , wherein the force transferred to the damper mass includes a first force applied at the first curved surface of the damper mass and a second force applied at the second curved surface of the damper mass, and the tuned mass damper is configured to rotate in response to the first force applied at the first curved surface and the second force applied at the second curved surface. 6. The tuned mass damper according to claim 1 , further comprising: a first spring and fluid-operated damper assembly that is configured to regulate motion of the damper mass with respect to an external portion; and a second spring and fluid-operated damper assembly that is configured to regulate motion of the damper mass with respect to the external portion, wherein the first mass portion includes a first bore and the second mass portion includes a second bore, the first spring and fluid-operated damper assembly extends at least partially through the first bore in the first mass portion, and the second spring and fluid-operated damper assembly extends at least partially through the second bore in the second mass portion. 7. A vehicle assembly defining a longitudinal axis and a lateral axis that is perpendicular to the longitudinal axis, the vehicle assembly comprising: a brake system including a rotor connected to a wheel assembly that includes a wheel and a caliper coupled to a wheel support and configured to apply a braking force to the rotor; and a tuned mass damper coupled to the wheel support, the tuned mass damper comprising a damper mass including a first mass portion, a second mass portion, and a third mass portion extending between the first mass portion and the second mass portion, wherein the caliper is positioned relative to the damper mass such that the third mass portion of the damper mass is diametrically opposite the caliper, wherein the first mass portion has a first curved surface at a first end of the damper mass, wherein the second mass portion has a second curved surface at a second end of the damper mass that is opposite the first end, wherein the first curved surface includes a first portion that faces away from the second mass portion relative to the longitudinal axis and a second portion that faces inward relative to the lateral axis, and wherein the first mass portion and the second mass portion are configured to rotate away from the longitudinal axis in response to a force applied at the first curved surface of the first mass portion. 8. The vehicle assembly according to claim 7 , wherein the first mass portion, the second mass portion, and the third mass portion of the damper mass form a U-shaped configuration of the damper mass. 9. The vehicle assembly according to claim 7 , further comprising a first engagement portion coupled to a vehicle body, the first engagement portion configured to transfer a force applied to the vehicle body to the first mass portion of the damper mass such that the tuned mass damper and the wheel assembly rotate outward relative to the longitudinal axis of the vehicle assembly. 10. The vehicle assembly according to claim 9 , further comprising a second engagement portion coupled to the vehicle body, the second engagement portion configured to transfer the force applied to the vehicle body to the second mass portion of the damper mass such that the first engagement portion and the second engagement portion cooperatively rotate the wheel assembly from a first position to a rotated position relative to the longitudinal axis of the vehicle assembly. 11. The vehicle assembly according to claim 7 , wherein a first position of the caliper is an upward position relative to the wheel support such that the caliper is above an axis of rotation of the wheel assembly and a second position of the damper mass is a downward position relative to the wheel support such that the third mass portion is opposite from the caliper relative to the axis of rotation of the wheel assembly. 12. The vehicle assembly according to claim 7 , wherein a first position of the caliper is a bottom position relative to the wheel support and a second position of the damper mass is a top position relative to the wheel support. 13. The vehicle assembly according to claim 7 , wherein the third mass portion includes a portion of stress concentration for the force applied at the first mass portion of the damper mass. 14. The vehicle assembly according to claim 7 , wherein the second curved surface of the second mass portion includes a first portion that faces away from the first mass portion relative to the longitudinal axis and a second portion that faces outward relative to the lateral axis. 15. A vibration absorption system, comprising: a damper mass coupled to a wheel assembly of a vehicle and including a first mass portion and a second mass portion connected by a third mass portion, the first mass portion including a curved surface, wherein a first portion of the curved surface faces away from the second mass portion relative to a longitudinal axis that extends along a length of the vehicle, and wherein a second portion of the curved surface faces inward relative to a lateral axis that is perpendicular to the longitudinal axis; and an engagement portion coupled to a vehicle body of the vehicle and extending toward the wheel assembly, the engagement portion including a geometric feature that is shaped to induce rotation of the wheel assembly away from the longitudinal axis during an impact to the vehicle body by interaction of the geometric feature with the curved surface of the first mass portion. 16. The vibration absorption system according to claim 15 , wherein the third mass portion is thinner in a lateral direction than the first mass portion and the second mass portion such that the third mass portion includes a portion of stress concentration such that the third mass portion is configured to separate within the portion of stress concentration in response to the impact to allow relative motion between the first mass por