The Higgs boson and the hypothetical graviton particle serve different roles in our current understanding of particle physics.
The Higgs boson is associated with the Higgs field, which is a quantum field that permeates all of space. According to the Higgs mechanism, when other elementary particles interact with the Higgs field, they acquire mass. The Higgs field is responsible for providing mass to the fundamental particles in the Standard Model of particle physics, such as quarks and leptons. So, in a sense, the Higgs boson is responsible for giving mass to other particles, rather than receiving mass from the graviton or any other particle.
On the other hand, the graviton is a hypothetical particle in the framework of quantum field theory that is believed to be the mediator of the gravitational force. In the theory of general relativity, gravity is described as the curvature of spacetime caused by mass and energy. In the context of quantum field theory, attempts have been made to describe gravity in terms of particles called gravitons, similar to how other fundamental forces (such as electromagnetism) are mediated by particles (such as photons).
However, it's important to note that a consistent theory of quantum gravity, which successfully combines general relativity and quantum mechanics while incorporating a graviton, has not yet been achieved. The nature of gravity at the quantum level and the existence of gravitons are still the subject of ongoing research and remain theoretical concepts that have not been experimentally confirmed.
So, to summarize, the Higgs boson is responsible for giving mass to other particles through their interactions with the Higgs field, while the graviton is a hypothetical particle that would mediate the gravitational force if it exists. The relationship between the Higgs boson and the graviton, if any, would depend on a complete theory that successfully unifies gravity and quantum mechanics, which is an active area of research.