As far as my current understanding goes, the majority of mass derives from the binding energy between particles; only a small portion of the mass is due to the higgs interaction.
Weight not mass
I was assuming that the image was confusing the term "weight" with "mass" (a completely forgivable and understandable mistake for a layman, given that both are equal on earth — give or take the variance in Earth's gravitational field [2.2])). If weight was intended to be a separate term, then it's just incorrect. Weight is the term given to the force that objects in a gravitational field impart on others when they are not accelerating (by "not accelerating" I mean, for example if one looks at the Earth, the object is still with reference to the surface of the Earth) [1.1], whereas mass is the term for the measure of an objects inertia [2.3][3]. Relativity shows that mass is equivalent to energy [4]. In SI, weight is measured in Newton's [1.2] and mass is measured in kilograms [2.1].
As far as my current understanding goes, the majority of mass derives from the binding energy between particles; only a small portion of the mass is due to the higgs interaction.
Weight not mass
I was assuming that the image was confusing the term "weight" with "mass" (a completely forgivable and understandable mistake for a layman, given that both are equal on earth — give or take the variance in Earth's gravitational field [2.2])). If weight was intended to be a separate term, then it's just incorrect. Weight is the term given to the force that objects in a gravitational field impart on others when they are not accelerating (by "not accelerating" I mean, for example if one looks at the Earth, the object is still with reference to the surface of the Earth) [1.1], whereas mass is the term for the measure of an objects inertia [2.3][3]. Relativity shows that mass is equivalent to energy [4]. In SI, weight is measured in Newton's [1.2] and mass is measured in kilograms [2.1].