Well, it's difficult to express this clearly. There's one and only one Higgs field. First of all it has a constant value throughout the universe, the socalled "vacuum expectation value", i.e., the vacuum state (the state of lowest energy) is one, where this field has a value. Now at the LHC through very high energy collisions of protons, one excites (among many other process) this Higgs field, which means one "creates a Higgs boson". This excitation (the Higgs boson) decays to other particles (which are in the picture of quantum field theory nothing else than excitations of their specific fields), which are detected and evaluated such to make sure that the Higgs boson really exists.
The logic behind this is the following: Over 50 years ago the physicists started to struggle with a correct mathematical description of the weak interaction, known much longer to be responsible for radioactive ##\beta## decay of atomic nuclei. There was also a very early model from the 1930ies by Fermi, which was built on quantum-field theoretical concepts, but this model had some formal shortcomings (it was not renormalizable as electrodynamics), and so one was trying to build a better renormalizable model even closer to the way electromagnetism is described by quantum electrodynamics. A prime candidate were the socalled gauge theories, based on a (btw. very beautiful, beacuse it's based on symmetries) mathematical formalism, but it turned out that this is pretty difficult, because such gauge theories lead to the prediction that the forces are mediated by fields whose quanta (i.e., elementary excitations) correspond to massless vector bosons like the photon. On the other hand, the weak interaction was known to be short-ranged, while massless fields imply long-range forces like the Coulomb field in classical electromagnetism. This force only falls off with ##1/r^2##, where ##r## is the distance between two point charges. Massive gauge bosons would solve this problem, but the trouble was that giving the gauge bosons a mass in the usual naive way destroys the nice properties of gauge theories and also their renormalizability. In the mid 60ies several physicists (among others Higgs and Englert, who got the Nobel prize for this work in 2013) came to the idea that one can give mass to the gauge bosons of the weak interaction by introducing another scalar field, which in it's lowest-energy ground state is not 0 but has a finite value (the mentioned "vacuum expectation value"). This gave the gauge bosons a mass without destroying the underlying mathematical symmetry principle underlying the gauge theory. But then Higgs immediately realized that the introduction of this field not only means that it can have this desired constant vacuum expectation value but must also be excitable, leading to the existence of a new particle, the socalled Higgs boson.
For quite a while this very abstract construction was not taken too seriously, and Higgs even had a hard time to get his (very short) paper published (finally it was published in PRL back to back with a similar paper by Brout and Englert). Also in the mid 60ies the quantum field theories were somewhat out of fashion, because of several problems, even the renormalizable theories have at very high energies. On the other hand, with renormalizable theories one could make precise predictions of the outcome of experiments with elementary particles, which were pretty good. Particularly in QED the precision in the agreement between experiment and theory was unprecedented. The real breakthrough of the gauge theories came in 1971 when 't Hooft in his doctoral thesis could show, working together with his adviser, Veltman, could prove the renormalizability of the non-Abelian gauge theories, which was the kind of theory used to describe the weak interaction (putting together the models by Glashow, Weinberg, Salam and many others with the Higgs mechanism to make the weak gauge bosons massive). Only a little later (in 1973) also the strong interactions were described by such a non-abelian gauge theory, Quantum Chromodynamics QCD (which is another fascinating story). Together with the Glashow-Salam-Weinberg-Higgs theory of the weak and electromagnetic interactions QCD builds the Standard Model of elementary particle physics.
