What makes the electron, as an excitation in a field, discrete?

In normal quantum mechanics, we consider an individual particle, turn its momentum and position into vector operators $hat{P}_i$ and $hat{X}_i$, and enforce the canonical commutation relations $[hat{X}_i,hat{P}_j]=ihbardelta_{ij}$. In Quantum Field Theory, we want to apply the laws of quantum mechanics to the field itself, and not to particles. A field $phi(mathbf{x})$ is treated as a generalized infinite-dimensional coordinate (each position $mathbf{x}$ is one degree of freedom, or one dimension). Its conjugate momentum is defined, using the usual procedure from Hamiltonian classical mechanics, as $$pi(mathbf{x})equivfrac{partialmathcal{L}}{partialdotphi(mathbf{x})},$$ where $mathcal{L}$ is the Lagrangian of the field. What we do in Quantum Field Theory is change the field $phi$ and the conjugate momentum $pi$ into operators. Then we need to figure out the eigenstates of the Hamiltonian. The way this is done depends on the field. For free Klein-Gordon fields, we do this using the commutation relations $[phi(mathbf{x}),pi(mathbf{x})]=ihbardelta^{(3)}(mathbf{x}-mathbf{y})$. We use the same trick that is often used in normal quantum mechanics to solve the quantum harmonic oscillator without invoking the Schrodinger equation. This is because the fourier-transformation the Klein-Gordon equation is of the same form as a harmonic oscillator equation. When we apply this method, we get creation and annihilation operators $a^dagger(mathbf{p})$ and $a(mathbf{p})$ that create and destroy energy-momentum eigenstates out of the vacuum. You can choose any value of $mathbf{p}$. The particles can have any momentum. However, the energy eigenvalues are $sqrt{|mathbf{p}|^2+m^2}$, so the particles always have mass $m$. There is no creation operator that gives you a "half" particle. There's the ground state $|0rangle$, a state with one particle $a^dagger(mathbf{p})|0rangle$, a state with two particles $a^dagger(mathbf{p}_1)a^dagger(mathbf{p}_2)|0rangle$, but nothing in between. The reasoning that leads to discrete particles is the same as the reasoning that leads to discrete energy states in the quantum harmonic oscillator. You could certainly form a linear combination of a one particle and a two particle state, but when measured, it will collapse into an eigenvalue of whatever operator corresponds to that measurement. The procedure for electrons is different, since electrons obey the Dirac equation, but the procedure for the Klein-Gordon field should give you the general idea.

There are two facts to be distinguished. Electrons are what we loosely call particles, so they only ever occur in discrete numbers. Millikan demonstrated the discreteness of charge. Secondly, localised states in general have discrete energies. Examples of these are atomic and molecular states. Free electrons have continuous electrons. So called free electrons in metals for all practical purposes have continuous energies if the metal volume is macroscopic.

Why electrons are discrete particles or why quantum states are often discrete is not known.

A further question is how we account for these properties mathematically, but I believe this is not what you are asking.