The electronic structure of trimethylenemethane was discussed in 1948.^[1][2] It is a neutral four-carbon molecule containing four pi molecular orbitals. When trapped in a solid matrix at about 90 K (−183 °C), the six hydrogen atoms of the molecule are equivalent. Thus, it can be described either as zwitterion, or as the simplest conjugated hydrocarbon that cannot be given a Kekulé structure. It can be described as the superposition of three states:

It has a triplet ground state (³A₂′/³B₂), and is therefore a diradical in the stricter sense of the term.^[3] Calculations predict a planar molecule with three-fold rotational symmetry, with approximate bond lengths 1.40 Å (C–C) and 1.08 Å (C–H). The H–C–H angle in each methylene is about 121°.^[1]

Of the three singlet excited states, the first one, 1¹A₁ (1.17 eV above ground), is a closed shell diradical with flat geometry and fully degenerate threefold (D_3h) symmetry. The second one, 1¹B₂ (also at 1.17 eV), is an open-shell radical with a D_3h-symmetric equilibrium between three equal geometries; each has a longer C–C bond (1.48 Å) and two shorter ones (1.38 Å), and is flat and bilaterally symmetric except that the longer methylene is twisted 79° out of the plane (C₂ symmetry). The third singlet state, 2¹A₁/¹A₁′ (3.88 eV), is also a D_3h-symmetric equilibrium of three geometries; each is planar with one shorter C–C bond and two longer ones (C_2ν symmetry).^[1]

The next higher energy states are degenerate triplets, 1³A₁ and 2³B₂ (4.61 eV), with one excited electron; and a quintet state, ⁵B₂ (7.17 eV), with the p orbitals occupied by single electrons and D_3h symmetry.^[1]

Trimethylenemethane was first obtained from photolysis of the diazo compound 4-methylene-Δ₁-pyrazoline with expulsion of nitrogen, in a frozen dilute glassy solution at −196 °C (77 K).^[3]

It was also obtained from photolysis of 3-methylenecyclobutanone, both in cold solution and in the form of a single crystal, with expulsion of carbon monoxide. In both cases, trimethylenemethane was detected by electron spin resonance spectroscopy.^[3]

Trimethylenemethane has been obtained also by treating potassium with 2-iodomethyl-3-iodopropene and isobutylene diiodide (IH
₂C)₂C=CH
₂ in the gas phase. However the product quickly dimerizes to yield 1,4-dimethylenecyclohexane, and also 2-methylpropene by abstracting two hydrogen atoms from other molecules (hydrocarbon or potassium hydride).^[4]

A number of organometallic complexes have been prepared, starting with Fe(C
₄H
₆)(CO)₃, which was obtained by the ring-opening of methylenecyclopropane with diiron nonacarbonyl (Fe
₂(CO)₉).^[3] The same complex was prepared by the salt metathesis reaction of disodium tetracarbonylferrate (Na
₂Fe(CO)₄) with 1,1-bis(chloromethyl)ethylene (H₂C=C(CH₂Cl)₂).^[5] Related reactions give M(TMM)(CO)₄ (M = Cr, Mo). The reaction leading to (TMM)Mo(CO)₄ also gives Mo(C
₈H
₁₂)(CO)₃ containing a dimerized TMM ligand.^[5]

TMM complexes have been examine for their potential in organic synthesis, specifically in the trimethylenemethane cycloaddition reaction with only modest success. One example is a palladium-catalyzed [3+2]cycloaddition of trimethylenemethane.^[6]

•  
  Structure of Ru(trimethylenemethane)(CO)₃, viewed down C₃ axis.^[7]
•  
  Structure of Ru(trimethylenemethane)(CO)₃, viewed orthogonal to C₃ axis.