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Piperidine absorbs CO2 and H2O in air to form a mo-lecular complex: piperidium-1-piperidinecarboxylate-H2O. The structure of the complex was characterized by X-ray single crystal diffraction. The crystal structure was determined to be triclinic, space group P 1with a=0.648 6(8) nm, b=0.809 2(10) nm, c= 1.357 1(16) nm,α =96.967(16)°, β =102.506(15)°,γ =104.202 (15)°, Z=2. The complex is stabilized via five hydrogen bonds between the three components, N—O electrostatic interaction and O—O interaction (electron transfer) between1-piperidinecarboxylate and H2O. Due to electron transference of carbamate ion, the oxygen atom in water molecule is strongly negatively charged and the O—H bond is considerably shorter than that of the free molecule of water. The formation of the molecular complex is a reversible process and will decompose upon heating. The mechanism of formation and stabilization is further investigated herein.
Piperidine absorbs CO2 and H2O in air to form a mo-lecular complex: piperidium-1-piperidinecarboxylate-H2O. The structure of the complex was characterized by X-ray single crystal diffraction. The crystal structure was determined to be triclinic, space group P 1with a = 0.648 6 (8) nm, b = 0.809 2 (10) nm, c = 1.357 1 (16) nm with α = 96.967 (16) °, β = 102.506 (15) °, °, Z = 2. The complex is stabilized via five hydrogen bonds between the three components, N-O electrostatic interaction and O-O interaction (electron transfer) between1-piperidinecarboxylate and H2O. Due to electron transfer of carbamate ion, the oxygen atom in water molecule is strongly negatively charged and the O-H bond is quite shorter than that of the free molecule of water. The formation of the molecular complex is a reversible process and will decompose upon heating. The mechanism of formation and stabilization is further investigated here.