Ultrathick (>25 mu m) carbon films were obtained on the inner surface of hollow and micron-thick quartz fibers by confining CH4/He or C2H2/He microplasmas in their hollow cores. The resulting carbon films were studied by using scanning electron microscopy and energy-dispersive X-ray spectroscopy. The microplasma-enhanced chemical vapor deposition (CVD) technique resulted in the uniform growth of amorphous carbon films on the inner surface of very long (>1 m) hollow-core fibers. Film deposition is performed by using microplasmas at atmospheric pressure and at 50 Pa. The carbon films obtained with the latter show the smooth inner surfaces and the well continuity across the film/optical fiber. Low-pressure CH4/He and C2H2/He microplasmas can lead to a rapid growth (similar to 2.00 mu m/min) of carbon films with their thickness of >25 mu m. The optical emission measurements show that various hydrocarbon species were formed in these depositing microplasmas due to the collisions between CH4/C2H2 molecules and energetic species. The microplasma-enhanced CVD technique running without the complicated fabrication processes shows its potentials for rapidly depositing the overlong carbon tubes with their inner diameters of tens of microns. (C) 2013 Elsevier B. V. All rights reserved.