Dry reforming (DRM) is a very promising route for producing carbon rich syngas from key future feed stocks of chemical industry: CO2 and methane. Partial combustion of methane with pure oxygen, preferably produced via water electrolysis, can be used to compensate for the required heat of reaction in autothermal operation of DRM. Therefore, a novel reactor concept is presented. The multitubular reactor consists of an inert section to perform efficient heat integration and a catalytically coated reaction section where temperatures far above 1000 degrees C are realized by means of ceramic materials, a suitable catalyst, and simultaneous combustion. A prototype laboratory scale reactor, equilibrium models, and a detailed kinetic model are used to measure the reactor performance in laboratory and in industrial scale. A stable operation is predicted in large scale reactors since constantly high reaction temperatures around 1000 degrees C can prevent harmful coke formation. Besides, the high temperatures enable CO2 conversions above 60% along the catalyst zone in a reactor which is characterized by a very simple and scalable design. (C) 2016 Elsevier B.V. All rights reserved.