The present disclosure provides an evaporation source and an evaporation device. The evaporation source includes a heat source structure and an evaporation container for accommodating a to-be-evaporated material. The heat source structure includes a heat source and a thermal conductor. The thermal conductor is in contact with the evaporation container, and the heat source is at the thermal conductor and around the evaporation container.

An organic molecular memory in an embodiment includes a first conducive layer, a second conductive layer, and an organic molecular layer provided between the first conductive layer and the second conductive layer, the organic molecular layer having an organic molecule, the organic molecule having a linker group bonded to the first conductive layer, a conjugated chain bonded to the linker group, and a phenyl group bonded to the conjugated chain opposite to the linker group and facing the second conductive layer, the conjugated chain including electron-accepting groups or electron-donating groups arranged in line asymmetry with respect to a bonding direction of the conjugate chain, the phenyl group having substituents R0, R1, R2, R3, and R4 as shown in the following formula, the substituent R0 being an electron-accepting group or an electron-donating group. ##STR00001##

Disclosed is a molecular diode using the assignment of electrical properties to inactive organic molecules when a self-assembled monolayer (SAM) thin film including an electrically inactive organic molecule is formed without synthesizing a separate organic molecule having electrical activity. The disadvantage of the instability of a conventional SAM can be overcome, a function can be extended, and electrical properties, such as a rectification characteristic in a non-functional molecule, can be induced even without the design and synthesis of organic molecules for introducing a functional molecule. Accordingly, the embodiments of the present disclosure can be usefully used in various technical fields in which an SAM is used, in particular, wide fields such as electronics, an organic display (OLED), solar cells, sensors, non-uniform catalysts, frictional electricity, cell growth surfaces, and a heat transfer control film.

The present invention relates to a memory device comprising biocompatible polymer nanoparticles, and a manufacturing method therefor. The present invention can provide a memory device which can be more efficiently integrated in the organic semiconductor field when applied to a biocompatible electronic device, and can have excellent capacitance by being treated with a silane coupling agent. In addition, the method for manufacturing the memory device, according to the present invention, uses a solution process, and thus a memory device can be manufactured with a very simple method.

An organic molecular memory includes a first electrode, a second electrode above the first electrode in a first direction, an organic molecule layer between the first and second electrodes and including a first molecule and a second molecule, the second molecule being closer to the second electrode than the first molecule, and a third electrode facing the second molecule. Each of the first and second molecules includes a metal complex or a fullerene derivative.

The present invention relates to an electronic switching device comprising an organic molecular layer in contact with a metal nitride electrode for use in memory, sensors, field-effect transistors or Josephson junctions. More particularly, the invention is included in the field of random access non-volatile memristive memories (RRAM). The invention thus further relates to an electronic component comprising a crossbar array comprising a multitude of said electronic switching devices.

A logic-gated protein device in which proximity-gated protein trans-splicing governs formation of an active protein from two otherwise inactive fragments.