摘要:
An organic functional device (1; 40; 50) comprising a substrate (2) having a first electrode layer (3) and at least a first substrate shunt structure (6), at least a first organic functional layer (7) provided on top of the first electrode layer (3), a second, transparent electrode layer (8) arranged on top of the first organic functional layer (7). The organic functional device further comprises a plurality of mutually spaced apart second electrode shunting structures (9a-d) which are each in electrical contact with the second electrode layer (8) and with the first substrate shunt structure (6).
摘要:
Disclosed is an optoelectronic device including at least one optoelectronic active region comprising at least a rear electrode and a front electrode between which an organic optoelectronic material is sandwiched, said rear electrode being reflective, and a cover layer arranged in front of said front electrode. The cover layer is formed from a material with light-scattering particles of a first material dispersed in a transparent matrix of at an least partly hydrolyzed silica sol. Due to the highly scattering properties of the cover layer, the device is essentially concealed behind the cover layer when not in its operative state.
摘要:
The invention provides a lighting system (100, 200, 300) for controlling the growth of plants, the system comprising; an array of solid state/semiconductor light sources (101, 201, 301) adapted to emit light of a predetermined wavelength or wavelength range; and a cooling arrangement(102, 202, 302) comprising a pipe (103, 203, 303) having at least one inlet opening for receiving a gaseous cooling medium and a plurality of outlet openings (105, 205, 305) for releasing said gaseous cooling medium from said cooling arrangement, the cooling arrangement being in mechanical and thermal contact with said light sources. The invention also provides a method for controlling the growth of a plant in a greenhouse of growth chamber. The invention allows promoting the photosynthesis of a plant by modifying the conditions (light intensity, temperature, CO2 concentration) locally around the plant.
摘要:
The present invention relates to an integrated device (10) comprising at least one active organic element (14, 24, 26), a substrate supporting the at least one active organic element, a prefabricated thin battery (20) coupled to the at least one active organic element, and an encapsulation for sealing the integrated device, wherein one of the substrate and the encapsulation is formed by the prefabricated thin battery. This structure allows for a thin integrated device. The present invention also relates to a method for the manufacturing of such an integrated device.
摘要:
The present invention relates to an OLED-arrangement (1) provided with an encapsulating structure (2) for protecting an OLED-device (3). The OLED-arrangement (1) comprises an internally operative substance binding member (15) and the encapsulating structure (2) comprises a barrier (11) and a covering layer (5) formed by a polymeric material arranged outside the barrier (11). The barrier (11) is arranged outside the substance binding member (15). The present invention aims at providing a robust and reliable encapsulation of OLED-arrangements.
摘要:
Disclosed is a multistage thermal convection apparatus such as a two-stage thermal convection apparatus and uses thereof. In one embodiment, the two-stage thermal convection apparatus includes a temperature shaping element that assists a thermal convection mediated Polymerase Chain Reaction (PCR). The invention has a wide variety of applications including amplifying nucleic acid without cumbersome and expensive hardware associated with many prior devices. In a typical embodiment, the apparatus can fit in the palm of a user's hand for use as a portable, simple to operate, and low cost PCR amplification device.
摘要:
The invention relates to an OLED device (100) comprising an organic layer (130) between an anode (120) and a cathode (140), and a mirror layer (150) on the anode or cathode. The organic layer (130) is structured into electroluminescent zones (131) and inactive zones (132), while the mirror layer (150) is structured into nontransparent zones (151) and transparent zones (152). Via an at least partial alignment of these structures, the OLED device can be made transparent for environmental light and simultaneously emissive in a dominant (or even a single) direction.
摘要:
An electric transport component may include a substrate provided with a barrier structure with a first inorganic layer, an organic decoupling layer and a second inorganic layer, wherein the organic decoupling layer is sandwiched between the first and the second inorganic layer, and at least one electrically conductive structure distributed in a plane defined by the organic decoupling layer, and that is accommodated in at least one trench in the organic decoupling layer. A method of manufacturing an electric transport component may include the steps of providing a first inorganic layer, providing a first organic decoupling layer, forming at least one trench in the organic decoupling layer, depositing an electrically conductive material in the at least one trench, and providing a second inorganic layer. The component may be applied for example in opto-electrical and electro-optical devices.
摘要:
Disclosed is an OLED device including an organic layer disposed between an anode and a cathode, and a mirror layer on the anode or cathode. The organic layer is structured into electroluminescent zones and inactive zones, while the mirror layer is structured into nontransparent zones and transparent zones. Via an at least partial alignment of these structures, the OLED device can be made transparent for environmental light and simultaneously emissive in a dominant direction.
摘要:
The invention relates to a method of encapsulating a flexible optoelectronic multi-layered structure (6) provided on a polymer substrate (2) comprising the steps of providing the flexible optoelectronic multi-layered structure with one or both a bottom encapsulation stack (B) and a top encapsulation stack (T), wherein the bottom encapsulation stack and the top encapsulation layer comprise a first inorganic layer (4a, 8a) separated from a second inorganic layer (4b, 8b) by a substantially continuous getter layer (5, 8) comprising a metal oxide, the first and the second inorganic layers having an intrinsic water vapour transmission of 10−5 g·m−2·day−1 or less.