Abstract: Example embodiments of the present invention disclose a semiconductor memory device and a method of forming a memory device. A semiconductor memory device may include a digit line disposed on a substrate, an intermediate insulating layer covering the digit line, a magnetic tunnel junction (MTJ) pattern disposed on the intermediate insulating layer and over the digit line, the MTJ pattern including a sequentially stacked lower magnetic pattern, upper magnetic pattern, and capping pattern, wherein the capping pattern does not react with the upper magnetic pattern at a temperature above about 280° C., and a bit line connected to the capping pattern and disposed to intersect the digit line.

Abstract: Provided are magnetic tunnel junction structures having bended tips at both ends thereof, magnetic RAM cells employing the same and photo masks used in formation thereof. The magnetic tunnel junction structures have a pinned layer pattern, a tunneling insulation layer pattern and a free layer pattern, which are stacked on an integrated circuit substrate. At least the free layer pattern has a main body as well as first and second bended tips each protruded from both ends of the main body when viewed from a plan view.

Abstract: Example embodiments of the present invention disclose a semiconductor memory device and a method of forming a memory device. A semiconductor memory device may include a digit line disposed on a substrate, an intermediate insulating layer covering the digit line, a magnetic tunnel junction (MTJ) pattern disposed on the intermediate insulating layer and over the digit line, the MTJ pattern including a sequentially stacked lower magnetic pattern, upper magnetic pattern, and capping pattern, wherein the capping pattern does not react with the upper magnetic pattern at a temperature above about 280° C., and a bit line connected to the capping pattern and disposed to intersect the digit line.

Abstract: A magnetic tunnel junction device includes a magnetically programmable free magnetic layer. The free magnetic layer includes a lamination of at least two ferromagnetic layers and at least one intermediate layer interposed between the at least two ferromagnetic layers.

Abstract: Example embodiments of the present invention disclose a semiconductor memory device and a method of forming a memory device. A semiconductor memory device may include a digit line disposed on a substrate, an intermediate insulating layer covering the digit line, a magnetic tunnel junction (MTJ) pattern disposed on the intermediate insulating layer and over the digit line, the MTJ pattern including a sequentially stacked lower magnetic pattern, upper magnetic pattern, and capping pattern, wherein the capping pattern does not react with the upper magnetic pattern at a temperature above about 280° C., and a bit line connected to the capping pattern and disposed to intersect the digit line.

Abstract: Magnetic Random Access Memory (MRAM) devices include a lower electrode and a magnetic tunnel junction on the lower electrode. The magnetic tunnel junction includes a seed layer and a tunneling barrier that is oriented in a same direction as the most closely packed plane direction of the seed layer. An oxide layer may be provided between the lower electrode and the magnetic tunnel junction. The lower electrode may be a titanium-rich TiN layer having more than 50 atomic percent titanium content. Analogous fabrication methods are also described.

Abstract: Magnetic Random Access Memory (MRAM) devices include a lower electrode and a magnetic tunnel junction on the lower electrode. The magnetic tunnel junction includes a seed layer and a tunneling barrier that is oriented in a same direction as the most closely packed plane direction of the seed layer. An oxide layer may be provided between the lower electrode and the magnetic tunnel junction. The lower electrode may be a titanium-rich TiN layer having more than 50 atomic percent titanium content. Analogous fabrication methods are also described.

Abstract: A magnetic random access memory device may include a semiconductor substrate, a magnetic tunnel junction (MTJ) structure, a contact plug, and a digit line. More particularly, the MTJ structure may be on the semiconductor substrate, and the digit line may be adjacent the magnetic tunnel junction structure. In addition, the contact plug may provide electrical connection between the magnetic tunnel junction structure and the semiconductor substrate, and the contact plug may be between the magnetic tunnel junction structure and the semiconductor substrate. Related methods are also discussed.

Abstract: A magnetic random access memory device may include a semiconductor substrate, a magnetic tunnel junction (MTJ) structure, a contact plug, and a digit line. More particularly, the MTJ structure may be on the semiconductor substrate, and the digit line may be adjacent the magnetic tunnel junction structure. In addition, the contact plug may provide electrical connection between the magnetic tunnel junction structure and the semiconductor substrate, and the contact plug may be between the magnetic tunnel junction structure and the semiconductor substrate. Related methods are also discussed.

Abstract: Magnetic Random Access Memory (MRAM) devices include a lower electrode and a magnetic tunnel junction on the lower electrode. The magnetic tunnel junction includes a seed layer and a tunneling barrier that is oriented in a same direction as the most closely packed plane direction of the seed layer. An oxide layer may be provided between the lower electrode and the magnetic tunnel junction. The lower electrode may be a titanium-rich TiN layer having more than 50 atomic percent titanium content. Analogous fabrication methods are also described.

Abstract: A method of writing to magnetic random access memory (MRAM) devices is provided. The method includes preparing a digit line disposed on a semiconductor substrate, a bit line crossing over the digit line, and a magnetic tunnel junction (MTJ) interposed between the digit line and the bit line. The MTJ has a pinned layer, a tunneling insulating layer, and a synthetic anti-ferromagnetic (SAF) free layer which are sequentially stacked. In addition, the SAF free layer has a bottom free layer and a top free layer which are separated by an exchange spacer layer. An initial magnetization state of the MTJ is read and compared with a desired magnetization state. When the initial magnetization state is different from the desired magnetization state, a first write line pulse is applied to one of the digit line and the bit line, and a second write line pulse is applied to the other of the digit line and the bit line, thereby changing the magnetization state of the MTJ.

Abstract: There are provided a magnetic tunnel junction structure and a method of fabricating the same. The magnetic tunnel junction structure includes a lower electrode, a lower magnetic layer pattern and a tunnel layer pattern, which are sequentially formed on the lower electrode. The magnetic tunnel junction structure further includes an upper magnetic layer pattern, a buffer layer pattern, and an upper electrode, which are sequentially formed on a portion of the tunnel layer pattern. The sidewall of the upper magnetic layer pattern is surrounded by an oxidized upper magnetic layer, and the sidewall of the buffer layer pattern is surrounded by an oxidized buffer layer. The depletion of the upper magnetic layer pattern and the lower magnetic layer pattern in the magnetic tunnel junction region can be prevented by the oxidized buffer layer.

Abstract: There are provided a magnetic tunnel junction structure and a method of fabricating the same. The magnetic tunnel junction structure includes a lower electrode, a lower magnetic layer pattern and a tunnel layer pattern, which are sequentially formed on the lower electrode. The magnetic tunnel junction structure further includes an upper magnetic layer pattern, a buffer layer pattern, and an upper electrode, which are sequentially formed on a portion of the tunnel layer pattern. The sidewall of the upper magnetic layer pattern is surrounded by an oxidized upper magnetic layer, and the sidewall of the buffer layer pattern is surrounded by an oxidized buffer layer. The depletion of the upper magnetic layer pattern and the lower magnetic layer pattern in the magnetic tunnel junction region can be prevented by the oxidized buffer layer.

Abstract: Example embodiments of the present invention disclose a semiconductor memory device and a method of forming a memory device. A semiconductor memory device may include a digit line disposed on a substrate, an intermediate insulating layer covering the digit line, a magnetic tunnel junction (MTJ) pattern disposed on the intermediate insulating layer and over the digit line, the MTJ pattern including a sequentially stacked lower magnetic pattern, upper magnetic pattern, and capping pattern, wherein the capping pattern does not react with the upper magnetic pattern at a temperature above about 280° C., and a bit line connected to the capping pattern and disposed to intersect the digit line.

Abstract: A method of writing to magnetic random access memory (MRAM) devices is provided. The method includes preparing a digit line disposed on a semiconductor substrate, a bit line crossing over the digit line, and a magnetic tunnel junction (MTJ) interposed between the digit line and the bit line. The MTJ has a pinned layer, a tunneling insulating layer, and a synthetic anti-ferromagnetic (SAF) free layer which are sequentially stacked. In addition, the SAF free layer has a bottom free layer and a top free layer which are separated by an exchange spacer layer. An initial magnetization state of the MTJ is read and compared with a desired magnetization state. When the initial magnetization state is different from the desired magnetization state, a first write line pulse is applied to one of the digit line and the bit line, and a second write line pulse is applied to the other of the digit line and the bit line, thereby changing the magnetization state of the MTJ.

Abstract: A magnetic random access memory device may include a semiconductor substrate, a magnetic tunnel junction (MTJ) structure, a contact plug, and a digit line. More particularly, the MTJ structure may be on the semiconductor substrate, and the digit line may be adjacent the magnetic tunnel junction structure. In addition, the contact plug may provide electrical connection between the magnetic tunnel junction structure and the semiconductor substrate, and the contact plug may be between the magnetic tunnel junction structure and the semiconductor substrate. Related methods are also discussed.

Abstract: Provided are magnetic tunnel junction structures having bended tips at both ends thereof, magnetic RAM cells employing the same and photo masks used in formation thereof. The magnetic tunnel junction structures have a pinned layer pattern, a tunneling insulation layer pattern and a free layer pattern, which are stacked on an integrated circuit substrate. At least the free layer pattern has a main body as well as first and second bended tips each protruded from both ends of the main body when viewed from a plan view.

Abstract: There are provided a magnetic tunnel junction structure and a method of fabricating the same. The magnetic tunnel junction structure includes a lower electrode, a lower magnetic layer pattern and a tunnel layer pattern, which are sequentially formed on the lower electrode. The magnetic tunnel junction structure further includes an upper magnetic layer pattern, a buffer layer pattern, and an upper electrode, which are sequentially formed on a portion of the tunnel layer pattern. The sidewall of the upper magnetic layer pattern is surrounded by an oxidized upper magnetic layer, and the sidewall of the buffer layer pattern is surrounded by an oxidized buffer layer. The depletion of the upper magnetic layer pattern and the lower magnetic layer pattern in the magnetic tunnel junction region can be prevented by the oxidized buffer layer.

Abstract: A magnetic tunnel junction device includes a magnetically programmable free magnetic layer. The free magnetic layer includes a lamination of at least two ferromagnetic layers and at least one intermediate layer interposed between the at least two ferromagnetic layers.

Abstract: Magnetic Random Access Memory (MRAM) devices include a lower electrode and a magnetic tunnel junction on the lower electrode. The magnetic tunnel junction includes a seed layer and a tunneling barrier that is oriented in a same direction as the most closely packed plane direction of the seed layer. An oxide layer may be provided between the lower electrode and the magnetic tunnel junction. The lower electrode may be a titanium-rich TiN layer having more than 50 atomic percent titanium content. Analogous fabrication methods are also described.