• Welcome to TechPowerUp Forums, Guest! Please check out our forum guidelines for info related to our community.

Team Group T-Force and T-Create NVMe SSDs at Computex 2024: Magnetic Stacked Heatsinks

btarunr

Editor & Senior Moderator
Staff member
Joined
Oct 9, 2007
Messages
47,296 (7.53/day)
Location
Hyderabad, India
System Name RBMK-1000
Processor AMD Ryzen 7 5700G
Motherboard ASUS ROG Strix B450-E Gaming
Cooling DeepCool Gammax L240 V2
Memory 2x 8GB G.Skill Sniper X
Video Card(s) Palit GeForce RTX 2080 SUPER GameRock
Storage Western Digital Black NVMe 512GB
Display(s) BenQ 1440p 60 Hz 27-inch
Case Corsair Carbide 100R
Audio Device(s) ASUS SupremeFX S1220A
Power Supply Cooler Master MWE Gold 650W
Mouse ASUS ROG Strix Impact
Keyboard Gamdias Hermes E2
Software Windows 11 Pro
M.2-2280 SSDs are always smaller than they look in pictures, a quarter of the size of a DIMM, but we've come across some huge cooling solutions. One of the most interesting of these is the T-Force Dark Airflow 06 magnetic-stacked cooling solution. An extruded aluminium heatsink with its fins positioned sideways, has two flattened surfaces, one of which makes contact with the SSD, the other is equally flat, and can make contact with another such heatsink.

A 20 mm fan pushes airflow sideways through the heatsink. The heatsink is magnetized to help with the stacking. The Dark Airflow 05 is a more conventional fin-stack heatsink that isn't expandable, it uses a simple aluminium fin-stack to which heat is fed by two copper heatpipes. The T-Force GE Pro Gen 5 is an M.2-2280 drive that leads Team Group's gaming SSD lineup. It comes in capacities of up to 4 TB, with transfer speeds of 14 GB/s reads, with up to 11 GB/s writes. The T-Create I54 Ai Gen 5 is not far behind, with a 4 TB, and up to 14 GB/s sequential speeds on tap, with a large amount of SLC caching that should benefit AI workloads.



View at TechPowerUp Main Site
 
Joined
Mar 21, 2016
Messages
2,508 (0.78/day)
If you need a bigger heatsink just build a bigger one. They don't even appear to be using a thermal pad or paste between the two magnetic surfaces. Doesn't look like it would be overly efficient with that approach, but to cool a SSD is probably bit overkill anyway.
 
Joined
Feb 20, 2019
Messages
8,339 (3.91/day)
System Name Bragging Rights
Processor Atom Z3735F 1.33GHz
Motherboard It has no markings but it's green
Cooling No, it's a 2.2W processor
Memory 2GB DDR3L-1333
Video Card(s) Gen7 Intel HD (4EU @ 311MHz)
Storage 32GB eMMC and 128GB Sandisk Extreme U3
Display(s) 10" IPS 1280x800 60Hz
Case Veddha T2
Audio Device(s) Apparently, yes
Power Supply Samsung 18W 5V fast-charger
Mouse MX Anywhere 2
Keyboard Logitech MX Keys (not Cherry MX at all)
VR HMD Samsung Oddyssey, not that I'd plug it into this though....
Software W10 21H1, barely
Benchmark Scores I once clocked a Celeron-300A to 564MHz on an Abit BE6 and it scored over 9000.
If you need a bigger heatsink just build a bigger one. They don't even appear to be using a thermal pad or paste between the two magnetic surfaces. Doesn't look like it would be overly efficient with that approach, but to cool a SSD is probably bit overkill anyway.
Exactly!
Magnetism is not a mechanism for thermal transfer!
 
Joined
May 3, 2018
Messages
2,881 (1.19/day)
Exactly!
Magnetism is not a mechanism for thermal transfer!
The strange world of quantum mechanics just got a little stranger with the discovery that a magnetic field can control the flow of heat from one body to another. First predicted nearly 50 years ago, the effect might some day form the basis of a new generation of electronic devices that use heat rather than charge as the information carrier.

The research stems from the work of physicist Brian Josephson, who in 1962 predicted that electrons could 'tunnel' between two superconductors separated by a thin layer of insulator — a process forbidden in classical physics. The Josephson junction was subsequently built and used to make superconducting quantum interference devices (SQUIDs), which are now sold commercially as ultra-sensitive magnetometers.


In the latest work, Francesco Giazotto and María José Martínez-Pérez at the NEST nanoscience institute in Pisa, Italy, measured the devices’ thermal behavior — that is, how the electrons inside them transfer heat. The duo heated one end of a SQUID several micrometers long and monitored the temperature of an electrode connected to it. A SQUID consists of two y-shaped pieces of superconductor joined together to form a loop, but with two thin pieces of insulating material sandwiched in between (see figure); as the researchers varied the magnetic field passing through the loop, the amount of heat flowing through the device also changed. The effect was in line with a theory put forward by Kazumi Maki and Allan Griffin in 1965.

The device worked by partly reversing the heat transfer, so that some would flow from the colder body to the warmer one. “This is completely unintuitive,” says Giazotto. “People are used to thinking of heat as disorder, so how can you impose quantum order on it? Amazingly, a device with Josephson junctions can do that.”
 
Joined
Oct 22, 2014
Messages
14,170 (3.82/day)
Location
Sunshine Coast
System Name H7 Flow 2024
Processor AMD 5800X3D
Motherboard Asus X570 Tough Gaming
Cooling Custom liquid
Memory 32 GB DDR4
Video Card(s) Intel ARC A750
Storage Crucial P5 Plus 2TB.
Display(s) AOC 24" Freesync 1m.s. 75Hz
Mouse Lenovo
Keyboard Eweadn Mechanical
Software W11 Pro 64 bit
I thought you used magnets to wipe data, not keep it cool.
 
Joined
Feb 20, 2019
Messages
8,339 (3.91/day)
System Name Bragging Rights
Processor Atom Z3735F 1.33GHz
Motherboard It has no markings but it's green
Cooling No, it's a 2.2W processor
Memory 2GB DDR3L-1333
Video Card(s) Gen7 Intel HD (4EU @ 311MHz)
Storage 32GB eMMC and 128GB Sandisk Extreme U3
Display(s) 10" IPS 1280x800 60Hz
Case Veddha T2
Audio Device(s) Apparently, yes
Power Supply Samsung 18W 5V fast-charger
Mouse MX Anywhere 2
Keyboard Logitech MX Keys (not Cherry MX at all)
VR HMD Samsung Oddyssey, not that I'd plug it into this though....
Software W10 21H1, barely
Benchmark Scores I once clocked a Celeron-300A to 564MHz on an Abit BE6 and it scored over 9000.
The strange world of quantum mechanics just got a little stranger with the discovery that a magnetic field can control the flow of heat from one body to another. First predicted nearly 50 years ago, the effect might some day form the basis of a new generation of electronic devices that use heat rather than charge as the information carrier.

The research stems from the work of physicist Brian Josephson, who in 1962 predicted that electrons could 'tunnel' between two superconductors separated by a thin layer of insulator — a process forbidden in classical physics. The Josephson junction was subsequently built and used to make superconducting quantum interference devices (SQUIDs), which are now sold commercially as ultra-sensitive magnetometers.


In the latest work, Francesco Giazotto and María José Martínez-Pérez at the NEST nanoscience institute in Pisa, Italy, measured the devices’ thermal behavior — that is, how the electrons inside them transfer heat. The duo heated one end of a SQUID several micrometers long and monitored the temperature of an electrode connected to it. A SQUID consists of two y-shaped pieces of superconductor joined together to form a loop, but with two thin pieces of insulating material sandwiched in between (see figure); as the researchers varied the magnetic field passing through the loop, the amount of heat flowing through the device also changed. The effect was in line with a theory put forward by Kazumi Maki and Allan Griffin in 1965.

The device worked by partly reversing the heat transfer, so that some would flow from the colder body to the warmer one. “This is completely unintuitive,” says Giazotto. “People are used to thinking of heat as disorder, so how can you impose quantum order on it? Amazingly, a device with Josephson junctions can do that.”
Cool, I guess Team Group are making these heatsinks out of superconductors cooled by liquid helium, and all the LHe cooling apparatus isn't pictured! ;)

Clearly, I can't afford these but maybe they'll come in handy for NASA, CERN, or some other research institute with easy access to superconductor cooling systems!
 
Top