Thermo Orion Micro ATC Probe

Thermo Orion Micro ATC probe

Features

  • Durable ATC probe, has epoxy body and stainless steel sensing tip
  • Diameter of sensor tip is less than 1 mm
  • Measurements in samples as small as 10 uL
List Price $397.00
Your Price $369.21
Usually ships in 3-5 days
Thermo Scientific
Government and Educational PricingGovernment and Educational Pricing
Free Lifetime Tech SupportFree Lifetime Tech Support
Free Ground ShippingFree Ground Shipping
ImagePart#Product DescriptionPriceStockOrder
Thermo Orion Micro ATC Probe928007MD Orion Micro ATC probe, MiniDIN connector, 1m cable
$369.21
Usually ships in 3-5 days
Thermo Orion Micro ATC Probe
928007MD
Orion Micro ATC probe, MiniDIN connector, 1m cable
Usually ships in 3-5 days
$369.21
Thermo Orion Micro ATC Probe measure the temperature of samples with an ATC probe that is less than 1 mm in diameter. Durable and compact, the Thermo Orion Micro ATC probe specifically designed to measure temperature in extremely small samples. This probe measures the temperature of samples in a 384 well plate or in samples requiring a depth of immersion of 3 mm.
  • Durable ATC probe, has epoxy body and stainless steel sensing tip.
  • Diameter of sensor tip is less than 1 mm.
  • Measurements in samples as small as 10 micro liters.
  • Minimum depth of immersions 3 mm.
  • Micro size will allow to measure in almost any aqueous sample.
  • Micro tip size provides optimum temperature response.
  • Compatible with Orion Star Series meters
  • Temperature Range: 0 to 100 C
  • Temperature Accuracy: +/-1 C
  • Length: 117 mm
  • Diameter: 5 mm
  • Tip Diameter: 1 mm
  • Approx. Tip Length: 38 mm
  • Minimum depth of Immersion: 3 mm
Questions & Answers
No Questions
Please, mind that only logged in users can submit questions

In The News

Diatoms dominate Muskegon Lake in a cold and rainy year

Climate change-driven volatility is changing lakes at the base of their food webs. That’s one way to interpret new research that documented such a change in Muskegon Lake on the coast of Lake Michigan. Researchers found that, in one particularly rainy and cool year, normal phytoplankton diversity and patterns were cast aside. Instead, one group of algae dominated the entire year, offering a glimpse into the kinds of surprising changes that could happen in the future. “Phytoplankton are a very responsive group of organisms,” said Jasmine Mancuso, whose research detailing the change in the lake was published in October in Journal of Great Lakes Research .

Read More

In the Right Place All the Time: Greenhouse Gas Research and NTL-LTER

While researchers all over the globe have been studying greenhouse gases, there are still some areas in the field that have not received as much attention as they deserve. Emily Stanley, professor in the department of integrative biology at the University of Wisconsin and principal investigator for North Temperate Lakes Long Term Ecological Research (NTL-LTER), has spent a significant part of her career exploring a few of them. “Clearly we have a problem with greenhouse gases. What people may not realize is that streams and lakes are hotspots of global methane and CO2. Understanding greenhouse gas dynamics in these systems is important because they are vents all over the world and they are not insignificant,” said Stanley.

Read More

Tides and microbes transform nitrogen where streams and the ocean meet

Enormous amounts of excess nitrogen hit water bodies all over the globe, including the U.S., due to runoff from agricultural and other human activities. This nitrogen can cause dead zones and harmful algal growth. Before it reaches the ocean, microbes can process and remove some of it from stream sediments, connected aquifers and tidal freshwater zones.  Thanks to this process, coasts can have a decreased likelihood of harmful algal blooms.  Keeping coastal waters clean is important for many reasons, including the fact that about 60% of the U.S. population lives on coasts. But despite the importance of these nitrogen processes, researchers have not fully investigated how they work.

Read More