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Photos of Snowflakes Like You’ve Never Seen Them Before

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Sextillions of snowflakes fell from the sky this winter. That’s billions of trillions of them, now mostly melted away as spring approaches.

Few people looked at them closely, one by one.

Kenneth G. Libbrecht, a professor of physics at the California Institute of Technology, has spent a quarter-century trying to understand how such a simple substance — water — could freeze into a multitude of shapes.

“How do snowflakes form?” Dr. Libbrecht said during an online talk on Feb. 23 that was hosted by the Bruce Museum in Greenwich, Conn. “And how do these structures appear — and just, as I like to say, literally out of thin air?”

One of the people intrigued by Dr. Libbrecht’s snowflake research and photography was Nathan P. Myhrvold, a former chief technology officer at Microsoft who has since pursued projects in myriad scientific disciplines, including paleontology, cooking and astronomy.

Dr. Myhrvold, an avid photographer, first met Dr. Libbrecht more than a decade ago, and in the spring of 2018, he decided he wanted to take pictures of the intricate frozen crystals himself. He recalled thinking, “Oh, we’ll just throw something together, and we’ll be ready for the winter.”

But, as with many of his projects, things were not as simple as Dr. Myhrvold planned.

“It turned out to be massively more complicated than I thought,” Dr. Myhrvold said. “So it took 18 months to build the damn thing.”

The “damn thing” was the camera system for photographing snowflakes. He wanted to use the best digital sensors, ones that captured a million pixels. “The real snowflake is very, very fragile,” he said. “It’s super intricate. So you want high resolution.”

But that kind of sensor is much larger in area than the images generally produced by the lenses of microscopes, a result of decisions that microscope manufacturers made close to a century ago.

That meant he needed to find a way to stretch the microscope image to fill the sensor.

In his tinkering, “I came up with a custom optical path that will actually allow it to work,” he said.

Then there is the housing for the optics. That is typically made of metal, but metal expands when warm and shrinks when cold. Moving the apparatus from the warm indoors to a frigid balcony where he would collect the snowflakes “would screw up the whole microscope,” Dr. Myhrvold said, making it impossible to keep everything in focus.

Instead of metal, he used carbon fiber, which does not appreciably expand or shrink.

Dr. Myhrvold also found a special LED, manufactured by a company in Japan for industrial uses, that would emit bursts of light 1/1,000th as long as a typical camera flash. This minimizes heat emitted from the flash, which might melt the snowflake a bit.

To look at something under a microscope, a specimen is typically placed on a glass slide. But glass retains heat. That also melts the snowflakes. So he switched from glass to sapphire, a material that cools more readily.

By February 2020, he was ready. But where to find the most beautiful snowflakes to photograph? At first, he thought he could just head to a ski resort town — perhaps Aspen or Vail in Colorado or Whistler in British Columbia.

But these places were not cold enough.

“Powder snow that a skier might like to ski through is, in fact, pretty much powder,” Dr. Myhrvold said. “There’s not a lot of beauty in those things.”

Indeed, the snowflakes that fall on most people most of the time are rarely what people think of as snowflake-shaped.

Water is a simple molecule consisting of two hydrogen atoms and one oxygen. When temperatures drop below 32 degrees Fahrenheit, the molecules start sticking to one another — that is, they freeze.

A snowflake is born in a cloud when a water droplet freezes into a tiny ice crystal. The shape of the water molecules causes them to stack together in a hexagonal pattern. That is why the archetypical snowflake has six arms.

Then the crystal grows, absorbing water vapor from the air and other droplets nearby evaporate to replenish the vapor. “It takes maybe 100,000 water droplets evaporating to make one snow crystal,” Dr. Libbrecht said.

But how the crystal grows depends on the temperature and the humidity. In the 1930s, a Japanese physicist, Ukichiro Nakaya, was the first to grow artificial snowflakes in his laboratory, and by varying the conditions, he was able to catalog which types form under most conditions.

When temperatures are just below freezing, the snowflakes are generally simple hexagon plates. At about 20 degrees Fahrenheit, the prevalent shape is hexagonal columns. It is between 15 degrees and -5 degrees Fahrenheit that the archetypically beautiful snowflakes usually form.

At these temperatures, the points of the hexagon grow into branches. The branches then spawn other branches and smaller hexagonal plates. Slight variations in the temperature and humidity affect the growing pattern, and the conditions are constantly changing as the snowflake falls toward the ground.

“Because it has this complicated path through the clouds, it gives a complicated shape,” Dr. Libbrecht said. “They’re all following different paths, and so each one looks a little different, depending on the path.”

Thus, to find the beautiful snowflakes, Dr. Myhrvold went north, much farther north. He and a couple of assistants lugged about a thousand pounds of equipment to Fairbanks, Alaska; Yellowknife, the largest community in the Canadian Northwest Territories; and Timmins, Ontario, about 150 miles north of Lake Huron.

A month later, the coronavirus pandemic put the endeavor on hiatus. But Dr. Myhrvold was able to take what he calls the highest resolution images of snowflakes ever.

That claim has irked others in the snowflake world, including Don Komarechka, a Canadian photographer who takes a decidedly lower tech approach. He uses a store-bought digital camera with a high-power macro lens. He does not even use a tripod — he just holds the camera while the snowflakes sit on a black mitten that his grandmother had given him.

“Incredibly simplistic,” Mr. Komarechka said. “It’s so approachable for anybody with any camera.”

He said of Dr. Myhrvold’s custom-built system: “I think it’s a little over-engineered.”

Mr. Komarechka also takes a different approach to illumination, using light reflected off a snowflake, while Dr. Myhrvold’s images capture light passing through. “You get to see surface texture, and sometimes beautiful rainbow colors in the center of a snowflake,” Mr. Komarechka said.

The rainbow effect is the same as what you see in soap film, but the colors are “often much more solidly displayed than you would see in a soap film or anything else,” he said. “It’s almost psychedelic colors, almost looking like a tie-dye T-shirt.”

To counter Dr. Myhrvold’s claims, Mr. Komarechka took an image that he says was even higher resolution. Dr. Myhrvold responded with a lengthy rebuttal explaining why his images were, nonetheless, more detailed.

In practical terms, Dr. Myhrvold’s images are sharper when printed on paper at expansive sizes. They are available for purchase at sizes up to 2 meters by 1.5 meters.

“In that very narrow sense, yep, that’s what Nathan is claiming, and he’s not wrong,” Dr. Komarechka said.

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Whole Foods will soon let customers pay for groceries with palm scan

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Whole Foods will soon let customers pay for groceries using its parent company’s palm-scanning technology.

Amazon said Wednesday its palm-scanning system — currently used in about a dozen of its brick and mortar stores — will debut at a Whole Foods in Seattle’s Capitol Hill neighborhood, the first of many planned rollouts at other locations.

The system uses Amazon One technology, which employs high-tech imaging and algorithms to create and detect a “unique palm signature” based on the ridges, lines and veins in each person’s hand.

Its high-tech sensors don’t require users to touch the scanning surface, like Apple’s fingerprint technology does.

Instead, palm-reading tech uses computer vision and depth geometry to process and identify the shape and size of each hand they scan before charging a credit card on file.

Amazon One will debut at a Whole Foods in Seattle's Capitol Hill neighborhood, with many rollouts at other locations planned for the future.
Amazon One will debut at a Whole Foods in Seattle’s Capitol Hill neighborhood, with many rollouts at other locations planned for the future.
Shannon Stapleton/Reuters

The company said that the palm-scanning tech will be offered as just one of many payment options at participating Whole Foods Stores and that it won’t impact store employees’ job responsibilities.

“At Whole Foods Market, we’re always looking for new and innovative ways to improve the shopping experience for our customers,” said Arun Rajan, senior vice president of technology and chief technology officer at Whole Foods Market.

Palm images used by Amazon One are encrypted and stored in a “highly secure” cloud, and customers can request to have their palm data deleted.

The company claims palm-scanning tech is more private than other biometric alternatives, such as facial recognition.

Amazon One builds on the “Just Walk Out” technology that Amazon uses in its Go stores, which detects the items shoppers pick up and charges them once they leave — without the need for a checkout line

Amazon is also planning to expand the cashier-less technology to Whole Foods, as reported by The Post.

Meanwhile, the tech could be good for its bottom line. The online behemoth aims to sell its palm-scanning tech to other companies like retailers, stadiums and office buildings.

Amazon One scanner
The scanner uses high-tech imaging and algorithms to create and detect a unique palm signature which is then encrypted and stored in a secured cloud.
Amazon

Last September, it said it was in “active discussions with several potential customers.” But it is unclear if it has progressed on any of those fronts.

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Apple’s new iPad Pros and TV remote don’t have U1 locators to help find them in your couch

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Apple has been quietly sticking special locator beacon chips into some of its new iPhones that’ll let you unlock your car and find lost items through walls — the latter thanks to the $29 AirTags announced today — but sadly, you won’t find that chip in the new M1-based iPad Pros or the long-awaited new Siri remote for the Apple TV.

Apple confirmed to us that the U1 locator chip, which uses pulses of ultra-wideband (UWB) radio to broadcast its precise location, won’t appear in the Siri remote. We’re waiting on final bulletproof confirmation about the iPad Pros, but it also doesn’t appear in their product page, spec sheet, or press release. Last year’s iP ad Pros didn’t include a U1 chip, either.

Is Apple expecting us to stick AirTags to our iPads and TV remotes to escape the jaws of the ever-ravenous couch? Unlikely, but the company has been pretty choosey about which devices get the chip so far. You can find it in the iPhone 11 and newer (but not the iPhone SE) and the Apple Watch Series 6 (but not the Apple Watch SE), but we’re pretty sure it hasn’t made its way to any iPads or MacBooks that have been announced since the chip’s introduction in September 2019.

Theoretically, Apple could build an ecosystem where any Apple device can easily find any other Apple device (not to mention UWB devices from Samsung, which is also deeply invested in the tech and has its own AirTag-like device as well). But for now, you’ll primarily just be using your phone to find AirTags, not other gadgets, except perhaps your future car.

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Your iPhone has a completely hidden app. Here’s how to find and use it

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Apple’s iPhone is full of hidden features and tricks we’re constantly discovering. For instance, did you know the Notes app has a hidden document scanner? Yeah, pretty cool. The latest hidden feature that’s been popping up on Twitter and blogs is another type of scanner, dedicated to QR codes, and it’s better than the one built into the camera app.

Indeed, you would already be able to filter QR codes utilizing the easy route in Control Center, or simply open the camera application and it will check a QR code. Also, you’re correct. Both of those strategies turn out great. However, the committed Code Scanner application accepts the position above and beyond by introducing a greater amount of the data I need to see about an examined code.

For instance, the camera application utilizes a little notice at the highest point of the screen to open a connection or show you data, though the devoted Code Scanner application makes it exceptionally clear what’s inside the QR code you just checked. Yet, here’s the rub: The Code Scanner application isn’t found on your home screen, nor is it found in iOS 14’s new App Library.

As should be obvious, the best way to discover the Code Scanner application is to utilize the iPhone’s Spotlight search include. Go to your iPhone’s home screen and swipe down in the center of the screen. An inquiry bar will show up at the highest point of your screen, alongside application and alternate route ideas underneath. Type either code or scanner. As you type, you’ll see the Code Scanner application symbol appear as an application idea. Tap to open it.

The flashlight icon at the bottom of the screen acts as a flash to illuminate a code if your phone is struggling to read it.

If you don’t have the QR scanner shortcut added to Control Center yet, here’s a post showing you how to customize Control Center to your liking. For more hidden features, check out our list for iOS 14. We also cover more general, but useful features in iOS 14.

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