{"id":387,"date":"2018-12-07T11:18:55","date_gmt":"2018-12-07T11:18:55","guid":{"rendered":"https:\/\/dev.ucomm.ncsu.edu\/web-platform-free-tier\/2018\/12\/07\/how-big-can-snowflakes-be\/"},"modified":"2018-12-07T11:18:55","modified_gmt":"2018-12-07T11:18:55","slug":"how-big-can-snowflakes-be","status":"publish","type":"post","link":"https:\/\/dev.ucomm.ncsu.edu\/web-platform-free-tier\/2018\/12\/07\/how-big-can-snowflakes-be\/","title":{"rendered":"How Big Can Snowflakes Be?"},"content":{"rendered":"

Editor\u2019s Note:<\/strong> This is a guest post by Megan Skrip<\/a>, a science communicator with NC State\u2019s Center for Geospatial Analytics<\/a>.<\/em><\/p>\n

How large can snowflakes get? The answer is: pretty darn big.<\/p>\n

Like many people, I enjoy keeping a page-a-day calendar on my desk and learning tidbits of trivia as I tear each day away. Recently, though, one of these tidbits stopped me cold. It was about the largest snowflake every recorded.<\/p>\n

The Biggest Snowflake Ever<\/strong><\/p>\n

\u201cDid you know,\u201d the calendar read, \u201cthat the largest reported snowflake measured 15 inches (38.1 cm) wide and 8 inches (20.3 cm) thick<\/em>?! It was discovered by a ranch owner in Fort Keogh, Montana, in 1887.\u201d<\/p>\n

No, I did not know that. A 15-inch snowflake? How could a snowflake possibly grow that big? And what would it have looked like?<\/p>\n

Luckily, I knew just who to ask: NC State\u2019s Sandra Yuter<\/a>, faculty fellow at the Center for Geospatial Analytics and a distinguished professor in the university\u2019s Department of Marine, Earth and Atmospheric Sciences<\/a>.<\/p>\n

Yuter uses information from satellites, radar and other sources to answer scientific questions related to weather and climate (her latest discoveries<\/a> about marine clouds were published in Science<\/em><\/a> last summer). She often studies winter storms that cover large geographic areas, but Yuter is also an expert on the snowflakes themselves, and how bizarre they can be.<\/p>\n

Most Snowflakes Don\u2019t Look Like Snowflakes<\/strong><\/p>\n

When we think of snowflakes, most of us envision the symmetrical, lacelike patterns that adorn greeting cards at this time of year. But the vast majority of snowflakes are not so neat and tidy, Yuter says. Most snowflakes are downright lumpy, made up of many individual ice crystals as well as frozen water droplets that resemble fuzzy snowballs.<\/p>\n

\u201cYou rarely get ice crystals that are pristine and perfect,\u201d Yuter says. \u201cAs snowflakes fall at slightly different speeds, one will overtake another and they\u2019ll lump together.\u201d<\/p>\n

For more than five years, Yuter and her collaborators have been studying the shapes of snowflakes in freefall, first in Utah and now in Stony Brook, New York. Using a Multi-Angle Snowflake Camera<\/a> (MASC), they have captured some stunning images<\/a>.<\/p>\n

One goal of the work is to better understand the inner workings of snow storms\u2013\u2013from the tops of the clouds to the ground\u2013\u2013and improve forecasts of local snowfall.<\/p>\n

What do snowflake shapes have to do with it? Snowflakes\u2019 shapes record what was happening in the clouds where they formed, because different temperature and moisture conditions affect the way snowflakes look and grow.<\/p>\n

\u201cSnowflakes are little histories of what they\u2019ve been through,\u201d Yuter explains.<\/p>\n

How Do Snowflakes Form?<\/strong><\/p>\n

Snowflakes form when water molecules in a cloud pass directly from water vapor gas to solid ice, skipping over the liquid phase to form an ice crystal.<\/p>\n

As these ice crystals fall and swirl through the clouds that formed them, they form larger flakes by continuing to grow, clumping together, gathering freezing water droplets, or all of the above. Water droplets that freeze on contact with an ice crystal create tiny snowball particles. And when multiple snow crystals clump together into a jumble, the snow particles they form are known in meteorological circles as aggregates.<\/p>\n

The largest falling aggregate snowflakes Yuter has photographed have been about 1.5 inches (about 4 cm) across (see photo above); that\u2019s partially due to the size limit of the MASC but also due to large flakes\u2019 rarity and difficulty to measure.<\/p>\n

How Big Can Snowflakes Get?<\/strong><\/p>\n

There\u2019s really no telling how large an aggregate snowflake might get while still airborne.<\/p>\n

\u201cWe don\u2019t know how big they can grow within the snow storm,\u201d Yuter says, \u201cbecause wind conditions typically conspire against giant flakes ever reaching the ground intact.\u201d<\/p>\n

The jumble of crystals that make up an aggregate snowflake tend to be only loosely connected, and the overall structure is consequently very fragile. Wind or other air turbulence can easily break the delicate aggregate into smaller pieces on its way to the ground.<\/p>\n

That means that the record-setting flake of 1887 \u2013 the one that was considerably larger than a football — would have needed to fall in very calm wind, or no wind at all. In addition, the moisture in the air would have needed to be quite high, to allow the flake to gather a plethora of ice crystals and frozen water droplets on its journey down to the ground. That enormous snowflake would also have looked very different from the ones we usually imagine. There is no photographic evidence for the giant flake, but Yuter says that if it existed, it was probably a variation of what she has observed in her own work: a very lumpy aggregate. It might be tempting to envision a perfectly symmetrical giant snowflake, but the reality is much more interesting.<\/p>\n

\u201cWhat do big snowflakes look like? A jumble of little flakes,\u201d Yuter explains. \u201cIn natural conditions, it is highly unlikely that the record snowflake from 1887 was one giant crystal. Much more likely is that it was a jumble of crystals together.\u201d To date, she has collected images of over two million snowflakes, many like the photo above. \u201cThis,\u201d she says, \u201cis what real snow looks like.\u201d<\/p>\n

Let it snow!<\/p>\n

This post was originally published<\/a> in NC State News.<\/em><\/p>","protected":false,"raw":"Editor\u2019s Note:<\/strong> This is a guest post by Megan Skrip<\/a>, a science communicator with NC State\u2019s Center for Geospatial Analytics<\/a>.<\/em>\r\n\r\nHow large can snowflakes get? The answer is: pretty darn big.\r\n\r\nLike many people, I enjoy keeping a page-a-day calendar on my desk and learning tidbits of trivia as I tear each day away. Recently, though, one of these tidbits stopped me cold. It was about the largest snowflake every recorded.\r\n\r\nThe Biggest Snowflake Ever<\/strong>\r\n\r\n\u201cDid you know,\u201d the calendar read, \u201cthat the largest reported snowflake measured 15 inches (38.1 cm) wide and 8 inches (20.3 cm) thick<\/em>?! It was discovered by a ranch owner in Fort Keogh, Montana, in 1887.\u201d\r\n\r\nNo, I did not know that. A 15-inch snowflake? How could a snowflake possibly grow that big? And what would it have looked like?\r\n\r\nLuckily, I knew just who to ask: NC State\u2019s Sandra Yuter<\/a>, faculty fellow at the Center for Geospatial Analytics and a distinguished professor in the university\u2019s Department of Marine, Earth and Atmospheric Sciences<\/a>.\r\n\r\nYuter uses information from satellites, radar and other sources to answer scientific questions related to weather and climate (her latest discoveries<\/a> about marine clouds were published in Science<\/em><\/a> last summer). She often studies winter storms that cover large geographic areas, but Yuter is also an expert on the snowflakes themselves, and how bizarre they can be.\r\n\r\nMost Snowflakes Don\u2019t Look Like Snowflakes<\/strong>\r\n\r\nWhen we think of snowflakes, most of us envision the symmetrical, lacelike patterns that adorn greeting cards at this time of year. But the vast majority of snowflakes are not so neat and tidy, Yuter says. Most snowflakes are downright lumpy, made up of many individual ice crystals as well as frozen water droplets that resemble fuzzy snowballs.\r\n\r\n\u201cYou rarely get ice crystals that are pristine and perfect,\u201d Yuter says. \u201cAs snowflakes fall at slightly different speeds, one will overtake another and they\u2019ll lump together.\u201d\r\n\r\nFor more than five years, Yuter and her collaborators have been studying the shapes of snowflakes in freefall, first in Utah and now in Stony Brook, New York. Using a Multi-Angle Snowflake Camera<\/a> (MASC), they have captured some stunning images<\/a>.\r\n\r\nOne goal of the work is to better understand the inner workings of snow storms\u2013\u2013from the tops of the clouds to the ground\u2013\u2013and improve forecasts of local snowfall.\r\n\r\nWhat do snowflake shapes have to do with it? Snowflakes\u2019 shapes record what was happening in the clouds where they formed, because different temperature and moisture conditions affect the way snowflakes look and grow.\r\n\r\n\u201cSnowflakes are little histories of what they\u2019ve been through,\u201d Yuter explains.\r\n\r\nHow Do Snowflakes Form?<\/strong>\r\n\r\nSnowflakes form when water molecules in a cloud pass directly from water vapor gas to solid ice, skipping over the liquid phase to form an ice crystal.\r\n\r\nAs these ice crystals fall and swirl through the clouds that formed them, they form larger flakes by continuing to grow, clumping together, gathering freezing water droplets, or all of the above. Water droplets that freeze on contact with an ice crystal create tiny snowball particles. And when multiple snow crystals clump together into a jumble, the snow particles they form are known in meteorological circles as aggregates.\r\n\r\nThe largest falling aggregate snowflakes Yuter has photographed have been about 1.5 inches (about 4 cm) across (see photo above); that\u2019s partially due to the size limit of the MASC but also due to large flakes\u2019 rarity and difficulty to measure.\r\n\r\nHow Big Can Snowflakes Get?<\/strong>\r\n\r\nThere\u2019s really no telling how large an aggregate snowflake might get while still airborne.\r\n\r\n\u201cWe don\u2019t know how big they can grow within the snow storm,\u201d Yuter says, \u201cbecause wind conditions typically conspire against giant flakes ever reaching the ground intact.\u201d\r\n\r\nThe jumble of crystals that make up an aggregate snowflake tend to be only loosely connected, and the overall structure is consequently very fragile. Wind or other air turbulence can easily break the delicate aggregate into smaller pieces on its way to the ground.\r\n\r\nThat means that the record-setting flake of 1887 \u2013 the one that was considerably larger than a football -- would have needed to fall in very calm wind, or no wind at all. In addition, the moisture in the air would have needed to be quite high, to allow the flake to gather a plethora of ice crystals and frozen water droplets on its journey down to the ground. That enormous snowflake would also have looked very different from the ones we usually imagine. There is no photographic evidence for the giant flake, but Yuter says that if it existed, it was probably a variation of what she has observed in her own work: a very lumpy aggregate. It might be tempting to envision a perfectly symmetrical giant snowflake, but the reality is much more interesting.\r\n\r\n\u201cWhat do big snowflakes look like? A jumble of little flakes,\u201d Yuter explains. \u201cIn natural conditions, it is highly unlikely that the record snowflake from 1887 was one giant crystal. Much more likely is that it was a jumble of crystals together.\u201d To date, she has collected images of over two million snowflakes, many like the photo above. \u201cThis,\u201d she says, \u201cis what real snow looks like.\u201d\r\n\r\nLet it snow!"},"excerpt":{"rendered":"

Snowflakes can get pretty darn big.<\/p>\n","protected":false},"author":4,"featured_media":388,"comment_status":"open","ping_status":"open","sticky":false,"template":"","format":"standard","meta":{"_acf_changed":false,"source":"ncstate_wire","ncst_dynamicHeaderBlockName":"","ncst_dynamicHeaderData":"","ncst_content_audit_freq":"","ncst_content_audit_date":"","ncst_content_audit_display":false,"ncst_backToTopFlag":"","footnotes":""},"categories":[1],"tags":[5],"class_list":["post-387","post","type-post","status-publish","format-standard","has-post-thumbnail","hentry","category-uncategorized","tag-_from-newswire-collection-6"],"displayCategory":null,"acf":[],"_links":{"self":[{"href":"https:\/\/dev.ucomm.ncsu.edu\/web-platform-free-tier\/wp-json\/wp\/v2\/posts\/387","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/dev.ucomm.ncsu.edu\/web-platform-free-tier\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/dev.ucomm.ncsu.edu\/web-platform-free-tier\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/dev.ucomm.ncsu.edu\/web-platform-free-tier\/wp-json\/wp\/v2\/users\/4"}],"replies":[{"embeddable":true,"href":"https:\/\/dev.ucomm.ncsu.edu\/web-platform-free-tier\/wp-json\/wp\/v2\/comments?post=387"}],"version-history":[{"count":0,"href":"https:\/\/dev.ucomm.ncsu.edu\/web-platform-free-tier\/wp-json\/wp\/v2\/posts\/387\/revisions"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/dev.ucomm.ncsu.edu\/web-platform-free-tier\/wp-json\/wp\/v2\/media\/388"}],"wp:attachment":[{"href":"https:\/\/dev.ucomm.ncsu.edu\/web-platform-free-tier\/wp-json\/wp\/v2\/media?parent=387"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/dev.ucomm.ncsu.edu\/web-platform-free-tier\/wp-json\/wp\/v2\/categories?post=387"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/dev.ucomm.ncsu.edu\/web-platform-free-tier\/wp-json\/wp\/v2\/tags?post=387"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}