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2022-08-15 14:34:28.000 – Naomi Lubkin, Summit Intern

Summit Intern Naomi Lubkin on the observation deck.

My first shift at the Observatory was a cold, clear day back in May, and what I remember most was the feeling of excitement and uncertainty. I truly had no idea what I was getting myself into, but I knew I was ready to learn, work, and live on the highest summit in the northeast.

Having grown up just a little ways down the road in Bartlett, NH, I’ve always been familiar with Mount Washington. Part of my fourth grade curriculum was learning about the history of the mountain, and my daily commute to high school included passing the Intervale Scenic Vista and catching a glimpse of the often snow-capped peak.

I’m about to head into my fourth year at the University of British Columbia, where I study biology with a specialization in marine biology. All summer, whenever I tell people I study biology, I’m invariably asked: “So… why the Observatory?”

The answer, at least to me, is obvious. While biology and meteorology may seem completely unrelated at first glance, if you look further you’ll start seeing connections. An example is one of my favorite places in the world: the intertidal zone. This is the incredibly biodiverse area where the land meets the sea; at high tides, it’s covered by water, and at low tides, it’s dry and exposed to the elements.

Intertidal organisms, many of which are glued to the rock and can’t move with the water, have developed some really cool adaptations to survive these changing conditions. For example, the seaweed Ulva fenestrata (also known as sea lettuce) can completely dry out at low tides, and then when the tide comes back in will rehydrate without missing a beat. Giant green anemones will curl in on themselves and stick bits of broken shells to their bodies to conserve moisture and avoid damaging UV rays.

For me, understanding large scale climate trends sheds light on why organisms need the adaptations they have. The upper limit of how high on the shore organisms can survive is often determined by how much extreme weather they can handle. (Remember, “extreme” means different things to you than it does to an anemone!)

A tide pool near Bamfield, BC, Canada, showing the biodiversity of intertidal life. Ulva fenestrata is the grass-green seaweed. Giant green anemones, some with shell fragments stuck to them, are visible in the middle of the image.

Beyond this, my interest in more fine-scale weather has been solidified by my time studying in Vancouver. In the city, which is sometimes referred to as “Raincouver,” it’s rare to see the sun in winter. During these bleak, gray months I’ve found myself obsessively checking the forecast for when we may get a window of clear skies. This naturally morphed into an interest in what is driving those systems and a desire to more meaningfully understand how the weather works.

This desire, as well as my love of the White Mountains, led me to the Observatory. As my time here draws to a close, I can say with certainty that it’s been a summer I won’t forget. Life at the summit has been as interesting and variable as the weather. I’ve experienced my fair share of cool and extreme weather, I’ve had the opportunity to learn from and work closely with extremely knowledgeable people, and I’ve also had a lot of fun.

Highlights of the summer include waking up at 2:30 am to see the Northern Lights, struggling to walk in a 94 mph gust, trying to win over summit cat Nimbus, chatting with co-workers at our family style dinners every night, and many foggy hikes to and from Lakes of the Clouds Hut. As my last week at the Observatory draws to a close, I’ve been thinking back to that first week; I’ve learned so much between then and now, and I’m really grateful for my time at the Obs.

The Northern Lights visible from the summit on July 4, 2022.

In addition to various summit operation tasks, giving weather station tours, shadowing observations, and learning to write mountain forecasts, much of my time on the summit has been spent on a research project. Alongside Appalachian Mountain Club Intern Larz von Huene, I am updating the long-term wind and humidity trends on Mount Washington and exploring what impacts these trends may have on alpine tree lines.

The upper elevation at which trees can grow in the White Mountains is limited by conditions like wind and moisture, so by examining long term trends in wind and humidity, we can hopefully understand better how tree line may be shifting over time and implications for alpine ecosystems.

You may have noticed that there are a few parallels between the intertidal zone I was talking about earlier and tree line on Mount Washington. Mainly, in both environments, upper limits are determined by species’ ability to survive harsh conditions. On Mount Washington, these conditions just happen to be extreme wind and ice instead of the heat and bright sunlight that challenge intertidal organisms. This project is a clear example of the intersection between meteorology and biology, and how understanding weather and climate trends is an essential part of understanding ecosystems. It’s been really rewarding for me to bring a biological perspective to this weather-oriented project.

Naomi Lubkin, left, and Larz von Huene are shown around tree line on Mount Washington this summer.

To hear more about our research project, as well as the research project conducted by fellow MWOBS Intern Henry Moskovitz, join us for the Science in the Mountains™ virtual lecture on Tuesday, August 16th at 7pm. Click here for more information and to register for the Zoom session.

Naomi Lubkin, Summit Intern

A Night in the Life of a Weather Observer

By Charlie Buterbaugh | March 15, 2022

Staff Meteorologist Ryan Knapp sets an anemometer on the observation tower.

Well over a mile above the valley of Mount Washington, in a weather station built into boulders deposited tens of thousands of years ago, a night observer keeps track of data through the night, maintaining one of North America’s longest continuous alpine climate records.

He is mainly focused on the minutes, completing observations between 00:49 and 00:59 past every hour. Routine and process rule the night, but no two nights make the same weather. The consistency of process, timing, and location assure continuation of a 90-year data set. Weather presents a far less reliable dimension, especially on Mount Washington, where cycles are shaped by cold fronts, warm fronts, and extreme conditions that arrive as they please.

It’s 5:30 p.m. on a mid-November Tuesday evening, and Staff Meteorologist Ryan Knapp seems accustomed to darkness, keeping the weather room dimly lit. He relieves the two day observers whose work started 12 hours ago. The transition between staff is critical. They compare notes about current conditions and forward-looking models.

“If you don’t write something down, it could quickly become too little too late,” says Knapp. “Weather systems could be arriving hours ahead of what the models are saying.”

His running analysis combines real-time observations at the summit with data charts and weather maps displayed on multiple screens. Tonight, a low-pressure system approaching from the northwest pushes dry air like a bulldozer, creating pockets between moist layers.

The meteorologist checks data quality, verifying figures entered during the prior day to keep a clean baseline. In addition to the nightly checks, the team circles back to assure quality each morning, then again every five days, and once more at the end of the month.

“That’s what goes into our 90-year record,” says Knapp, referring to the monthly review.

Before the next ob, we head downstairs for dinner in the crew’s living quarters. Seated at a long table, eating sautéed vegetables and pizzas charred by a commercial gas range, the three meteorologists and one intern debate whether the approaching cold front will bring freezing rain, sleet, or snow. Nimbus, the observatory’s gray shorthair cat named after clouds that bring precipitation, makes his presence known.

After dinner, the crew scrubs and vacuums the entire quarters, including kitchen, pantry, bathroom, bunk rooms, and living room. They’re tired but in high spirits. Snow is in the forecast. And their off week starts tomorrow after they welcome the alternating crew of observers and travel down the mountain, this time of year by pickup truck on the auto road. If the snow is deep, they’ll stop to put chains on the tires. In the back of their minds, they know the whole trip could be delayed by dense fog or high winds above tree line.

Knapp’s short dinner break ends and he heads back up to the weather room. Except for my questions, he is alone once again for a nocturnal routine he has kept for 16 years.

Just after 7:45, he gears up briskly and ascends the observation tower, opens the door beneath an A-frame protecting against chunks of rime that fly when winds accelerate, and steps onto the vast observation deck, walking in darkness to the north end. He counts two layers of clouds below and three aloft.

The meteorologist heads to the designated spot for measuring ambient air temperature, turns his headlamp on, and spins the sling psychrometer, a low-tech instrument that’s reliable in a variety of extreme conditions. This manual weather observation process has been happening the same way, every hour, since 1932. With side-by-side dry-bulb and wet-bulb thermometers, measurements are used to calculate dew point and relative humidity, the amount of water vapor in the air.

During the next ob, he climbs three flights of stairs and ladders to the top of the observation tower, perched in darkness above anywhere attached to earth in the northeastern U.S. He checks the heated anemometers and, if needed, removes ice that accumulates fast as winds accelerate and temperatures plummet. Tonight, it’s only hovering around freezing with winds gusting at 50 mph.

Heading inside, he closes the hatch at the top of the tower, quieting the west winds blowing out of the chasm of the Ammonoosuc Ravine against Mount Washington’s windward flank, and again returns to the weather room to log data, check radar, and perform other tasks until he heads outside again regardless of the weather, repeating this routine through the night.

Asked if the work ever gets monotonous, he says no. The weather is ever-changing, and knowing his work continues the 90-year data set steels his sense of purpose.

“It’s almost like having the mountain to myself,” he says. “I only have to worry about the weather.”

Data is inputted after every hourly observation through the night.

A playlist and mug of coffee also keep him going. He responds to a question on MWOBS’ Facebook page about yesterday’s photo of a cap cloud that formed over the summit. Knapp doubles as the observatory’s photo administrator, and his summit photography has attracted a colossal following.

He’s known at the summit for rating sunrises on a scale of one to ten. A three on his scale is likely an eight or nine on ours.

But from now until early March, he’ll go to sleep before sunrise, missing the morning blue hour.

It’s approaching 1:00 a.m. and the meteorologist starts a synoptic observation, a six-hour detailed snapshot of conditions. He records maximum and minimum temperature, atmospheric pressure tendency, and precipitation types and totals. This all gets delivered to the National Weather Service. Being prompt matters. The synoptic data feeds weather models that Mount Washington’s observers and many other meteorologists rely on for accurate forecasting.

The complexity of his work increases after the 1:00 synoptic. He starts to work on the daily mountain forecasts between 2:00 and 3:00, staying keenly aware of the observatory’s backcountry audience. The Mount Washington and Higher Summits forecasts need to be posted on mountwashington.org before 5:00 a.m. The weather is always changing and the stakes are high. Search and rescue teams, climbing guides, and others rely on MWOBS’ forecasting accuracy, helping them decide when to head out, how to modify plans, or to postpone.

After a few hours of sleep in one of the cozy wood-paneled bunk rooms, I head back to the weather room and overhear Knapp recording his voice for the audio forecast. Falling snow is starting to accumulate at 5:15 when Weather Observer Sam Robinson arrives in the weather room to start his day. He fields a round of probing, collegial questions from Knapp about data points entered the previous day. It’s all part of keeping the record straight.

Knapp and Robinson stay composed as ever. With winds on the increase and a snow storm in process, care will be needed on this shift change day as the next crew makes their way to the alpine zone for another challenging week at the weather station.

Knapp reads in an observatory bunk room after completing his nightly shift.

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About the Author

Charlie Buterbaugh is the Director of Communications at Mount Washington Observatory.

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August 2022

A Marine Biologist in the Mountains

A Marine Biologist in the Mountains

March 2022

A Night in the Life of a Weather Observer

A Night in the Life of a Weather Observer

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