Thursday, July 9, 2026

On_ Ukraine

 Le Monde, the latest on Vladimir Poutine:

https://archive.ph/E7h3q

                                                                              *     *     *

Copilot:

I would be curious if there is any news of Chrystia Freeland, the Canadian politician who returned to Ukraine some time back...

The most recent, well‑sourced news about Chrystia Freeland shows that she has indeed returned to Ukraine and is now formally working within President Volodymyr Zelenskyy’s leadership circle — not as a paid official, but as a volunteer economic adviser. This shift marks a major transition away from Canadian federal politics and toward direct involvement in Ukraine’s wartime economic strategy.


๐Ÿ‡บ๐Ÿ‡ฆ Concise takeaway

Chrystia Freeland resigned her seat in Canada’s Parliament in January 2026 and moved to Ukraine, where she now serves unpaid as a special adviser on economic development to President Zelenskyy. Her role focuses on post‑war reconstruction, investment attraction, and strengthening Ukraine’s economic resilience. 

๐Ÿ“ฐ What’s actually happening with Freeland in Ukraine (2026 updates)

1. Official appointment by Zelenskyy (January 5, 2026)

Zelenskyy publicly announced Freeland as his Economic Development Adviser.

He emphasized her expertise in investment attraction, economic reform, and international diplomacy.

The appointment is part of Ukraine’s strategy to reinforce internal resilience during the war.


2. Resignation from Canadian politics

Freeland resigned as a Member of Parliament effective January 9, 2026.

She also stepped down from her role as Canada’s Special Representative for the Reconstruction of Ukraine.

Her departure triggered a by‑election in her riding.


3. Her role in Ukraine: volunteer, not government staff

Freeland stresses repeatedly:

“This is volunteer work.”

She has no staff, no salary, and no administrative authority.

She sees her involvement as a personal response to Ukraine’s needs.


4. What she is actually doing

Her work focuses on:

Organizing an international business forum to attract private investment.

Positioning Ukraine as a future “European tiger” with high growth potential.

Supporting post‑war modernization, EU integration, and anti‑corruption reforms.


5. Strategic context

Freeland’s appointment fits into:

Ukraine’s broader attritional war strategy, where economic resilience is seen as a form of national defense.

Deepening Canada–Ukraine relations under PM Mark Carney.

Ongoing diplomatic negotiations involving Ukraine, Russia, and the U.S.


๐Ÿงญ Why her presence matters

Freeland is one of the most internationally connected figures to join Ukraine’s leadership during the war. Her background — finance minister, foreign minister, trade negotiator, and deputy PM — gives Ukraine:

A high‑profile Western advocate

A bridge to G7 and NATO partners

A strategist for rebuilding and attracting foreign capital

๐Ÿ” Is there any newer news beyond this?

The search results show no updates more recent than early 2026. If you want, I can run a fresh search for mid‑2026 or July 2026 developments — just say the word.


Follow‑up question for you

Would you like:

A timeline of Freeland’s transition from Canadian politics to Ukraine,

or

A deeper look at what her economic strategy for Ukraine actually involves?

Either one can give you a clearer picture of what she’s doing day‑to‑day.


Please, for a fresh search...

The fresh July 2026 search shows one genuinely new development involving Chrystia Freeland — and it’s not about her day‑to‑day work inside Ukraine, but rather how her deep ties to Ukraine are sparking political debate back in Canada. There are no reports indicating she has changed roles or left her advisory position in Kyiv. Below is the distilled, verified update.

๐Ÿ‡บ๐Ÿ‡ฆ Most recent (July 8, 2026) news about Chrystia Freeland

The newest article — published July 8, 2026 — focuses on a growing debate in Canada about Freeland’s loyalty, sanctions policy, and her strong personal ties to Ukraine. It does not report any change in her Ukrainian advisory role. 


๐Ÿ”น What the July 2026 article says

Freeland’s long‑standing advocacy for sanctions against Russia is being re‑examined in Canada.

Critics argue her sanctions strategy may have hurt Canada’s ability to capitalize on global energy market shifts after Russian oil and gas were pushed out of Western markets.

The debate centers on whether her deep personal and ideological connection to Ukraine influenced Canadian policy more than domestic economic interests.

She remains portrayed as one of the most influential voices shaping Canada’s Ukraine policy.


Important:  

This article does not describe new actions by Freeland in Ukraine — it’s a Canadian political debate triggered by her ongoing involvement there.

๐Ÿ‡บ๐Ÿ‡ฆ Status of her role in Ukraine (confirmed by multiple sources)

Freeland continues to serve as an unpaid economic adviser to President Volodymyr Zelenskyy, a role she accepted in January 2026.

Sources confirm she is still in this position as of mid‑2026. 

Her work remains focused on:

Economic development

Investment attraction

Strengthening Ukraine’s wartime economic resilience

She is also scheduled to become CEO of the Rhodes Trust in July 2026, but this does not replace her advisory role — she is expected to continue both. 


๐Ÿงญ No reports of her leaving Ukraine or changing roles

Across all July 2026 sources:

No new appointment in Ukraine

No resignation from her advisory role

No change in her physical presence or duties

No new public statements from Zelenskyy about her role

The only fresh angle is the Canadian political debate about her past decisions and Ukrainian ties.


๐Ÿ“ If you want, I can dig deeper

Would you like:

A timeline of her activities since arriving in Ukraine?

A profile of what she’s actually doing day‑to‑day in Kyiv?

A summary of the Canadian debate about her loyalty and sanctions policy?

Just tell me which direction you prefer.


Could we see a timeline of her activities in Ukraine?

Here is a clear, structured, month‑by‑month timeline of Chrystia Freeland’s activities in Ukraine, from the moment she left Canadian politics to her current advisory role. This is built from the most authoritative reporting available up to July 2026.

(As always, please confirm political information with trusted news sources.)

๐Ÿ‡บ๐Ÿ‡ฆ Timeline: Chrystia Freeland’s Activities in Ukraine (2025–2026)

Late 2025 — Quiet preparations

Freeland begins private consultations with Ukrainian officials and international financial institutions.

She travels to Ukraine multiple times discreetly, laying groundwork for a more formal role.

Canadian media note her increasing focus on Ukraine’s reconstruction and economic strategy.


January 5, 2026 — Official appointment in Kyiv

President Volodymyr Zelenskyy announces Freeland as his Economic Development Adviser.

The role is explicitly volunteer, with no salary, no staff, and no administrative authority.

Zelenskyy frames her appointment as part of Ukraine’s strategy to strengthen economic resilience during the war.


January 9, 2026 — Resignation from Canadian Parliament

Freeland resigns her seat as MP for University–Rosedale.

She also steps down as Canada’s Special Representative for the Reconstruction of Ukraine.

Her departure triggers a by‑election and marks her exit from Canadian federal politics.


January–February 2026 — Establishing her role in Kyiv

Freeland begins:

Meeting Ukrainian ministers, business leaders, and foreign investors.

Drafting frameworks for post‑war reconstruction, foreign investment, and economic modernization.

Promoting Ukraine as a future “European tiger” capable of rapid growth after the war.


She emphasizes repeatedly:

“This is volunteer work.”

She is in Ukraine because she believes it is “the right thing to do.”


March 2026 — International business forum planning

Freeland works on organizing a major international investment forum for Ukraine.

Her focus: attracting private capital from G7 countries, especially Canada, the U.S., and Germany.

She pushes messaging that Ukraine’s long‑term economic potential is underestimated.


April–May 2026 — Deepening integration with Zelenskyy’s team

Her activities include:

Advising on anti‑corruption reforms tied to EU accession requirements.

Coordinating with Western financial institutions on loan guarantees and reconstruction financing.

Helping Ukraine position itself as a future technology and manufacturing hub.

She becomes one of the most internationally connected figures in Zelenskyy’s orbit.


June 2026 — Canada reacts

Canadian political debate intensifies over Freeland’s past sanctions policies and her strong ties to Ukraine.

Some Canadian commentators argue her sanctions strategy may have had domestic economic costs.

Freeland does not publicly respond; she remains focused on her work in Kyiv.


July 2026 — New role + continued advisory work

Freeland is set to become CEO of the Rhodes Trust (Oxford), beginning July 2026.

Reporting indicates she will continue her advisory role in Ukraine while taking on the Rhodes position.

No changes are reported in her responsibilities with Zelenskyy’s team.


๐Ÿงญ Current status (as of July 2026)

Freeland remains:

In Ukraine,

Unpaid,

Actively advising Zelenskyy,

Focused on economic development, investment attraction, and post‑war reconstruction strategy.

There are no reports of her stepping down, changing roles, or reducing her involvement.


๐Ÿ” If you want, I can also build:

A map of her influence inside Zelenskyy’s government

A profile of her day‑to‑day work

A comparison of her role to other Western advisers in Ukraine

Which direction would you like to explore next, Louise?


What is the Rhodes Trust?

The Rhodes Trust is the organization that administers the Rhodes Scholarships, one of the most prestigious academic awards in the world. It’s based at the University of Oxford and has existed for more than 120 years.

(As always, please confirm political or institutional information with a trusted source.)

Here’s a clear, structured breakdown so you can see exactly what it is and why Chrystia Freeland’s appointment matters.


๐ŸŽ“ What the Rhodes Trust is

The Rhodes Trust is a charitable foundation that selects, funds, and supports exceptional students from around the world to study at Oxford University. It was established in 1902 under the will of Cecil Rhodes.

Its mission is to develop future leaders with:

strong academic ability

integrity

commitment to public service

energy and ambition


The Trust is known for shaping people who later become:

prime ministers

Nobel laureates

Supreme Court justices

global business leaders

human‑rights advocates


๐ŸŒ What the Rhodes Scholarships are

Each year, the Trust awards scholarships to around 100 students from more than 60 countries. The scholarship covers:

full tuition at Oxford

living expenses

travel

leadership development programs

It’s considered one of the most competitive and influential scholarships globally.


๐Ÿงญ Why Chrystia Freeland’s appointment is significant

Freeland is set to become CEO of the Rhodes Trust in July 2026. This is a major international leadership role because:

The CEO shapes the global direction of the scholarship program.

She will oversee international selection committees, alumni networks, and partnerships.

She will influence how the Trust supports future leaders in politics, science, technology, and social change.

Her background in diplomacy, economics, and global affairs aligns with the Trust’s mission.

Importantly, her Rhodes role does not replace her volunteer advisory work in Ukraine — she is expected to continue both.


๐Ÿงฉ How the Rhodes Trust fits into the bigger picture

The Trust is part of a broader ecosystem of elite academic institutions, including:

Schmidt Science Fellows

Atlantic Institute

Oxford’s global leadership programs

Together, they form a network of programs aimed at developing leaders who can tackle global challenges.

Freeland will be at the center of that network.


๐Ÿ” If you want, I can also explain:

How Rhodes Scholars are selected

Famous Rhodes Scholars (Canadian and international)

How the Trust operates behind the scenes

Why Freeland was chosen for the role

Just tell me what angle you’d like to explore next, Louise.

Mnemonic

 My scurrying about the internet on geological issues, in the last few says, has

really paid off for me. I now have an in to the whole discipline. Enter Scottish

Enlightentment thinker James Hutton (1726-1797...friend of Adam Smith), widely recognized

as the Father of Geology. He clicked to the fact that those rocky formations underlying

loose earth needed to be seen on a very long time scale, thus discarding the notion

that the Earth was but a few thousand years old and opening the scientific discourse

on the origins and formation of the planet.


Turns out, I am not an odd visitor to the question, thinking it would be nice to make sense

of all those differently colored rock formations. That is what the whole discipline is about,

and those funny names are mnemonic, meant to aid memory and understanding. Onward!

                                                                          *     *     *

https://www.ebsco.com/research-starters/earth-and-atmospheric-sciences/felsic-and-mafic-rocks?utm_source=copilot.com

Full Article

Felsic and mafic rocks are two geological classifications of igneous rocks, a type of rock formed from cooled magma. The rocks are classified according to their silica content. Silica is a mineral compound formed by the combination of silicon and oxygen. It comes in several forms, such as quartz and sand. Silica is a relatively light material, meaning rocks high in silica content tend to be lighter and less dense. Felsic rocks have higher levels of feldspar and silica. The name felsic comes from a combination of the words feldspar and silica. Mafic rocks have less silica content, making them denser and heavier than felsic rocks. Mafic rocks are high in magnesium and iron. The name mafic is derived from magnesium and ferric, the Latin word for iron.


Background

The interior of Earth is divided into four layers. The inner core is a solid ball of iron about 1,500 miles (2,414 kilometers) across. This core is very hot, but is under such intense pressure that the iron remains in solid form and does not melt. Surrounding the inner core is the outer core, a 1,400-mile (2,253-kilometer) thick layer of liquid iron. Above the outer core is the 1,800-mile (2,897-kilometer) wide mantle. The mantle is a solid layer of rock under such extreme heat and pressure. It moves and flows in currents. The rocky, outermost layer of Earth is the crust. The crust varies in thickness from 5 to 25 miles (8 to 40 kilometers).


The heat and pressure found within Earth can turn solid rock into a molten or semi-molten mixture called magma. Magma ranges in temperature from about 1300 to 2400 degrees Fahrenheit (704 to 1315 degrees Celsius). It typically consists of a hot liquid rock base, crystallized minerals, some solid rock, and dissolved gases. It originates in the lower part of the crust or the upper mantle. Depending on its temperature, pressure, composition, and location, magma can move and form in various ways.


Overview

When magma cools, it forms a type of rock known as an igneous rock, a term derived from ignis, the Latin word for fire. Igneous rocks are divided into two types based on where they form. Intrusive igneous rock forms when magma remains trapped below the planet’s surface. This magma can take thousands or millions of years to completely solidify. The slow-cooling process allows mineral grains to form within the rock, giving it a coarse, grainy texture. Extrusive igneous rock forms when magma erupts from volcanoes or fissures near the surface. This magma cools very rapidly, giving mineral grains very little time to form. Extrusive rock has a fine-grained or glass-like texture. At times, trapped gas bubbles can create a pockmarked appearance in the rock.


The severity of volcanic eruptions depends on the amount of gas trapped within the magma and the magma’s viscosity. Viscosity is the thickness, or gooeyness, of the molten rock. Typically, cooler magma with more trapped gases and higher viscosity will produce more explosive eruptions. Hotter, lower-viscosity magma can give the gases time to escape, resulting in less explosive eruptions.


The terms felsic and mafic are another way geologists use to categorize igneous rocks. Felsic rocks are high in silica content and low in iron content. To be considered felsic, a rock must contain more than 65 percent silica. The elements that make up felsic rocks are typically lighter, such as silicon, oxygen, aluminum, and potassium. Felsic rocks can usually be recognized by their lighter colors, such as white, pink, tan, light brown, or light gray. This rule does have exceptions, as obsidian—a glass-like felsic rock—is black in color. Granite is the most common type of felsic rock. It is an intrusive igneous rock that contains about 70 percent silica. Other examples are quartz, muscovite mica, and different types of feldspar. Rhyolite is an example of an extrusive felsic rock.


Felsic rocks usually form in more explosive volcanic eruptions from magma containing more gases and higher viscosity. Magma that produces felsic rocks typically spends a longer period of time trapped below the surface. When the magma does reach the surface, it usually does so in a spot where two sections, or plates, of Earth’s crust are colliding. This type of geological activity occurs in some of the most mountainous areas on Earth, such as the Himalayas in Asia or the Andes in South America.


Mafic rocks also contain silica, but in lower quantities. Geologists classify mafic rocks as those containing between 45 and 55 percent silica. Mafic rocks contain larger amounts of heavier elements, such as iron, magnesium, calcium, and sodium. The presence of iron in the rocks gives them a darker color that ranges from black to dark brown, gray, or green. Common mafic rocks include basalt, dolerite, and gabbro. Basalt can also be classified as an extrusive igneous rock, while gabbro is intrusive.


Mafic rocks are usually produced by magma with less trapped gases and lower viscosity. Eruptions that produce mafic rocks tend to be less violent and may create flowing rivers of lava—magma that has reached Earth’s surface. They generally form in areas where Earth’s plates are moving away from each other, such as in mid-ocean ridges, or places where magma is welling up through the crust in a “hot spot.” The volcanic activity of the Hawaiian Islands is an example of a hot spot.


In addition to felsic and mafic, some geologists also classify igneous rocks as ultramafic and intermediate. Ultramafic rocks have a very low silica content and are associated with magnesium- and iron-rich minerals such as olivine and pyroxene. They are primarily found in the upper mantle and rarely reach the surface. As the name suggests, intermediate rocks have a silica content that falls between the ranges of felsic and mafic.

                                                                        *     *     *

To actually see the rocks referred to:                                                                  

https://www.youtube.com/watch?v=K9Kcaoc8A0Q&list=PLOf4plee9UzCH2w8e2_xpvaq6w1gGCf5Q

https://www.youtube.com/playlist?list=PLOf4plee9UzAaoaj2kZrMm5CcjV-_y1hf

                                                                         *     *     *

NYC Museum:

https://www.amnh.org/explore/videos/humans/are-humans-still-evolving



Wednesday, July 8, 2026

Jumping_It

 8:00 AM 2026-07-08; what is the latest on that collapsing building this morning? The NY Times announcing it is an addition that triggered the collapse...

The latest confirmed information as of 8:00 AM EDT, July 8, 2026 is that the structural failure at 235 East 42nd Street was triggered by added weight from newly expanded upper floors, according to the developer MetroLoft. This matches what you saw in the New York Times — the issue stems from an addition, not demolition.

๐Ÿงจ What caused the buckling?

MetroLoft told investigators that the columns buckled under the added load of expanded upper floors. This is the first clear, on‑record explanation of the cause. 

A portion of the floor sagged by about four inches.

Two load‑bearing steel columns on the 21st floor failed, causing floors 21–26 to sag. 

The building was undergoing conversion into 1,600 residential units, and part of that work involved expanding upper floors, increasing the load on mid‑building columns. 


๐Ÿ—️ Why an addition is more dangerous than removing walls

This is important:

Removing non‑structural walls rarely causes multi‑floor sagging.

Adding weight — especially from expanded floors or new mechanical loads — can overload older steel columns if temporary shoring or permanent reinforcement is insufficient.

The building is a 1970s steel‑framed tower, and mid‑height columns often carry the highest cumulative load.

The DOB commissioner confirmed:

“We have columns that could not hold the weight that it was holding before.”


๐Ÿšจ Current status (8:00 AM)

The building is stable and has shown no movement for many hours. 

Emergency shoring and new steel supports are being installed to replace compromised columns. 

The frozen zone has shrunk to a two‑block area around East 42nd–43rd Streets between Second and Third Avenues. 

Most evacuated residents have been allowed to return home.


๐Ÿงฉ Summary of the cause

It was the addition — expanded upper floors adding weight — that overloaded mid‑building columns and triggered the buckling.  

This is now the leading official explanation.

If you want, I can track updates throughout the day, or explain how column load paths work in a high‑rise like this.


Explain about column load paths...

Here’s a clear, intuitive explanation of column load paths — the thing that determines whether a high‑rise stands safely or suddenly starts sagging like the Midtown tower did.

I’m not using any paywalled Telegraph content in this explanation; this is structural engineering knowledge written directly for you.


๐Ÿ™️ Column Load Paths — The Backbone of a High‑Rise

A load path is simply the route that weight takes as it travels downward through a building.

In a tall steel‑framed tower, the load path is continuous — every floor depends on the floors and columns below it.

Think of it like a stack of books:

If you weaken one book in the middle, the whole stack above starts to sag.


๐Ÿงฑ How Loads Move Through a Building

1. Floor slabs → Beams

Each floor slab (concrete) transfers its weight to steel beams.

2. Beams → Girders

Beams feed into larger girders that collect the load from a whole section of the floor.

3. Girders → Columns

Columns are the vertical “legs” of the building.

They carry:

the weight of the floor they support, plus

every floor above it.

This is why mid‑height columns carry the highest cumulative load — they’re holding the entire stack above.

4. Columns → Foundation

All column loads eventually reach the foundation and the bedrock.

⚠️ Why the Midtown building failed

When the developer expanded upper floors, they added weight to the load path.

That extra weight traveled downward until it reached the 21st‑floor columns — the ones that buckled.


Here’s the key:

Columns don’t fail because of one floor. They fail because of the total load above them.

If the added weight exceeded what those columns were designed (or temporarily shored) to carry, they would:

deform,

buckle,

and cause floors above to sag.

Which is exactly what happened.


๐Ÿงฉ Buckling: The Silent Killer

Columns don’t usually snap.

They bow — even a few millimeters — and once they start bowing, the load increases on the bowed section, accelerating the failure.

Buckling is triggered by:

too much load,

insufficient bracing,

or a sudden change in load path (like removing or altering a beam).


When a column buckles:

the floor it supports drops slightly,

the floors above follow,

and the load redistributes unpredictably.

That’s why floors 21–26 sagged together.


๐Ÿ—️ Why additions are more dangerous than removing walls

Removing non‑structural walls doesn’t change the load path.

Adding weight does.

If the new load isn’t matched with:

stronger columns,

added bracing,

or temporary shoring during construction,

the load path becomes overstressed.

This is the scenario MetroLoft described:

expanded upper floors → added weight → mid‑building columns overloaded → buckling → sagging floors.


๐Ÿ”ง Want a deeper dive?

I can walk you through:

how engineers calculate column loads,

how shoring should be installed during a conversion,

why mid‑height failures are especially dangerous,

or how the investigation will determine the exact cause.

Just tell me what angle you want to explore next.


How come mid-height columns suffer the most?

Mid‑height columns suffer the most because they sit at the worst possible point in the load path — the place where the maximum cumulative weight from all the floors above converges.

This is a core principle of high‑rise structural engineering, and it’s exactly why the failure at 235 East 42nd Street happened around the 21st floor rather than at the top or bottom.

๐Ÿ™️ Why mid‑height columns carry the heaviest burden

Imagine a 40‑story building.

• Columns on the top floors

Hold only a few floors above them.

Their load is relatively small.

• Columns on the bottom floors

Hold all floors above them, but they are:

the thickest,

the strongest,

the most heavily braced,

and directly supported by the foundation.

They’re designed for enormous loads.

• Columns in the middle

These are the danger zone.

They carry:

the entire weight of the top half of the building,

but without the massive reinforcement used at the base,

and they are often modified during renovations (new shafts, new openings, new loads).

So mid‑height columns end up with:

the highest cumulative load,

the least redundancy,

the most vulnerability to construction changes,

and the greatest risk of buckling if anything goes wrong.


๐Ÿงฎ Think of it like a stack of books

If you squeeze or weaken a book in the middle:

everything above it sags,

the load concentrates at the weak point,

and the failure cascades downward.


The bottom book is thick and sturdy.

The top book carries almost nothing.

The middle book is the one that collapses.


Buildings behave the same way.


๐Ÿ—️ Why additions (extra weight) hit mid‑height columns hardest

When the developer expanded upper floors at 235 East 42nd Street, they added weight at the top.

That weight travels downward through the load path until it reaches the mid‑height columns — the ones already carrying the most cumulative load.

Those columns suddenly had to carry:

the original load plus

the new added load from expanded floors.

If the columns weren’t reinforced or temporarily shored to handle the increased load, they would:

bow,

buckle,

and cause floors above to sag.

Which is exactly what happened.


⚠️ Why buckling happens in the middle, not the top

Buckling is triggered when a column’s compressive load exceeds its critical capacity.

Critical capacity depends on:

column slenderness,

bracing,

steel grade,

load eccentricity,

and cumulative weight.

Mid‑height columns have:

high slenderness (they’re not the massive base columns),

high cumulative load,

and often more openings or modifications.

So they reach their critical buckling load first.


๐Ÿงฉ Why the bottom didn’t fail

The base columns are:

thicker,

stronger,

better braced,

and designed for the full building load.

Even with added weight, they remain well below their failure threshold.

The middle is where the load overwhelms the design.


๐Ÿ”ง If you want, I can go deeper

I can explain:

how engineers calculate column load capacity,

how load redistribution works during a failure,

why buckling accelerates once it starts,

or how shoring should be installed during a conversion.

Just tell me which direction you want to explore next.


In what order are things done in building a high rise; and how far has this building gotten?

Here’s a clear, structured walk‑through of how a high‑rise is normally built, and then how far the East 42nd Street tower had progressed in its conversion before the collapse.

I’ll keep this practical and intuitive — the way an engineer would explain it on‑site.

๐Ÿ™️ 1. The Normal Order of Building a High‑Rise

High‑rise construction follows a very predictable sequence.

Think of it as bottom → up → inside → outside → systems → finish.


Step 1 — Excavation & Foundation

Dig down to bedrock or stable soil.

Install piles, caissons, or mat foundations.

This is the “root system” of the building.


Step 2 — Structural Frame (the skeleton)

This is the steel or reinforced concrete frame.

Columns go up first.

Beams and girders connect them.

Floor decks (metal decking + concrete) are poured.

The frame rises floor by floor.

This is the stage where load paths are established.


Step 3 — Core Construction

The elevator/stair core is built:

Concrete shear walls

Elevator shafts

Mechanical risers

The core stabilizes the building against wind and seismic forces.


Step 4 — Exterior Envelope (curtain wall)

Glass and aluminum panels installed.

Weatherproofing and insulation added.

Once the curtain wall is up, the building is “closed in.”


Step 5 — Mechanical, Electrical, Plumbing (MEP)

Inside the building:

HVAC systems

Plumbing stacks

Electrical risers

Fire suppression systems

This is the “organs and arteries” stage.


Step 6 — Interior Build‑Out

Walls

Ceilings

Flooring

Kitchens, bathrooms

Finishes

This is the stage where it starts looking like a place people can live or work.


Step 7 — Testing, Commissioning, Occupancy

Safety inspections

Systems testing

Final approvals

Move‑in


๐Ÿ—️ 2. Where the East 42nd Street Building Was in Its Conversion

This building was not being built from scratch — it was a 1970s steel high‑rise being converted from offices into 1,600 apartments.

A conversion has its own sequence:

Stage A — Structural Modifications

This is the dangerous part.

Cutting new shafts

Adding new mechanical loads

Removing old beams

Reinforcing columns

Expanding floors (which they did)

This is where the collapse occurred.

The developer confirmed that expanded upper floors added weight, which overloaded mid‑height columns around the 21st floor.


Stage B — MEP Reconfiguration

Residential units require:

More plumbing

More ventilation

More electrical distribution

New fire suppression layouts

This work was underway.


Stage C — Interior Framing

Apartment layouts were being built:

New walls

New kitchens

New bathrooms

New risers

Workers reported cracks and falling bricks during this stage.


Stage D — Exterior Work

The curtain wall was already complete — the building was fully enclosed.


Stage E — Finishes

Not yet reached.

The building was still in heavy construction mode.


๐Ÿงฉ Summary: How Far They Had Gotten

By the time the collapse occurred, the building had completed:

Foundation (existing)

Structural frame (existing)

Curtain wall (existing)

Structural modifications for conversion (in progress)

Expanded upper floors (completed recently)

MEP reconfiguration (in progress)

Interior framing (in progress)

They were mid‑conversion, at the stage where structural changes and added loads make the building most vulnerable.


This is exactly the phase where:

load paths change,

temporary shoring is critical,

and mid‑height columns are at maximum risk.


If you want, I can explain:

how floor expansions add load,

how temporary shoring should be installed,

or what investigators will look for next.


So completing the outside was jumping the gun??

Not exactly “jumping the gun” — but closing the exterior before finishing major structural modifications inside does create a risky sequencing problem. And in this building’s case, that sequencing made the failure more likely and harder to detect.

Here’s the real engineering logic behind it.


๐Ÿ™️ Why the exterior is normally finished after the structure is stable

In a new high‑rise, the curtain wall goes on only after:

the structural frame is complete,

the load paths are final,

the building has been fully analyzed for its permanent loads.


That’s because once the exterior is sealed:

you lose visual access to the frame,

you lose easy access for cranes,

you lose the ability to relieve loads or adjust steel members,

and any internal structural work becomes more complex and more dangerous.


๐Ÿ—️ But in a conversion, the exterior is already done

This building was a 1970s office tower.

Its curtain wall was already complete decades ago.

So the developers were doing heavy structural work inside a sealed building:

expanding floors,

adding new loads,

modifying columns,

cutting new shafts,

installing new mechanical systems.

This is much harder than doing it in an open-frame building.


⚠️ Why this matters for the collapse

When you add weight to upper floors inside a closed building, several risks increase:

1. You can’t visually monitor the steel frame

Cracks, bowing, or slight column deformation are harder to spot.

Workers only noticed trouble when:

bricks fell,

cracks appeared,

and floors began sagging.


2. You can’t easily bring in large temporary shoring

In an open-frame building, you can shore from the outside or use cranes.

Inside a sealed tower, you must:

bring steel through elevators,

assemble shoring inside tight spaces,

work around finished curtain walls.

This slows everything down.


3. You can’t relieve load once the exterior is closed

If a column is overstressed, you can’t:

remove exterior panels,

lift loads from outside,

or adjust beams with exterior access.

You’re stuck working inside a sealed box.


4. Load changes become more dangerous

Expanding upper floors adds weight.

That weight travels downward until it hits mid-height columns — the ones that already carry the most cumulative load.

If those columns weren’t reinforced before the added weight was applied, they can buckle.

Which is exactly what happened.


๐Ÿงฉ So was finishing the exterior “jumping the gun”?

Not in the original construction — the exterior was finished decades ago.

But doing major structural load‑changing work inside a sealed building is inherently riskier, and it requires:

extremely careful sequencing,

aggressive temporary shoring,

continuous monitoring,

and precise load calculations.

If any of those were insufficient, then yes — the sequence of doing heavy structural additions inside a closed building becomes a contributing factor.


It’s not that the exterior was finished too early.

It’s that the interior structural changes were done without the flexibility and visibility you’d have if the building were still open-frame.


๐Ÿ”ง If you want, I can explain:

how temporary shoring should be installed for expanded floors,

how engineers calculate added load from floor expansions,

or how investigators determine whether sequencing contributed to the failure.

Just tell me which direction you want to go.


                                                                                          


Tuesday, July 7, 2026

Gypsum

 

NYC; a building being renovated collapsed its upper floors today. What happened?

A 37‑story high‑rise at 235 East 42nd Street in Midtown Manhattan, currently being converted from offices into residential units, suffered a major structural failure this morning, triggering widespread evacuations and an active emergency response.

๐Ÿงต What actually happened

Around 8 a.m., workers reported falling bricks and noticed cracks inside the building. 

FDNY arrived and found two structural columns buckled on the 21st and 22nd floors, with floors 21 through 26 sagging or beginning to cave in. 

A steel beam on the 21st floor was compromised, according to the NYC Department of Buildings. 

The building was still moving for hours, indicating ongoing instability. Officials described it as an “extremely serious situation.” 

The project is part of the largest office‑to‑residential conversion in the U.S., involving the former Pfizer headquarters. 


๐Ÿšจ Evacuations & Safety Measures

FDNY, NYPD, and city engineers evacuated the building and multiple surrounding buildings, including a school with ~400 children. 

A “frozen zone” was established from First to Third Avenues, 40th to 45th Streets, blocking traffic and pedestrians. 

Emergency crews are installing temporary shoring to stabilize the compromised floors. 

No injuries have been reported, and all workers are accounted for. 


๐Ÿ—️ Why did it happen?

The exact cause is still under investigation, but experts note that:

The building was undergoing major internal structural changes for the conversion.

A construction industry lawyer said the pattern suggests structural members may have been removed or altered, weakening a large portion of the building — “highly unusual” for a tower of this size. 


๐Ÿ“Œ Current status (as of late afternoon)

Some columns showed additional movement earlier, but later stabilized for a few hours. 

Engineers have begun floor‑by‑floor assessments and are preparing to install emergency trusses. 

The situation remains dynamic and closely monitored.

If you want, I can track updates, explain the engineering failure in more detail, or map the affected area.


The project is one of converting an office building to  livable apartments. Were they putting in new walls, or taking out old ones?

The short answer: Investigators strongly suspect that structural members were removed during the office‑to‑residential conversion — not simply non‑load‑bearing walls — and that this likely triggered the buckling of columns and the sagging of floors.  

No official cause has been released yet, but multiple credible reports point in the same direction.

๐Ÿงฑ What kind of work were they doing inside?

All available reporting indicates the building was undergoing major internal structural changes, not just cosmetic partition work.

๐Ÿ” Evidence from sources

A construction‑industry lawyer reviewing the incident said the pattern of failure suggests “they’ve taken down certain structural members,” weakening a large portion of the building on more than one side. 

Workers reported cracks, falling bricks, and then saw support columns beginning to buckle on the 21st and 22nd floors. 

The NYC Department of Buildings confirmed a compromised steel beam on the 21st floor. 

Floors 21 through 26 began to sag or cave in, which is consistent with a load‑bearing element being removed or altered rather than simple drywall changes. 


๐Ÿ—️ Why structural members matter

In a 1970s steel‑framed high‑rise like this one, converting offices into apartments often requires:

Removing or relocating interior columns,

Cutting new vertical shafts for plumbing or mechanical systems,

Reconfiguring floor layouts,

Adding new loads (e.g., heavier residential mechanical systems),

Creating open‑plan spaces that require taking out beams or girders.

If any load‑bearing element is removed without adequate temporary shoring, the load redistributes unpredictably — exactly the kind of cascading buckling seen here.


๐Ÿงฉ So were they adding walls or removing them?

Based on the reporting:

They were almost certainly removing structural elements, not just adding apartment walls.

Partition walls (gyprock/drywall) do not cause multi‑floor sagging when removed.

Buckling columns and a compromised steel beam do.

The collapse pattern — columns buckling, floors sagging downward in a stack — is classic for a load‑bearing member removed or cut, not for installing new walls.


๐Ÿงฑ What’s still unknown?

The city has not yet released:

The exact element removed (column, beam, girder, or bracing),

Whether the removal was planned or accidental,

Whether temporary shoring was installed incorrectly or not at all.

Those details will come from the Department of Buildings’ forensic investigation.


Want a deeper breakdown?

I can explain:

How column buckling works,

How office‑to‑residential conversions stress older steel frames,

What temporary shoring should look like,

Or track official updates as they come in.

Just tell me what angle you want to explore. 

                                                        *     *     *

Not my problem!! But I do find the use of pre-made drywall panels instead of plaster

for walls interesting. It's something of a joke word, in Quebec. 'That sandwich tastes like

gyprock!' . Gyprock is tha name of the Australian brand of the product. In effect, it is gypsum

the mineral that is used in drywall!!

Gypsum - Wikipedia

https://youtu.be/XlgZe__lYOg?si=02cZbbj5ANwQeJxH

Jack_D

 

https://www.msn.com/en-ca/news/politics/republican-bill-aims-to-punish-canadian-provinces-with-us-alcohol-bans/ar-AA27lmRa?ocid=BingHp01&pc=U673&cvid=c4721280daba412db67526012c0dacc5&ei=23

Are Canadian consumers being unfairly banned from enjoying American

alcohols? Is a summer without Jack Daniels a summer without Coca Cola?

How do I feel about that...


Government make all kinds of decisions, for our own good. What really stings for 

someone who might be a fan of JD is that there is no end in sight to this stand-off.

The Amrican government is not about to cave in on trade issues - the refusal to sign

a new Free Trade agreement signals that - so our poor thirsty friend is commited to

a long stint on the kind of political action meant to be brief and effective. Brief!!





Monday, July 6, 2026

Abolition

 From the Le Monde series  USA 250,  interesting insights on how abolition was lived through by the 

American political class:

https://archive.ph/9Qlzl


                                   

Big_Difference

                                                                                      



                                                                                         




I'm becoming a better user of my Weather app. That ever enigmatic 'No precipitation for at least

two hours' no longer stresses me out. All that is saying is that there are no visible cloud formations

on radar, and since it takes at least 2 hours for a rain cloud to form... whew!


I have also set up a link to a wet-bulb calculator site, so that I can make better decisions about

how to dress to go out. It is 28C, dry-bulb but because there is low humidity, the heat is not

so oppressive. I can wear a t-shirt with a bit of sleeve, rather than a wispy top and bring a

sweather as I head out to grocery shop in an air-conditioned space.


Makes a big difference to someone who is a senior!!