Fooling greedy foreigners is so easy

Nanox Chairman (and soon to be former CEO) lies to the Korean press again, inflating chip production estimates by 30x in the temporary "plant" and by 9x in the future "fab:"

The Cheongju plant has a partial production capacity of 300 wafers per month, and can produce 50-150 chips per wafer depending on the product line. Chairman Poliakine added, “The clean room size for semiconductor production will also be expanded to more than three times that of the Cheongju plant.” [google translated]

His statement contradicts the slides from the investment presentation at Jefferies on June 4.

Specifically, the temporary "clean room," which is not clean at all and located in an equipment parts manufacturing plant, was supposed to have a maximum capacity of 1,000 chips per month, not the 15,000-45,000 (300 x 50-150) he told the Korean press.  Similarly, he lied about the new fab, when he said production will be more than 3x, implying over 45,000-135,000 chips a month, while the investor presentation said 10,000 chips a month at full capacity.

Weren't Koreans supposed to be good at math?

By the way, those chips are neither semiconductor (they are supposed to use small molybdenum pins, not semiconductors) nor MEMS (there is nothing mechanical about them), and they are not functional.  Here is a snapshot again from the August Business Update proving that the temporary "clean room" is not clean at all, showing the chips all covered with dust specs everywhere.

The article also repeats the lies perpetuated by Nanox investor, Yozma group:

Nanox is a company that manufactures X-rays that can reduce radiation exposure time by one-half by shooting images with clearer quality than existing X-rays at 30 times faster. Its size and weight are one-fifth of that of existing devices, so it can be used in small hospitals and medical blind spots. 

All of the statements in the paragraph above are intentionally misleading.  As the 510(k) summary revealed, Nanox' tube is nothing more than an used and abused (and severely underperforming) dental x-ray tube that is underpowered and slow.  Nanox proposed devices are obviously larger than the portable x-ray devices that it underperforms.

A handheld x-ray device by Vatech Korea

Update:  A slightly different version of the same article also quotes the upcoming CEO, who was kicked out of his Chairman position at Hadassah Medical Center last year (he was also on the Board of Nanox when Nanox signed a suspect agreement with Hadassah):

New CEO Erez Meltzer said, “Once the acquisition of Zebra Medical is completed, we can create next-generation medical devices with imaging AI solutions. Zebra's AI and cloud can form a new AI-assisted diagnostic space," he said. "New cooperation opportunities are always welcome."

The new CEO will not be much different from the old CEO, based on the statement above.  Zebra's AI simply does not work with the proposed Nanox.Arc - the reason is simple - Zebra's AI has been trained on regular x-ray images, while there is nothing regular about the proposed Nanox.Arc.  For example, the chest images that Zebra has utilized must be standard standing/sitting erect PA at a sufficient distance from the x-ray source, while all the proposed Nanox.Arc can produce is an underexposed, close-range supine AP (and it is a good bet Zebra has no chest tomosynthesis training images whatsoever).  Maybe Zebra's team can deliver a miracle, eventually, but only after thousands of the proposed Arcs have been deployed and fully utilized and many, many years.

Korean math, again

Another non-sensical fluff piece sponsored by Nanox:

Nanox said that its Yongin plant will be annually producing 220,000 MEMS chips, enough to make 50,000 Nanox.ARC devices. The temporary facility in Cheongju currently has a monthly production capacity of 1,000 MEMS chips.

That is interesting.  220,000 divided by 50,000 is 4.4.  In other words, each Arc device will have 4 tubes and another very special partial ( 4/10, exactly) tube, just short of the 5 tubes in the investor presentations.   Also, Nanox has not disclosed any plans to make 50,000 Arc devices (only 15,000 by 2024).

The capacity is also wrong  - it was supposed to be 120,000 (based on the 10,000 a month from inventor presentations).

Here is the Korean text, in case of doubt.

The equipment shown in the article's photo appears to be Precision 5000 by Applied Materials, an almost 40-year-old CVD machine - baking the very innovative fake Nanox.Source!  Let me know, if I am mistaken.  

Just too good to be true

Steven Koepke, who goes by koepkesd @ Stocktwits and Steven @ Yahoo, has been busy reading this blog while trying to justify the lies by the Nanox CEO that somehow the $200 (or $100, depending on the day) Nanox.Tube can replace the $150,000 modern CT tube (these are "list prices," of course).

For the longest time I was trying to figure out how Ran can claim that his field emitting device (FED) can generate x-rays on par with the high end x-ray tubes used in CT machines. Those large tubes can generate 800 to 1,000 mA at 120 kV. They also cost $120,000-$150,000. Here is the math. The MEMS (FED) chip has an active area of 0.126cm^2 (4mm diameter on chip in diameter and the power level was communicated at 2.5A/cm^2. The power is concentrated down via focusing device onto the tungsten anode. The basic math provides the power of the beam to be 314mA and 120 kV (per conference call last week). That's quite close and running multiple sources in parallel amplifies the power. Cost comparison: 5 small tubes @ $100 vs $150,000 for singe large CT device tube. Micro-X has a similar arrangement working today with a CNT device (also Field Emitting Device)

 

So, what's wrong with his reasoning?

There is no such thing as a field emitting device.  FED refers to a failed display technology -  a field emitting DISPLAY.  It does not contain "a field" of emitters, as Nanox CEO believes - it emits electrons induced by an electrostatic field.  It is not a more efficient or a cooler way to generate x-rays - all x-ray tubes, whether using a cold cathode (based on the field effect) or a hot cathode (using a hot filament) to emit electrons, have about 1% efficiency as 99% of the energy applied to the tube gets wasted as heat at the anode.  A hot filament uses a lower voltage - about 4V - than the 40V (or way more) needed by a cold cathode.  Roentgen discovered x-rays in 1895 using a cold-cathode (gas discharge) tube.  GE invented the hot-cathode x-ray tube in 1913 and obliterated the cold-cathode ones.

The proposed Nanox.Source chip is not MEMS, as there is nothing mechanical about it.  The chip is not real, or commercially available, of course, as Nanox has no ability to manufacture it commercially, at least not yet.

The current density of 2.5A/cm^2 comes from a fraudulent, that is, intentionally misleading, 2015 datasheet by Nanox predecessor, which I have previously linked here on this blog. 

The Nanox.Tube cannot do 314mA and 120 kVp.  The one used in the Nanox.Cart can do up to 2mA and up to 40 kVp, at most (or 0.08 kW, per 510K summary).  The CEI one can do up to 1mA and up to 100 kVp (or something like 0.1 kW, per CEI video).  The tube used by GE in the predicate device for Nanox.Cart can do about 40 kW - it has a rotating anode.  The CT tube can do about 120 kW (using Steven's numbers). So, to replicate the power of a $150,000 CT tube, one needs to use, oh, something like 1,000-1,500 Nanox tubes that cost $100,000 or more.  An after-market CT tube will cost less than $100,000, of course.  All this has been already discussed last year.

Micro-X has a 4.8 kW tube (a bulky stationary-anode one) - it uses carbon nanotubes, which Nanox says is impossible - it sells a few units a year.  The biggest CEI tubes are smaller sizes than Micro-X's and go up to about 2.5 kW (also stationary-anode ones).  

Update June 10, 2021:  Investors will eventually blame Nanox CEO for their delusions.  Steven continues:

The anode temperature becomes the challenge with the NNOX tube. CEI states that their tubes can handle about 60KJ. The RSNA video shows the bed is moving through the sources quickly (15-20 seconds for whole body). My guess is that NNOX is using high current short bursts to keep the anode temperature under control. In the video they may have used 300mA for up to 0.2 seconds to make 10 shots (capturing 8" per shot) while the cart moves through. 300mA x 0.2 X 10 shots = 60KJ. You can't shot this with dental tubes like that. They don't have the current and the image gets too blurry.

He is right that a typical dental tube (which has a better performance than the Nanox tube) cannot do 300mA.  He is also right that at some point, the heat capacity of the anode becomes a challenge (the anode temperature is not really a problem - it is the temperature of a part of the anode, the tungsten target, that is the challenge).

But Steven does not understand what heat capacity means.  Yes, one of CEI's most powerful medical tubes, OX125-06, can handle 60 kJ (CEI only makes stationary-anode tubes).  But that does not mean that it can do 300 mA or that 300 mA  x 0.2 s  x 100 kVp  x 10 shots = 60 kJ.  Nor does it mean that you can do 5 A x 0.2 s  x 60 kVp x 1 shot.  CEI provides nice charts in its datasheets to explain the interplay between heat capacity, tube current, tube voltage, and time.

As the charts show, the tube cannot do more than 35mA at 60kVp for 0.1s or more than 20mA at 110 kVp for 0.1s. But it can do 15 mA at 100 kVp for 10 seconds.  The RSNS 2020 demo, which we now know was fake, never demonstrated a full-body scan - it scanned three phantom "organs." The "hand" scan consisted of 45 "shots" or images ( 5 tubes x 9 tilts/translations) - it took about 50 seconds for the images thumbnails to appear on the display.  That is about 1 second per shot, not 0.2 seconds (and we don't know what that's even real).

The CEI OX-70, a dental tube,  can do about 32mA at 60 kVp for 0.1s or more than 20mA at 90 kVp for 0.1s.  It can do 10mA at 90 kVp for 10 seconds.  Here is some summary table from CEI's datasheets.  Stationary-anode tubes all look kind of the same.  The tubes that do less than 100 kVp are "dental" and typically tolerate half the current than the "medical," and are a bit smaller. 

Model	Voltage  kVp	Current mA, 0.1s	Current mA, 100kV	Focal sp. (mm)	Diam. (mm)	Length (mm)
Small/Dental tubes
OX/70-P	70	19	N/A	0.8	30	72
OX/70-5	70	11	N/A	0.5	30	72
OCX/65-G	70	12	N/A	0.8	30	76
OX/70-4	70	9	N/A	0.4	30	72
OX/70	90	21	N/A	1.2	30	82
OX/90	90	9	N/A	0.5	30	83
OCX/70-G	70	12	N/A	0.8	30	65
OCX/70-G4	70	8	N/A	0.4	30	65
Medical/Mobile tubes
OPX/105	110	18	2.5	0.5	42	125
OPX/105-4	105	17	2.5	0.4	42	95
3D/cone-beam CT tubes
OCX/100	105	20	4	0.5	46	140
OX/100	100	26	1.5	1.0	35	85

Recall, the Nanox tube in Nanox.Cart can do only 2mA at 40 kVp (for 0.1s -1 s).  The CEI Nanox tube can do only 1 mA at 100 kVp for 40 seconds (per CEI video).  The CEI OX-70 dental tube can do about 40 mA at 40 kVp for 0.1s, about 25 mA at 40 kVp for 1s, and about 3 mA at 90 kVp for about 40 seconds (per datasheet charts).  If Nanox tubes perform like poorly-made hot-cathode dental tubes, they probably are.  No mystery Nanox.Source chip required.

Update June 10, 2021:   Just to clarify, regular dental tubes (just one or 5 ) can definitely replicate the fake RSNA 2020 Nanox.Arc demo.  The "hand" scan took about 50 seconds for 45 images.  Let's see whether a dental tube can do 45 images at 45 seconds, that is, a bit faster.  A CEI dental tube operating at 90 kVp can do 3mA continuously for 45 seconds, so each exposure (image) will be 3 mAs at 90 kVp.  The Nanox.Cart demo at RSNA 2020 image needed just 1.5 mAs at 40 kVp (so, significantly less than 1/4 of what the CEI dental tube can supply).  Commercial fluoroscopy equipment does ok with 100 kVp and 1 mAs for each frame (image) at 30 fps.  So, sure, with a good enough (expensive enough) detector, you can do the Nanox.Arc tomosynthesis within 45 seconds.  But the detector (regardless of the tubes used) won't cost anywhere near $10,000.  And no one would like to look at the images (the American College of Radiology never considers a tomosynthesis procedure to be "usually appropriate,"  except for breast, which the Arc cannot do).

The curious case of Nanox.Arc's development

Last week @Ehlyz on Yahoo linked to a webpage of the engineering firm Ziv-Av and wrote:

If you are still worried this company is fraud and there is no end product to sell, take a look at who is building their CT scanner, Ziv-Av, who is also a vendor for Mazor Robotics and other medical companies.

Sure enough, the engineering firm Ziv-Av claims that the Nanox.Arc device was developed by Ziv-Av's engineers, not by Nanox (Nanox supposedly only contributed a proposed x-ray source).

According to the webpage, published sometime in 2020 prior to Nanox IPO, Nanox.Arc is a revolutionary x-ray device that could do anything the current technology could, but it is smaller, more mobile, and at least 1/100 as affordable.  The device was developed in record time - just 3 months, from scratch and for peanuts (Nanox shows in its prospectus on page 9 less than $3 million in research and development expenses for the entire 2019).  It was this working prototype that supposedly led to the equity raise and Foxconn "endorsement" in January 2020.

The problem is that that the device shown on the webpage (Nanox.Arc version 1.0, according to Nanox tech webpage) is completely fake.  It cannot take any x-ray images because it does not have any x-ray tubes and any x-ray detectors.  It only has a battery and blue LED lights - no need for the special cooling system that Ziv-Av claims to have developed.   

Ziv-Av's claim that this was a "working" prototype also contradicts the draft registration statement that Nanox did not have a working prototype prior to February 2020 (that is, the equity raise in January 2020 must have occurred without a working prototype):

We have not produced a working prototype of the Nanox.Arc (page 9) 

Moreover, if the working prototype looked like what Ziv-Av is showing, then the device in the demo to Foxconn in December 2019 shown below must have used a non-working prototype - that is, the demo was fake.

device demoed to Foxconn, December 2019

Here is the list of all the false and weird claims by Ziv-Av on that webpage:

1.  Ziv-Av develops revolutionary and affordable CT scanner for Nanox

Nope, even if the device were not fake, it cannot be used as a CT scanner due to limited number of projections (a CT scan uses hundreds of projections at different angles per arc/rotation).  It is affordable only because it is completely fake. 

2.  Nanox is a medical imaging company which has developed a revolutionary CT device that is mobile, substantially smaller and extremely cheaper than the existing devices. 

Nanox now denies that its proposed concept device is a CT device, and says it is a tomosynthesis device (unable to generate axial slices).  The device is cheap only because it is fake - the main cost of a real device would be in the detector.

3.  Nanox’s CT technology is based on digital X-ray production using a MEMS component instead of conventional flame lamps enabling cost reduction by orders of magnitude. 

There is no such thing as digital x-ray production - the proposed Nanox x-ray source generates x-rays the same way as a regular $100 hot-cathode x-ray tube - by smashing a bunch of electrons into a metal target.  And the cost of a Nanox tube will always be higher than a regular x-ray tube of the same performance, as any non-defective chip will cost more to make than a filament (a piece of wire).  It is also apparent that Ziv-Av believes x-rays are generated by conventional flame lamps - not clear whether burning kerosene or lamp oil.

conventional x-ray tube per Ziv-Av ( image source: https://www.freeimages.com/photo/the-oil-lamp-3-1535516 )

4.  The device supports scans such as CT, mammography, fluoroscopy and angiography.

Nanox now denies the CT and mammography "support" (CT-like imagining with 11 sources is now a simulation only).  Fluoroscopy and angiography are still on the table for the concept device, but they would be extremely limited, as its device lacks the positional flexibility of modern low-cost C-arm devices.

5.  Ziv-Av engineers revolutionized the medical imaging system 

Nope - the medical imaging system is still the same.

6.  Nanox approached Ziv-Av for the design of the revolutionary digital X-ray machine and its prototype within a stringent timeline of three months.

This may actually be true.  But the only revolutionary thing was the complete fakeness of the device. 

7.  Among many other design features, Ziv-Av designed the arch of the scanner which scans the patient’s body from different angles. 

Oh, so the Arc idea came from Ziv-Av rather than Nanox...

8.  The arch is designed to work with a very high voltage of 70,000V which creates immense heat. 

The statement that 70kV is associated with immense heat shows that Ziv-Av engineers do not understand basic physics and engineering.  An x-ray tube that operates at 1mA generates less heat than a 100W lightbulb.  Also, 70kV tube voltage is too low for a general x-ray device (it could be ok for extremities). 

this lightbulb generates immense heat per Ziv-Av (image source: https://www.freeimages.com/photo/light-bulb-1531205 ) 

9.  Ziv-Av managed the heat dissipation by designing a cooling system. 

The cooling system in the device is fake and not needed, as there is no x-ray source.  Subsequent proposed device iterations by Nanox show that the proposed "cooling system" is just a CNC-cut metal slab - a simple, and not very effective, heat sink.

 

10.  Along with the arch of this amazing machine, Ziv-Av also provided the design of the machine’s table, mechanics, electricity, electronics and motion control system .

Wow - so the only thing that Nanox has developed was the proposed x-ray source, and everything else (fake, of course) came from Ziv-Av? 

11.  Through its specialists, Ziv-Av achieved a significant cost-reduction – realizing Nanox’ vision of affordability to all.

True.  A fake device without an x-ray source or a detector or even a high-voltage generator would be cheap and affordable, indeed.  And, as a plus, it does not even require radiation shielding.  The only downside - it can generate no images.

12.  Ziv-Av excels in cost-effective prototype production.  Ziv-Av’s multidisciplinary engineers provided a turnkey solution from design to production of this innovative machine. 

It is innovative and cost-effective, as it is completely fake - a rarity!

12.  All the production, assembly & integration and tests were performed in Ziv-Av’s well-equipped workshop. 

No doubt.  Again, Nanox only contributed a proposed (fake) x-ray source.  

13.  The demonstrations of this perfectly working prototype helped Nanox raise $26 million within three months from many investors including ‘Foxconn-the IT industry giant’. 

By perfectly working, Ziv-Av means it can light up in blue using the built-in LEDs and a 12V battery, of course.

14.  From scratch to a revolutionary, cost-effective design as well as a working prototype – Ziv-Av accomplished all in just 3 months.

Nice.

What the webpage does not say is that the engineering firm's owner, Mr. Ziv-Av, at some point a chief scientist of the Israeli Ministry of Transportation, was convicted of securities fraud and then claimed that he did not know what he was doing.

Update:  Apparently, a Nanox promoter also tweeted about Ziv-Av last week, transforming CT or computed tomography into "3d tomo" (tomo simply means slice in greek), falsely claiming that a single (non-axial) slice meant CT-like capability, and insisting 70kV or less is not a problem for chest:

Chest/lung, musculoskeletal including skull likely on this 510(k) w/ enhanced 3D, slices, plus 2D x-ray. Cheap device. Will expand market.

Yeah, will expand the market with a completely fake device.

Update December 20, 2021:  Minor spelling correction.  

News in Nanox annual report

What's news and notable in Nanox annual report, relative to the Prospectus filed in February? 

Material weakness

We have identified a material weakness in our internal control over financial reporting in connection with the audit of our financial statements as of and for the years ended December 31, 2019 and 2020. (page 49)

Oops.  That's even before any revenues are recognized.

Dangling chips 

 As mentioned above, we currently manufacture the MEMs X-ray chips in the clean rooms located in Tokyo, Japan (page 15)

Nothing like it is mentioned above (in the annual report).  The rest of the statement, of course, is also false - the clean rooms located in Tokyo, Japan do not allow commercial use, and therefore Nanox cannot manufacture the proposed "digital" x-ray source that relies on those chips (and, in reality, there is nothing digital or MEMs about them).

 

No working Nanox.Arc

Although we have produced a working prototype of the Nanox.ARC and developed a prototype of the Nanox.CLOUD, we have not produced any of the approximately 15,000 Nanox.ARC units planned for the initial global deployment under the contract manufacturing agreement with FoxSemicon Integrated Technology, Inc., a subsidiary of Foxconn (“FITI”).  (page 7)

So, one working prototype of Nanox.CART, the one that got cleared?   But no working prototypes of Nanox.Arc?  Is this an admission, finally, that the RSNA 2020 demo of the Nanox.Arc was faked?  Why couldn't Nanox complete even one of the 10 prototypes that Nanox was supposedly assembling in November 2020 (according to the Q3 2020 results call)?  What happened to those mock-ups in all these production photos pushed by Nanox and its promoters this year?

A side note here:  Nanox never signed an agreement with FITI, according to the text of the contract manufacturing agreement.  The agreement was signed with a Japanese company that is not a Nanox subsidiary, according to public corporate records.

No ceramic tubes

We are evaluating, subject to completion of testing, a transition from glass-based X-ray tubes to ceramics-based tubes for cost efficiency purposes, which are the tubes to be used in the multi-source version of the Nanox.ARC, and we intend to enter into an agreement for such ceramics-based tubes with a new manufacturer in the future. (page 14)

That is, Nanox still cannot manufacture the ceramic tubes that the CEO claimed were used at the RSNA 2020 demo of both the Nanox.Cart and Nanox.Arc.  So, the RSNA 2020 demo was fake and the FDA 510(k) submission may have been fraudulent.

Fuji is out

We have not entered into any licensing agreements; however, we expect to enter into negotiations regarding a commercial arrangement with FUJIFILM Corporation for the licensing of our Nanox System. Any of the above factors may negatively affect the implementation of our Licensing Model, or cause our Licensing Model to fail. (page 12)

This is an admission that Fuji is not a Nanox Mamography OEM (that is, all Nanox investor presentations so far have been misleading ).  In the Prospectus, Nanox still falsely claimed:  

We are currently discussing the terms of a potential commercial agreement with FUJIFILM Corporation.

Chinese tubes 

We have, and expect to enter into, agreements with manufacturers and/or suppliers in China for the production of our X-ray tube, the Nanox.ARC and some of their respective components. (page 23)

Is this an admission that Nanox is using a regular low-cost, low-quality, hot-cathode Chinese x-ray tube and calling it "digital?"

 

A confused FDA: Cart or Arc

 

... we submitted a 510(k) premarket notification for the Nanox Cart X-Ray System... in January 2020... On January 30, 2021, we received additional information requests from the FDA which, among other things, require us to address certain deficiencies and questions, including requests that we provide additional support regarding the intended use of the Nanox.ARC and the comparability of the Nanox.ARC to the predicate device. We submitted our response to these requests on March 1, 2021. On April 1, 2021, we received clearance from the FDA to market our Nanox Cart X-Ray System. ...we may seek alternatives for commercialization of our Nanox Cart X-Ray System.  (page 32) 

Why was the FDA asking about Nanox.Arc in January 2021?  The device that got submitted and eventually got clearance is Nanox Cart X-Ray System, that is, the ugly Nanox.Cart, not the fake Nanox.Arc. The FDA should have asked about Nanox Cart X-Ray System, no?

Nanox also confirms that it still has no plans the market/commercialize the Nanox Cart X-Ray System even after its pre-market notification got cleared.

Update:  Muddy Waters tweets about Gilad Yron, the Chief Business Officer, no longer counting as an executive, which I missed (it is not clear what his current role is, if any). 

Update April 8, 2021:  Fixed some spelling.  Also, the Nanox.Cloud prototype developed by Nanox is just a collection of a few mock-up screens that use stolen images and contain non-sensical findings.  

The "nano" in Nanox isn't

So, Nanox has been boasting in the technology section on its website: 

Over nine years of development by a Japanese and Israeli engineering team, produced a ‎stable Cold-Cathode field emission MEMS silicon‎. Using proprietary Micro-Electrical-Mechanical-Systems (MEMS) techniques, ‎millions of nanoscale gates are fabricated on each silicon chip. ‎Nanox emitters are far more uniform than carbon nanotubes (CNT) and are orders of ‎magnitude smaller than conventional Spindt-type cathodes‎. ‍

But is any of it true?  For example, has Nanox been able to miniaturize a technology that was a complete failure and make it potentially successful?  The answer is:  No!

If Nanox' emitters are "orders of magnitude smaller" than conventional Spindt-type cathodes, this means they are smaller than 1/100 the size of the "conventional" emitters (that's two orders of magnitude).  Here is how Nanox emitters are supposed to look like under an electron microscope (Slide 13, January 2021 JP Morgan presentation).

They look tiny, but how tiny are they?  Nanox is withholding that information.  Luckily, Nanox predecessor company has already published the original image - in early 2016, in a one-page "Nanox Technology Brochure" - with an embedded scale in it, like any regular image, or micrograph, generated from a commercial electron microscope.  All we have to do is use that scale to measure the diameter of the gate holes and the distance between them, and compare to say state-of-the-art Spindt emitters twenty years ago.

Aha.  So the holes are about 300nm in diameter and the distance between them is about 500nm.

And, what was the state-of-the-art twenty years ago, in year 2001?  Here is a picture from the Motorola paper titled "Field Emission Displays: a critical review" 

Uh-oh.  Turns out the Spindt holes from Candescent Technologies were actually smaller - 100nm in diameter, and intentionally placed at random distances.

Is it possible that somehow Nanox' team did not know about those developments twenty years ago?  Nope.  Here is why.  According to the unofficial history of the Spindt scam,  three years prior, Sony, desperate to maintain its relevance in the TV market, but completely clueless, joined forces with Candescent.

In November 1998, CTC announced an agreement with Sony Corporation for joint development of a 14-inch diagonal FED by the year 2000. Both companies pledged to spend $50 million on this effort. Most of the work would be performed at CTC's plants. A team of six Sony engineers were sent to San Jose to begin the work, with some additional staff dedicated to the project in Japan

Motorola had already canceled its project in 1999, thus the paper in 2001, due to inability to "solve some basic technology problems."  Candescent went bankrupt in 2004.  It took Sony a few more years to realize its mistake, but the $1 billion R&D spending is a complete myth.

So, to reiterate, ‎Nanox emitters are not orders of ‎magnitude smaller than conventional Spindt-type cathodes‎ - they are, in fact, LARGER.  Not that it matters, because Nanox, contrary to the false claims in the Prospectus and elsewhere, has no access to facilities to fabricate them commercially.

And the "nano" should have been a red flag anyway - MEMS in the supposed Nanox "Cold-Cathode field emission MEMS silicon" stands for micro-electro-mechanical systems.  Electro, not electrical.  Micro, not nano.  And there is nothing mechanical (moving) - the "electro-ns" do not count.

Ok, but what about those 100 million emitters in Slide 13 above?  Well, that number is possible.  Assuming those are positioned in a 10,000 x 10,000 square, and assuming 800nm distance between the tips, that gets us to a 8mm x 8mm "chip," ballpark.  But such a chip, even if it were real, is not changing anything.

In case anyone was wondering how big the Spindt emitters were 50 years ago, here is a diagram and a micrograph from the 1976 Spindt paper.  The gate hole diameter is 1,500 nm.  So Nanox emitter is just 1/5 of it, not 1/100.

Update March 29, 2021:  reworded and added the original Spindt emitter size.

Update March 29, 2021:  Wikipedia's page on Field Emitter Arrays have an interesting entry about nano-Spindts.

Nano-Spindt arrays represent an evolution of the traditional Spindt-type emitter. Each individual tip is several orders of magnitude smaller; as a result, gate voltages can be lower, since the distance from tip to gate is reduced. In addition, the current extracted from each individual tip is lower, which should result in improved reliability.

How did this incorrect and misleading entry wind up on wiki?  After checking the edit history, it turns out Nanox added it on December 22, 2015, a few days after the failed attempt by Nanox predecessor to market its fake cathode at RSNA 2015 (Nanox current CEO was then the Chief Strategy Officer).  Here is who added it:

My name is Joshua Lilienstein. I am an American medical doctor, now specializing in medical device development. I currently serve as Chief Medical Officer for Nanox Imaging, Plc., a Japan-based startup. Nanox's core technology is the field effect cathode. I will be editing entries that pertain to this technology, and specifically, in its application to medical imaging. I am aware of Wikipedia's Conflict of Interest policies, and will endeavor to abide by them.

At least he was honest about something.

He referenced an interesting paper that does not support his wiki entry in any way, but describes the long-lost x-ray detector, SAPHIRE, that was supposed to use nano-Spindts.  This is a flashback to the times when Nanox team "believed" that the x-ray detector was more important than the x-ray source.