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Researchers High On “Molly” For Low-Cost Hydrogen Fuel
http://cleantechnica.com/2015/10/13/researchers-high-molly-low-cost-hydrogen-fuel/
Molybdenum Disulfide!!! (or MoS2 if you’re not making a party drug joke out of it)
MoS2 has two points in its favor here in the US: it currently costs just 37 cents per pound, and it can be produced from abundant domestic sources, namely molybdenite.
If MoS2 is ringing bells, that’s because the material is emerging as a 2D “cousin” of graphene, and research teams have been investigating it for energy storage as well as renewable hydrogen production and other clean tech applications.
The secret sauce is an “energetically disordered region” at the edges of the 2D crystals, which translates into a catalytic efficiency pretty close to that of platinum.
Hydrogen Cars Reach Mass Market in UK
http://www.theguardian.com/environment/2015/nov/04/the-future-is-here-mass-market-hydrogen-cars-take-to-britains-roads
GreenCarReports HYSR Coverage
http://www.greencarreports.com/news/1100234_hypersolar-reaches-voltage-to-produce-hydrogen-with-solar-energy
Good info-Several possibilities
1) Cumorah was a broker for other short term holders
2) Cumorah sold out on the last rally [possibly accumulating now]
International Patent Link
https://patentscope.wipo.int/search/en/detail.jsf?docId=WO2015142916
Apple, Inc: 900 MILLION shares can be UNLEASHED
Better not invest in Apple!
Just kidding =)
Never invest without a Chart
HYSR has good volume and just filed for an international patent based on their American patent
Details of International patent are being reviewed now by several of us and we are doing some more Q&A w/ Tim Young
HYSR-Panasonic Deal Approaching -- !?
Tim dropped Hints several times - Japan-Panasonic[[-Australia]] synergy
Submersible PV element - Must need a highly Translucent, Semi-Conductive, Patterned PEDOT:PSS coating?!
HyperSolar patent value is now appreciating in front of the world for all see
http://news.panasonic.com/press/news/official.data/data.dir/2012/07/en120730-5/en120730-5.html
Panasonic Develops Highly Efficient Artificial Photosynthesis System Generating Organic Materials from Carbon Dioxide and Water
Panasonic opens up a new way to reuse the wasted carbon dioxide to a usable energy source. This efficient system with a simple structure has been realized by applying a nitride semiconductor as a photo-electrode. The simple structure has a significant advantage in scalability for real systems.
Osaka, Japan - Panasonic has developed an artificial photosynthesis system which converts carbon dioxide (CO2) to organic materials by illuminating with sunlight at a world's top efficiency*1 of 0.2%. The efficiency is on a comparable level with real plants used for biomass energy. The key to the system is the application of a nitride semiconductor which makes the system simple and efficient. This development will be a foundation for the realization of a system for capturing and converting wasted carbon dioxide from incinerators, power plants or industrial activities.
CO2 is one of the substances responsible for greenhouse effect and as such, efforts are being made to reduce the emissions of CO2 worldwide. The problem of CO2 is also directly connected to an issue of the depletion of fossil fuels. Artificial photosynthesis is the direct conversion from CO2 into organic materials, which can solve both of these problems.
In the previous approaches so far, the systems have had complex structures such as organic complexes or plural photo-electrodes, which makes it difficult to improve their efficiency in response to the light. Panasonic's artificial photosysnthesis system has a simple structure with highly efficient CO2 conversion, which can utilize direct sunlight or focused light.
We found firstly that a nitride semiconductor has the capability to excite the electrons with enough high energy for the CO2 reduction reaction. Nitride semiconductors have attracted attention for their potential applications in highly efficient optical and power devices for energy saving. However, its potential was revealed to extend beyond solid devices; more specifically, it can be used as a photo-electrode for CO2 reduction. Making a deviced structure through the thin film process for semiconductors, the performance as a photo-electrode has highly improved.
The CO2 reduction takes place on a metal catalyst at the opposite side of nitride semiconductor photo-electrode.(See Fig. 1) The metal catalyst plays an important role in selecting and accelerating the reaction. Here, it is noted that the system comprises of only inorganic materials, which can reduce the CO2 with low energy loss. Because of this, the amount of reaction products is exactly proportional to the light power. This is one of the merits in such an all-inorganic system while some conventional systems cannot follow the light power in general because of their internal or external rate-limiting processes in the complex structures.
The system with a nitride semiconductor and a metal catalyst generates mainly formic acid from CO2 and water with light at a world's top efficiency of 0.2%. The efficiency is of a comparable level to real plants used in the biomass energy source. The formic acid is an important chemical in industry for dye and fragrances. The reaction rate is completely proportional to the light power due to the low energy loss with simple structure; in other words, the system can respond to focused light. This will make it possible to realize a simple and compact system for capturing and converting wasted carbon dioxide from incinerators and electric generation plants.
On this development, Panasonic holds 18 domestic patents and 11 overseas patents, including pending applications.
This development was partially presented at 19th International Conference on the Conversion and Storage of Solar Energy held on Pasadena, United States on July 30, 2012.
Reading: Photoelectrochemical Water Splitting: Standards, Experimental Methods, and Protocols
https://books.google.com/books?id=eVWRAAAAQBAJ&printsec=frontcover&source=gbs_ge_summary_r&cad=0#v=onepage&q&f=false
Photoelectrochemical Water Splitting: Standards, Experimental Methods, and Protocols
By Zhebo Chen, Huyen Dinh, Eric Miller
This book outlines many of the techniques involved in materials development and characterization for photoelectrochemical (PEC) – for example, proper metrics for describing material performance, how to assemble testing cells and prepare materials for assessment of their properties, and how to perform the experimental measurements needed to achieve reliable results towards better scientific understanding. For each technique, proper procedure, benefits, limitations, and data interpretation are discussed. Consolidating this information in a short, accessible, and easy to read reference guide will allow researchers to more rapidly immerse themselves into PEC research and also better compare their results against those of other researchers to better advance materials development. This book serves as a “how-to” guide for researchers engaged in or interested in engaging in the field of photoelectrochemical (PEC) water splitting. PEC water splitting is a rapidly growing field of research in which the goal is to develop materials which can absorb the energy from sunlight to drive electrochemical hydrogen production from the splitting of water. The substantial complexity in the scientific understanding and experimental protocols needed to sufficiently pursue accurate and reliable materials development means that a large need exists to consolidate and standardize the most common methods utilized by researchers in this field.
Happy Halloween HYSR Holders!![[ECS in 2 weeks!]]
A ghoulish day to you all!
https://ecs.confex.com/ecs/228/webprogram/Paper59686.html
228th ECS Meeting (October 11-15, 2015):
http://www.electrochem.org/meetings/biannual/228/
1736 Low-Cost Synthetic Routes for Fabricating Tandem/Multi-Junction Photoelectrochemical Devices
Wednesday, October 14, 2015
West Hall 1 (Phoenix Convention Center)
W. Cheng (University of Iowa),
A. M. Rassoolkhani (Chemical and Biochemical Engineering, University of Iowa),
S. Mubeen (University of Iowa)
Using sunlight to convert widely available and inexpensive feed stocks such as water, CO2, and industrial wastes (including halogenides) reliably to fuels and value added chemicals, efficiently and cost-effectively, has been, and continues to be a major goal. Most such reactions require a minimum of 1eV or more photon energies. For example, the minimum free energy required to split water reversibly is 1.23 eV. However, kinetic limitations and other sources of inefficiencies (for example, water oxidation on photoanodes is kinetically sluggish, and CO2 reduction at photocathodes needs high overpotentials) make the practical energy needed to carry such reactions even considerably higher. A single-junction photosynthetic device would therefore need to base on a semiconductor with a band gap (Eg) > 2.5 eV for it to carry out water splitting or CO2 reduction, precluding the exploitation of a substantial portion of the solar spectrum. Using tandem/multi-junction photovoltaic architectures is an attractive strategy to overcome these limitations. Such strategies have been estimated to be capable of achieving ~18% solar-to-hydrogen conversion efficiencies. John Turner and his colleagues [1] demonstrated a solar-to-H2 conversion efficiency of 12.4% using multi-junction III-V semiconductors in 1990’s. However, the high cost and complexity associated with device fabrication using Si and III-V semiconductors to produce triple junction devices have impeded commercialization. Here, we report a novel and low-cost wet chemical synthesis route to fabricate a tandem junction PEC device through direct deposition of inexpensive and efficient metal oxide/sulfide based photoanodes on single junction Si solar cells which act as photocathodes. The above structures were able to generate sufficiently high cell voltages to drive valuable, and, at times, challenging photoelectrochemical processes sustainably.
Reference:
Khaselev, O. & Turner, J. A monolithic photovoltaic-photoelectrochemical device for hydrogen production via water splitting. Science (New York, N.Y.) 280, 425–7 (1998).
SOFC/PEMFC before the egg (HyperSolar H2Generator)
PEMFC/SOFC is indeed a competitive business (FCEL, BLDP, ITM.L, HYGS, PLUG, ..)
You are mentioning HYSR like we have competition - The article you posted references materials research supplemental to our product
Confused here
Beyond that:
Our H2 production can be injected directly to the existing Natural Gas Pipeline as Hydrogen, it is non-corrosive
Natural Gas Pipeline can carry 15% Hydrogen and up to 60% would only require consumers to switch out their burners
We already have distribution infrastructure
Don't even need to wait on the interim to produce Hydrogen / NG Fueling Stations by this rhetoric
The goal of HYSR is to super concentrate focus on advancement of materials research and manufacturing to optimize Hydrogen evolution [and eventually produce hydrogen at the point of distribution]
Their patents have them well positioned on application of PAH Reactor technology
HYSR Patented Semi-Conductive Transparent Polymer is a product of our research
In terms of application, the polymer is used to coat particulate solar devices to create submersible Photoelectrochemically Active Heterostructures (PAH) for use in a Slurry Reactor
The coating is a product which will continue to evolve in parallel with :: The material used in composition of multi-junction photosynthetic cells
HyperSolar has University of California Santa Cruz working on materials and voltage output of PV Cells
University of Iowa working on manufacturing and voltage output thru optimization of the manufacturing process (patterning and bonding of the polymer coating, etc)
Bloom Energy=SOFC, not Hydrogen Production
HYSR is actually what will supplement the possibility of SOFC or PEMFC use in residential circumstances
HYSR enables utility scale production of pipeline ready H2, and as efficiencies continue to improve residential applications will make way.
"Bloom Box" Solid Oxide Fuel Cell is a product which uses (consumes) H2 from its point of storage/production
Natural Gas Pipeline can carry 60% H2
Therefore :: Infrastructure is already in place
For a so-called "tiny" company, HyperSolar in fact has two concurrent Sponsored Research Agreements - Does this surprise to you?
Regents of the University of California are joint holders of our patents
UC Santa Barbara & University of Iowa sponsor our research in Dept of Energy funded labs.
Dr Eric McFarland (University Queensland) and Dr Yat Li (UC Santa Cruz) continue to directly collaborate.
If you want to understand where we are at in terms of reaching commercialization goals, ...
http://www.highbeam.com/doc/1P3-3819593301.html
And in terms of our next accomplishments, check out "Particle Suspension Reactors and Materials for Solar-Driven Water Splitting"
[Have you even read the most recent news? Just curious...
http://www.theguardian.com/sustainable-business/2015/may/22/solar-fuel-carbon-dioxide-co2-climate-change-photosynthesis ]
Decent analyst coverage as well:
( http://www.microcapdaily.com/riding-the-hypersolar-inc-otcmktshysr-express/112904/ )
( http://www.microcapdaily.com/everyone-is-talking-about-hypersolar-inc-otcmktshysr/113236/ )
This catalyst can easily be incorporated w/HYSR H2Generator
We have been considering use of Biological [Bacteria Driven] Catalysts as well, working w/Dr. Yat Li's group
http://news.ucsc.edu/2013/10/solar-microbial-device.html
This is another option to supplement in reaching our target voltage
Each materials discovery (as referenced, cobalt + graphene) can be applied to our particles
Best option so far is arrays of gold nanorods embedded with Cobalt
Short Answer:We've researched Cobalt Catalysts Since 2008
http://www.news.ucsb.edu/2013/013471/uc-santa-barbara-scientists-develop-whole-new-way-harvesting-energy-sun
Rapid materials testing has been going on for years and years w/Moskovitz team [incl. Eric McFarland, Syed Mubeen, Joun Lee, Nirala Singh]
http://www.phschool.com/science/science_news/articles/solar_hydrogen.html
https://chemengr.ucsb.edu/~ceweb/ce/people/faculty/mcfarland/index.html?header.html&0
Cobalt: Materials Sourcing
drop me an email guys
bhmltn 7 a live.com
Let's hope for 2.5v announcement 10-21-16
228 ECS Confernce;presentation from Iowa team!
Our University Iowa team presented one week ago today
I wasn't able to attend
Hope we can obtain/distribute details of their presentation soon!
https://ecs.confex.com/ecs/228/webprogram/Paper59686.html
1736 Low-Cost Synthetic Routes for Fabricating Tandem/Multi-Junction Photoelectrochemical Devices
W. Cheng (University of Iowa), A. M. Rassoolkhani (Chemical and Biochemical Engineering, University of Iowa), and S. Mubeen (University of Iowa)
Using sunlight to convert widely available and inexpensive feed stocks such as water, CO2, and industrial wastes (including halogenides) reliably to fuels and value added chemicals, efficiently and cost-effectively, has been, and continues to be a major goal. Most such reactions require a minimum of 1eV or more photon energies. For example, the minimum free energy required to split water reversibly is 1.23 eV. However, kinetic limitations and other sources of inefficiencies (for example, water oxidation on photoanodes is kinetically sluggish, and CO2 reduction at photocathodes needs high overpotentials) make the practical energy needed to carry such reactions even considerably higher. A single-junction photosynthetic device would therefore need to base on a semiconductor with a band gap (Eg) > 2.5 eV for it to carry out water splitting or CO2 reduction, precluding the exploitation of a substantial portion of the solar spectrum. Using tandem/multi-junction photovoltaic architectures is an attractive strategy to overcome these limitations. Such strategies have been estimated to be capable of achieving ~18% solar-to-hydrogen conversion efficiencies. John Turner and his colleagues [1] demonstrated a solar-to-H2 conversion efficiency of 12.4% using multi-junction III-V semiconductors in 1990’s. However, the high cost and complexity associated with device fabrication using Si and III-V semiconductors to produce triple junction devices have impeded commercialization. Here, we report a novel and low-cost wet chemical synthesis route to fabricate a tandem junction PEC device through direct deposition of inexpensive and efficient metal oxide/sulfide based photoanodes on single junction Si solar cells which act as photocathodes. The above structures were able to generate sufficiently high cell voltages to drive valuable, and, at times, challenging photoelectrochemical processes sustainably.
Reference:
Khaselev, O. & Turner, J. A monolithic photovoltaic-photoelectrochemical device for hydrogen production via water splitting. Science (New York, N.Y.) 280, 425–7 (1998).
2 Upcoming Scientific Pubs,Chemical Catalyst Study comes first
Shareholder Letter in December will outline 2016 very well!
Guys: Do you want to know a secret!?
HYSR Does NOT need to REVERSE SPLIT and UPLIST...
IT NEEDS 10,000% GAIN AND A FORWARD SPLIT!!
Thoughts?
Q: Any idea who can make that happen? (A: blekko) =)
Next Step: LOAD UP - Marketing Engine Revving UP
HYSR Large Scale Prototype:FLUOR, DOW Chemical,Uni Queensland[AU]
Details coming soon
I am reviewing some of the scientific articles published by our research teams and getting more in depth
Much can be done with little
Jose posted this Toyota link and I am excited by the reality that H2 is coming true
Gas to power applications which incorporate[factor] HYSR tech will prove most interesting as HYSR systems can be supplemented with excess [cheap] and off-peak [cheap] sources of energy to obtain huge H2 production capacities
Let's talk c.f.cntct at gmail is my new primary
Interest?:Free HYSR 5x7 Cards&Brochures for distribution
I Am finishing layout and content, can get them printed by the hundred and drop ship to anyone who wants to help w/marketing!
Volume averaging up, MM's continue averaging @0.02
For your anniversary SLTWW will see a pop!
No marketing budget. PEC Reactor technology has been RE-evolutionized by HyperSolar's cash injection [And Dept of Energy Labs, UCSB, University of Iowa]
The natural gas grid can be injected with 15% pure hydrogen - In the UK the gas grid used to carry up to 60% hydrogen - It is non-corrosive - The only different is re flame speed [which requires burners to be switched out]
One thing for certain is that within 2 years our product will be Revolutionized again within the next two years, and again from a 5 year perspective
Thanks for the info!! Now Following your board here
Happy Saturday HYSR ShareHolders!
30% gain this week... Nice!!
HYSR can&will&does&has rally on a moments notice!!
This stock is like a "Stock Trading 101" for investors. I think that is because all of the UCSB alumni are trading by standard investment rules! Look how it responds exponentially to volume, look at the gradual decay back to the baseline & snap back movement that occurs any time there is a real trickle of volume.
We are trading among the gods here - or highly automated computer trading systems. There are a few people who are already rich the charts dont lie!!
The research output of the two labs is virtually non stop. The less sunny days maybe push them to think of the next steps in our optimization process // This whole thing reminds me of when I was a kid trying to get the biggest heatsink and most fans in my computer case // optimizing surface area of cooling components and maximizing airflow = same thing as HYSR
DFF, I can't believe the rally going on there I am excited too! Hope this is a sign that the market for securities in Hydrogen will kick into overdrive
For purpose of discussion I think we should identify and outline corporations that are involved in our market segment
I've been racking my brain to figure out who is going to supply our manufacturing tech/systems
Here's a list of H2 players.. And hey....... There is one in here you will recognize!!!
http://www.forbes.com/sites/tomkonrad/2013/12/11/twelve-hydrogen-and-fuel-cell-stocks/
True, after voltage achievement many wonder: what's next?!
In terms of economics, cost-comparative models are hard to nail down on this product. We are not comparing electrolyzer to electrolyzer or fuel cell to fuel cell.
Comparisons can't be made to our particle efficiency, only to our system on more broad level [ Cost / (Sq/m) /H2 production]
We are in the fourth phase of rapid materials prototyping, of which I estimate five additional rounds before PR of a large scale prototype.
With much to be determined pertaining to vessel(tank) construction(materials, uv filter(?), magnification tech(?)) the game changer that HYSR could be is perhaps still two years off.
The UCSB conference documents put it in black and white, Artificial Photosynthesis is the ultimate goal.
HYSR appeal lies in its potential - Their unique model, kind of like and inverted Concentrated Solar Power plant, will take much time to enhance and improve at our present pace - Pinning real commercialization at least 18 months out in my mind.
Will the share price rally between now and then? I only wish I had more time to trade HYSR this year rather than simply holding.
Will gains begin to stick at some point? I think they may be starting to just now. If they aren't already.
Sponsored Research Agreement with University of Santa Barbara is great.
The University of Iowa deal? Phenomenal; I don't think anyone saw it coming.
Our buyout offer from Panasonic? That will really give some vim and vigor to the bull camp! [If it comes]
Do longs have anything to be afraid of? Every day - But our UCSB SRA will be up for extension end of the year and that is a PR that I like to see!
Right now we are the believers - Besides Young, McFarland, Mubeen, etc.
If one of us believers had bigger pockets trust me the SP would be higher!
If we trade smartly we can either make money or accumulate more for the day of revelation!
Need access to this article
Co-author Nirala Singh [UCSB/HYSR]
http://pubs.rsc.org/en/content/articlelanding/2015/ee/c5ee01434d/
Best case scenario: Eric McFarland, Yat Li, Syed Mubeen, and colleagues have perfected the science already
Our Sponsored Research Agreement w/UCSB and University of Iowa Hydrosciences teams are filling out gaps in knowledge pursuant to aspects of the relative concrete sciences.
If our approach, utilizing PAH Reactors were not such a cost competitive solution, we wouldn't be in this position to begin with.
We are not taking Hydrogenics out of business any time soon, or ever, for that matter - We share the market of Hydrogen Production, but their prime ROI is found in excess, "run off", cheap, solar energy at grid bottlenecks.
HyperSolar's approach can not currently be used in that particular fashion, where by electrolysis the Hydrogen is simply a rechargeable battery for use at the discretion of the grid operator.
Although I do suspect that something is brewing in terms of combining a PAH Reactor with excess solar energy capacity.
The goal of HyperSolar's PAH approach is to produce as much H2 as possible, putting every electron to work in splitting a water molecule [Optimized at the nano-scale]
The overall efficiency of traditional electrolysis systems is limited among other things by the magnetic resistance of the cabling structures and the efficiency of the electrolyzer.
The varieties of our submersible particles will be tailored to the H2O feedstock which will be used with the reactor.
To my senses, the panel variety seems more appealing than the larger tank-style reactor.
The cradle-to-grave efficiencies of our solutions can not yet be compared to traditional systems until Eric McFarland further revises the cost projections proportionately as the figures will largely be dependent upon manufacturing costs [which will initially be "higher"]
So to reiterate - beyond the above state facts - Best case scenario: We wouldn't be here in the first place if the reactor approach weren't suitably cost competitive.
Now - The visibly more attractive panel option is probably the least cost effective, contrast to the utility scale tank style reactors. This will always be true as the costs of rooftop solar installations greatly exceed the costs of utility scale solar farms.
When does HYSR reach capacity to produce considerable H2 At Point Of Distribution: ???????
That is the trillion dollar question.
That is why CNN featured us in the first place: We told the world we were going to accomplish the task of scientifically achieving artificial photosynthesis - the task which has been eluding researchers for decades.
By maximizing the voltage, expanding the surface area [Check.(Patterend PEDOT:PSS)], optimizing band gap and material selection [Check. Thanks UCSB JCAP Materials Research Lab]
By bonding the ideal catalysts to the H2 production points on our particles,
By improving the procedures of our aqueous manufacturing process [clean room]
We are running very, very lean right now..
I don't think UCSB would like it if HYSR was running $100k marketing campaigns, but if we as shareholders run one of our own, we will make this little puppy take off
I thought of selling my research in HYSR to investors with big pockets but we get rich quicker if we kick this off and let it snowball on its own
HYSR has no marketing... Well I won't be so mean as to say that... We did get picked up last year in the Santa Barbara View
Exactly-Unexpected based on past market moves
To Shareholders 1.55v news is phenomenal, but to the many sell-side analysts who are securing their profits, the buy side is not yet strong enough to warrant a higher Share Price.
The present SP reflects market interest + sentiment given the present reach of our market presence.
Honestly boys if you want to make this puppy run back to $0.13 we are one $15k marketing campaign away from being millionaires.
After that it will snowball on its own and we can schedule our Cayman Islands meet up. Or Luxembourg for our European shareholders!
Toyota H2 Vehicles will be driven by people who are supporting build out of H2 Infrastructure as opposed to:
People who support creating CH4 Natural Gas out of the H2 for ease of distribution.
Owners of the Natural Gas Pipelines would love for us to sacrifice end-to-end efficiency by reforming all of our nice H2 into CH4 just for ease of distribution. It will line their pockets.
That is the traditional power-to-gas model, however, and the - The Easy, Inefficient Way - Pipelines in place, Technology available, Simple as Pie. Rack panels up, electrolyzer, and CO2 Capture systems... Good to go!
HYSR will trump all proponents with our one simple goal:
H2 Production at the point of distribution
Forget that old pipeline.
Very interesting...HYSR's Marketing Dept kicking in???
I would be excited to see a continuance of this effort!
I think licensing presents many questions because UCSB and others have property rights to our property, and Dept of Energy funded them...
From my perspective that dichotomy may result in HYSR being unwilling to "sell out" or license exclusively to just one particular corporate entity.
We should do some research to determine who SolarCity licensed/obtained their tech from on their new 22% efficiency panel!
Remember we are not in the business of panels... We are in the business of submersible Photoelectrochemically Active Heterostructures
Our main goal is strictly to invent tech to produce the Maximum amount of Hydrogen possible - Knowing that other valuable chemicals will also be produced in the process!
The Electrolyzer unit of a typical Power-To-Gas plant doesn't work with waste water, salt water, and industrial byproducts. We suck the Hydrogen right out of whatever source feedstock there is, whereas an electrolyzer would slowly clog up.
Great research coming out of our scientific teams and further publications to come =)
Lets HOPE that OCTOBER is the end of CHEAP SHARES:
No more shares under 3 cents!
That means No more flipping for small gains here folks!
Honestly I want to setup a mini-CSP based electrolysis unit here at home! Too excited to get into the utility scale project I am pursuing... Love the video!
If big money front loaded HYSR then I am sure celebrities would have no problem endorsing our tech?? I do however think they would want to buy us out before it really went to the moon like that!!
Solid PPS building on this baby!!! Remember we came from subs not so long ago! Nice to wake up and see +4.65% on the first trickle of volume for the day!