Transcript Document

U.S. Low Level Counting Facilities
Status and Plans
LRT 2004, Laurentian University
Dec 12-13, 2004
Prisca Cushman
University of Minnesota
In Progress: Working Group on Low Background Counting
Facilities (NSF Solicitation 1 Proposal)
How do we optimize science and technology choices
before DUSEL, for DUSEL, and in addition to DUSEL?
• Screening for existing experiments (and security-related appl.)
• Underground testing of prototypes for DUSEL technology choices
• Screening for the proposed experiments
• Development of high purity materials
• Clean rooms, radon scrubbing, shielding, infrastructure
• R&D now for a future DUSEL LBCF
How can we share resources in a tight budgetary climate?
How can we exploit economy of scale?
First Job: Gather Information
Identify current and future needs
Sensitivity required:
Low Level vs Ultra-Low vs Extreme-Low
Type of screening: a, b, g
Sample size or material
Best technique may not be “counting”
NAA (counting + radiochem lab)
ICPMS, AMS ($$)
RBS, PIXE, Auger, SIMS
Categories used
MJ R&D
KamLAND R&D
MJ Prod
KamLAND Prod
MJ Ops
KamLAND Ops
EXO R&D
Borexino R&D
EXO Prod
Borexino Prod
EXO Ops
Borexino Ops
Our first try already anticipates backlogs
Turnover at 2008 reflects our ignorance
As limits improve, migration from LL  UL and UL  XL
(this is not properly folded in)
Many of the LL category could explore other techniques
Cuore R&D
Cuore Prod
Cuore Ops
UNO R&D
Moon R&D
UNO Prod
Moon Prod
UNO Ops
Moon Ops
KillerAp 1 R&D
SuperDMS R&D
KillerAp 1 Prod
SuperDMS Prod
KillerAp 1 Ops
SuperDMS Ops
KillerAp 2 R&D
Clean R&D
KillerAp 2 Prod
Clean Prod
KillerAp 2 Ops
Clean Ops
KillerAp 3 R&D
Xenon R&D
KillerAp 3 Prod
Xenon Prod
KillerAp 3 Ops
Xenon Ops
KillerAp 4 R&D
R&D1 R&D
KillerAp 4 Prod
R&D2 R&D
KillerAp 4 Ops
Each collaboration should define needs
and then give to us…
Gather Information – cont.
Identify existing counting facilities in the US
DEPTH
Analysis centers at most Universities
User fees – cheaper for University faculty
Commercial Labs
Longer turn around, more expensive, more standardized
“Use for Others” at most national labs (Oak Ridge, LANL, BNL)
A few shallow  middle depth sites open for users
LBL Bldg72 and Oroville Dam – now
LOMO at PNNL - soon
Deep screening sites are only in development stage
WIPP (MEGA )
Soudan: g-screening capability in SOLO
Plans to create a multi-purpose LBCF
Really, Really Deep sites are DUSEL era
Sensitivity for US Sites
Surface counters
LBL Bldg 72,
PNNL, and many
other places etc.
Shielded on surface
PNNL 17-A
LBNL Oroville
LoMoCF estimate
2000 + mwe
Soudan, MEGA
Berkeley Complex:
Surface and Shallow Site under same umbrella organization:
Institute of Nuclear and Particle Astrophysics
STAFF
Kevin Lesko
Al Smith
Dick McDonald
Donna Hurley
Throughput determined by number of Ge detectors
Bldg72 has NaI counters and a 130% HPGe,
Oroville has a 80% p-type HPGe
Major User: SNO (screened virgin and machined acrylic, plastic resins,
PMT envelopes, internal components, stainless steel, etc.)
Also Clean room preparation and operation, sample handling procedures
Bldg 72 (LBL)
Dam (140 mi) from LBL
Sensitivity is currently limited by detector contamination
PNNL – UW Complex:
Surface + 17-A ULB +
new initiative at Lower Monumental Dam
• 1 hr from PNNL
• 37 meters of overburden
• Operated by US Army Corp of Engineers
Inside LoMo Counting Facility:
Currently being used as cosmogenic isolation space
for copper stock and MEGA parts
Plan is to install gamma screening in lead cave.
Funding is in place.
PNNL
UW
Water trough
1’
J.A. Formaggio
J.F. Wilkerson
C.E. Aalseth
R.L. Brodzinski
T. Hossbach
H.S. Miley
J.L. Orrell
4’
Person
1’
~8’
Access
1
’
4’
1’
4-person elevator access
Two sets of 3 HPGe counters with
active cosmic veto shield
• DOE Facility
• Impressive
infrastructure
• Modest depth
(1600 mwe)
• Science as
add-on to
primary mission
• Low background
counting lab
being built
MEGA-SEGA
WIPP
LANL/WIPP complex:
2 connex for storage and office space
Detector Hut and electronics room
The highlight is the MEGA detector:
combination R&D for Majorana and ultra-low screener
SEGA underground by next summer (not a screener)
Assembling MEGA at WIPP now.
1st detector may take data by end of January
Completed in a couple years.
Low background Screening and Prototyping Facility
at the Soudan Underground Lab
Draft Proposal at http://www.hep.umn.edu/~prisca/soudan
The major arguments for placing it at Soudan are
Availability: 40 ft x 35 ft x 100 ft experimental hall
surrounded by a 99% efficient muon veto shield.
Infrastructure: The Soudan Underground Laboratory is a working science lab:
(MINOS, CDMS, SOLO gamma-screening facility)
Cost:
Cheap (~ $2 M) due to existing infrastructure and working muon shield
A multiple-user facility is far more cost efficient.
Self-sufficient: operating budget pays for itself
Timescale: 2 years if not funding limited. Staged plan starting NOW.
Last Soudan2 proton decay
calorimeters (at back) were
removed Nov 23rd 2004
SOLO HPGe
Diode M (35%)
Twin (75%)
UF detector (100%)
Full Proposal includes the following features
• Four
HP Ge detectors for gamma screening.
Two in existing lead-shielded SOLO facility (Brown, PNNL)
Third from U. Florida startup, 4th Clover Well Detector (NSF MRI)
• Two alpha/beta screeners (via alternate funding)
neon gas MWPC (Caltech, CWRU, FNAL)
triggered expansion cloud chamber (UCSB, UMinn)
• Underground electroforming facility to make high purity copper
(Reeves & Sons via awarded SBIR)
• Ge Detector fabrication (pending SBIR with Princeton Gamma Tech)
• Clean Machine shop
• Water tank with multiple top-loading ports in clean room on top
• Multipurpose clean room with shielded bays for prototypes
• Radon-scrubbing for all clean rooms
Drawings and Design Consultation: Short Elliott Henderson Engineering, Inc
Upper mezzanine above tank top
Electro
form
40 ft
Anteroom
Multipurpose
clean room
User shielding
Clean room over tank
Water ports with crane
Ante-room
100 ft
Muon veto shield
radon scrubbing plenum.
Clean
Clean room over room
tank
mezzanine
current mezzanine
Clean
anteroom room
Shielded
bays
Muon veto shield
Water tank
Muon veto shield
Muon veto shield
anteroom
If we build in stages, we will always use lead caves,
but the water tank advantage is:
Cost is the same as one lead castle, but it will serve multiple users.
It can be upgraded (limited by water purification) or filled with Liq. Scint
Provides an R&D example for DUSEL LBCF
At Soudan, it reduces cosmogenic neutron flux to ~ 0.007 mdru
roughly equivalent to 4000 mwe cavern depth
Strategy for Soudan LBCF
• Create minimum facility now
(DOE University supplements for infrastructure)
• Provide world class gamma screening via 2005 NSF MRI
• Provide novel beta screeners through CDMS collaborators
(or possible MRI 2006)
• Take this next year to
Increase size of collaboration
Attend NSF Solicitation 1 and LRT2004
Modify design according to input and new users
That’s You!
• Put in complete proposal next Fall ‘05
The following ongoing work has been funded
Soudan2 Removal
DONE
Veto Shield refurbishing
Pressure tests finished, tubes repaired, preamps tested
New DAQ: Location and Time stamp (1MHz osc + GPS pps)
for every 2-plane coincidence
Clean room on Mezzanine (CDMS SiLi and BF detector)
Clean room in back of Mezzanine (Reeves electroforming & detector)
Full Project File (BOE and engineering input)
A process to accept new experiments: (fee structure, management, EPS)
EPS Signers for this winter
Medtronics: cosmogenic soft memory errors
SBIR to do copper electroforming underground (Jim Reeves)
2nd SBIR for a low background detector (microBq/kg) to test copper
COUPP (superheated liquid bubble chamber for dark matter)
Experimental Planning Statement for the Low Background Counting Facility
A statement with the information detailed below, together with the signature sheet, must be submitted to the Soudan
Underground Lab Manager before any experiment can be approved for installation in the Low Background Counting
Facility. This will ensure that any new experiment does not interfere with either the of the two existing large experiments
or with public tours, as well as reviewing safety and code-related issues.
1. Project Title and Description, incl. list of collaborators, institutions, and funding sources.
2. Experiment Area and Infrastructure Needs.
This section should include physical area needed, both underground and on the surface, connections needed between
surface and underground installations, electrical power needs, LAN bandwidth, and any special air handling requirements.
There should also be list of number phone or fax lines needed. Depending on the area needed or type of the experiment,
are there additional fire or life safety infrastructures needed?
3. Project Schedule
Schedule should contain any construction period needed for infrastructure, detector assembly, operation period and
removal of experiment. An estimate of access (and access schedule, including on-call emergency access) should be
included such that hoist costs directly related to the experiment can be properly calculated. A description of the load size
and weight of the cage is available.
4. Hazard Analyzes
A complete list materials to be brought underground and waste products to be removed. Any possible physical hazards
should be listed. All materials should have MSDS sheets appended to this document. Any material handling issues should
also be noted. Assessment of this issues, especially the ones that fall under the safety category, need to be addressed by
both the U of M and DNR who are responsible for site safety.
5. Minecrew Labor
An estimate of minecrew labor needed should include any construction or operation manpower requirements. As a general
rule, all non carry-on equipment must be moved underground by the minecrew. A trained and designated cage rider must
be present underground at all time if access for non-standard shifts is needed.
6. Surface Space Required
List any space usage needed in Surface Building for staging or remote operation, including control rooms and computers
(there is a fiber optic connection to the underground lab).
Also list any space required that cannot be accommodated inside the surface building for parking, staging or general
material storage.
Project Title:____________________________________________________
Prof. Earl Peterson ______________________________________
University of Minnesota
Soudan Underground Lab Director
[email protected]
Mr. William Miller ______________________________________
University of Minnesota
Soudan Underground Lab Manager
[email protected]
Mr. Paul Wannarka ______________________________________
Department of Natural Resources
Soudan Underground Mine State Park Manager [email protected]
Dr. Regina Rameika ______________________________________
Fermi National Laboratory
MINOS Operations Manager
[email protected]
Dr. Dan Bauer ___________________________________________
Fermi National Laboratory
CDMS II Project Manager
[email protected]
Prof. Priscilla Cushman ____________________________________
University of Minnesota
Manager of the Low Background Counting Facility
[email protected]
What should a DUSEL LBCF look like?
Soudan/WIPP are pre-DUSEL
Address screening issues NOW
Could be expanded into a DUSEL
or
Used as R&D for DUSEL design
Supplement screening & prototyping in DUSEL era.
Homestake NUSL Reference Design Report
WBS 6.1 (Low-level counting facility)
NUSL White Paper (Nico, Piepke, Shutt)
Figure E-16 from the Homestake Reference Design
NAA Laboratory + general environmental sample handling
Secure lab
(TBA) Pool 2
Gd-loaded liq. Scint
for neutron sensitivity
or
Mini-Borexino for U/Th
down to 10-16 g/g
Emanation
and leaching
laboratory
Pool 1
12 m cube – ultra-pure water
Built-in liq. Scint acrylic thimble ports
read out by PMT’s
for U/Th down to 10-14 g/g
University of Minnesota Intercollegiate Grant
1. Seek out other user communities for LBCF
2. Coordinate low level counting/analysis across sites
website this spring
tie it to the solicitation 1 work
Examples of other user communities involved:
C. Alexander (Geology) Tritium and
14C
in groundwater
C. Lungu (Environmental Health Sciences) & Minnesota Pollution Agency
Radioactive environmental sampling (accidental release of radio-isotopes)
Exposure assessment studies (14C as a tracer of particiulate lung burden)
Epidemiological studies of uranium workers (tissue samples)
Large Lakes Observatory, The St Croix River Watershed Research Center,
Florida Dept of Fisheries and Wildlife
short-lived isotopes for sediment dating
These “other” users need well-type HPGe, chemical separation, sample handling
AND beta-counting applications (14C, 3H)
Conclusions and not-so-random Thoughts
Immediate need for more screening facilities – we cannot wait for DUSEL
Most samples can use shallow/shielded sites and many could use other techniques,
but a growing number require the shielding of a deep site
One-stop shopping would be very convenient
sorting samples, pre-screening, follow up techniques,
cosmogenic/radon-free isolation storage
Plus: industry spin-offs (electroforming, detector development)
cost effective (manpower, infrastructure, scheduling)
fosters R&D and collaborative efforts
To be complete, such an analysis center should have deep capabilities.
Collaborations can use European/Asian facilities
BUT backlogs still exist, local sites are convenient,
small R&D efforts and non-int’l groups left out
Symbiosis possible: geology, hydrology, public health, environmental sciences
are growing users of isotope analysis and dating.
Multiple Sites are a Good Thing – but some complementarity is desirable.